Sunscreen Drug Products for Over-the-Counter Human Use, 6204-6275 [2019-03019]

Download as PDF 6204 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules DEPARTMENT OF HEALTH AND HUMAN SERVICES Food and Drug Administration 21 CFR Parts 201, 310, 347, and 352 [Docket No. FDA–1978–N–0018] (Formerly Docket No. FDA–1978–N–0038) RIN 0910–AF43 Sunscreen Drug Products for Over-theCounter Human Use AGENCY: Food and Drug Administration, HHS. ACTION: Proposed rule. The Food and Drug Administration (FDA or Agency) is issuing this proposed rule to put into effect a final monograph for nonprescription, over-the-counter (OTC) sunscreen drug products. This proposed rule describes the conditions under which FDA proposes that OTC sunscreen monograph products are generally recognized as safe and effective (GRASE) and not misbranded. It is being published as part of the ongoing review of OTC drug products conducted by FDA. It is also being published to comply with the Federal Food, Drug, and Cosmetic Act (FD&C Act), as amended by the Sunscreen Innovation Act (SIA). DATES: Submit either electronic or written comments. on the proposed rule by May 28, 2019. Electronic comments must be submitted on or before May 28, 2019. The https://www.regulations.gov electronic filing system will accept comments until 11:59 p.m. Eastern Time at the end of May 28, 2019. See section XII for proposed effective and compliance dates of a final rule based on this document. ADDRESSES: You may submit comments as follows. Please note that late, untimely filed comments will not be considered. Comments received by mail/hand delivery/courier (for written/ paper submissions) will be considered timely if they are postmarked or the delivery service acceptance receipt is on or before the closing date. Please be advised that safety and effectiveness data that are not available to the public cannot be relied on to establish conditions under which the OTC drugs described in this document of proposed rulemaking are generally recognized as safe and effective. Accordingly, you should not submit, and FDA generally does not intend to rely on, any evidence of safety and effectiveness that bears a confidential mark unless you include a statement that the information may be released to SUMMARY: VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 the public. Similarly, if your submission includes safety and effectiveness data or information marked as confidential by a third party (such as a contract research organization or consultant), you should either include a statement that you are authorized to make the information publicly available or include an authorization from the third party permitting the information to be publicly disclosed. If you submit data without confidential markings in response to this document and such data includes studies or other information that were previously submitted confidentially (e.g., as part of a new drug application), FDA intends to presume that you intend to make such data publicly available. Electronic Submissions Submit electronic comments in the following way: • Federal eRulemaking Portal: https://www.regulations.gov. Follow the instructions for submitting comments. Comments submitted electronically, including attachments, to https:// www.regulations.gov will be posted to the docket unchanged. Because your comment will be made public, you are solely responsible for ensuring that your comment does not include any confidential information that you or a third party may not wish to be posted, such as medical information, your or anyone else’s Social Security number, or confidential business information, such as a manufacturing process. Please note that if you include your name, contact information, or other information that identifies you in the body of your comments, that information will be posted on https://www.regulations.gov. • If you want to submit a comment with confidential information that you do not wish to be made available to the public, submit the comment as a written/paper submission and in the manner detailed (see ‘‘Written/Paper Submissions’’ and ‘‘Instructions’’). Written/Paper Submissions Submit written/paper submissions as follows: • Mail/Hand Delivery/Courier (for written/paper submissions): Dockets Management Staff (HFA–305), Food and Drug Administration, 5630 Fishers Lane, Rm. 1061, Rockville, MD 20852. • For written/paper comments submitted to the Dockets Management Staff, FDA will post your comment, as well as any attachments, except for information submitted, marked and identified, as confidential, if submitted as detailed in ‘‘Instructions.’’ Instructions: All submissions received must include the Docket No. FDA– PO 00000 Frm 00002 Fmt 4701 Sfmt 4702 1978–N–0018 (formerly Docket No. FDA–1978–N–0038) for ‘‘Sunscreen Drug Products for Over-the-Counter Human Use.’’ Received comments, those filed in a timely manner (see ADDRESSES), will be placed in the docket and, except for those submitted as ‘‘Confidential Submissions,’’ publicly viewable at https://www.regulations.gov or at the Dockets Management Staff between 9 a.m. and 4 p.m., Monday through Friday. • Confidential Submissions—To submit a comment with confidential information that you do not wish to be made publicly available, submit your comments only as a written/paper submission. You should submit two copies total. One copy will include the information you claim to be confidential with a heading or cover note that states ‘‘THIS DOCUMENT CONTAINS CONFIDENTIAL INFORMATION.’’ The Agency will review this copy, including the claimed confidential information, in its consideration of comments. The second copy, which will have the claimed confidential information redacted/blacked out, will be available for public viewing and posted on https://www.regulations.gov. Submit both copies to the Dockets Management Staff. If you do not wish your name and contact information to be made publicly available, you can provide this information on the cover sheet and not in the body of your comments and you must identify this information as ‘‘confidential.’’ Any information marked as ‘‘confidential’’ will not be disclosed except in accordance with 21 CFR 10.20 and other applicable disclosure law. For more information about FDA’s posting of comments to public dockets, see 80 FR 56469, September 18, 2015, or access the information at: https://www.gpo.gov/ fdsys/pkg/FR-2015-09-18/pdf/201523389.pdf. Docket: For access to the docket to read background documents or the electronic and written/paper comments received, go to https:// www.regulations.gov and insert the docket number, found in brackets in the heading of this document, into the ‘‘Search’’ box and follow the prompts and/or go to the Dockets Management Staff, 5630 Fishers Lane, Rm. 1061, Rockville, MD 20852. Submit comments on information collection issues under the Paperwork Reduction Act of 1995 to the Office of Management and Budget (OMB) in the following ways: • Fax to the Office of Information and Regulatory Affairs, OMB, Attn: FDA Desk Officer, Fax: 202–395–7285, or email to oira_submission@omb.eop.gov. All comments should be identified with E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules the title, ‘‘Sunscreen Drug Products for Over-the-Counter Human Use.’’ The Agency encourages commenters also to submit their comments on these paperwork requirements to the rulemaking docket (Docket No. FDA– 1978–N–0018), along with their comments on other parts of the proposed rule. FOR FURTHER INFORMATION CONTACT: Kristen Hardin, Center for Drug Evaluation and Research, Food and Drug Administration, 10903 New Hampshire Ave., Bldg. 22, Rm. 5443, Silver Spring, MD 20993, 240–402– 4246. SUPPLEMENTARY INFORMATION: Table of Contents I. Executive Summary A. Purpose and Coverage of the Proposed Rule B. Summary of the Major Provisions of the Proposed Rule C. Legal Authority D. Costs and Benefits II. Table of Abbreviations/Commonly Used Acronyms in This Document III. Background A. FDA’s Current Regulatory Framework B. History of This Rulemaking IV. Scope of This Rulemaking V. Legal Authority VI. Need for Additional Safety Information A. Increased Consumer Exposure to Sunscreen Active Ingredients B. Emerging Safety Concerns VII. Framework for Evaluation of Safety Data A. General B. Clinical Safety Testing C. Nonclinical Safety Testing D. Postmarketing Safety Data E. Sunscreens Containing Nanomaterials VIII. Existing Safety Data for Sunscreen Active Ingredients A. Ingredients Proposed as Category I B. Ingredients Proposed as Category II C. Ingredients Proposed as Category III D. Anticipated Final Formulation In Vitro Permeation Testing IX. Additional Proposed Conditions of Use A. Proposed Requirements Related to Dosage Form B. Proposed Maximum SPF and Broad Spectrum Requirements C. Proposed PDP Labeling Requirements D. Proposed Requirements Related to Final Formulation Testing and Recordkeeping E. Proposed Status of Sunscreen-Insect Repellent Combination Products X. Proposed Actions To Effectuate Lifting of Stay and Harmonize Impacted Regulations XI. Comment Period XII. Proposed Effective/Compliance Dates XIII. Preliminary Economic Analysis of Impacts A. Introduction B. Summary of Costs and Benefits XIV. Analysis of Environmental Impact XV. Paperwork Reduction Act of 1995 A. Labeling for Sunscreen Products and Associated Clinical Testing VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 B. Regulatory Status of Testing Entities C. Generating and Maintaining Records of SPF and Broad Spectrum Testing XVI. Federalism XVII. Consultation and Coordination With Indian Tribal Governments XVIII. References I. Executive Summary A. Purpose and Coverage of the Proposed Rule The Food and Drug Administration (FDA or Agency) is publishing this proposed rule as part of the regulatory proceeding to put into effect a final monograph 1 for nonprescription, OTC sunscreen drug products under the OTC Drug Review. In 2011, FDA announced that ‘‘we are considering certain active ingredient safety issues further . . . In a forthcoming rulemaking, we intend to request additional data regarding the safety of the individual sunscreen active ingredients.’’ (‘‘Revised Effectiveness Determination; Sunscreen Drug Products for Over-the-Counter Human Use’’ (Max SPF PR), 76 FR 35672 at 35673, June 17, 2011). As described in further detail below, changed conditions in the nearly 20 years since publication of the final rule ‘‘Sunscreen Drug Products for Over the Counter Human Use’’ (64 FR 27666, May 21, 1999) (now stayed) (Stayed 1999 Final Monograph) have meant that additional safety data are now needed to establish that certain of the active ingredients listed in the Stayed 1999 Final Monograph are GRASE for use in sunscreen products.2 As detailed below, we emphasize that this proposed rule does not represent a conclusion by FDA that the sunscreen active ingredients included in the Stayed 1999 Final Monograph but proposed here as Category III are unsafe for use in sunscreens. Rather, we are requesting additional information on these ingredients so that we can evaluate their GRASE status in light of 1 An OTC monograph establishes conditions under which certain OTC drugs may be marketed without approved new drug applications because they are generally recognized as safe and effective (GRASE) and not misbranded. The proposed rule classifies active ingredients and other conditions as Category I (proposed to be GRASE and not misbranded), Category II (proposed to be not GRASE or to be misbranded), or Category III (additional data needed). 2 Unless otherwise noted, references in this proposed rule to sunscreen active ingredients and/ or sunscreen products are to sunscreen active ingredients or products marketed pursuant to the OTC monograph system and subject to 21 CFR 201.327. Unless specifically noted, references to sunscreen active ingredients and/or sunscreen products in this notice do not refer to those marketed pursuant to a new drug application (NDA) or an abbreviated new drug application (ANDA). They also do not refer to sunscreen active ingredients being evaluated under the new procedures set out in the SIA (21 U.S.C. 360fff et seq). PO 00000 Frm 00003 Fmt 4701 Sfmt 4702 6205 changed conditions, including substantially increased sunscreen usage and exposure and evolving information about the potential risks associated with these products since they were originally evaluated. While these additional data are being developed and reviewed, FDA generally intends to follow the enforcement approach discussed in section III.B with regard to sunscreen products that contain those sunscreen active ingredients included in the Stayed 1999 Final Monograph. This proposed rule is also being published to comply with section 586E of the FD&C Act (21 U.S.C. 360fff–5), as amended by the SIA (21 U.S.C. ch. 9, sub. 5, part I, enacted November 26, 2014). The SIA calls for FDA to issue a final OTC sunscreen monograph to be effective within 5 years of enactment of the SIA, or by November 26, 2019 (section 586E(a) of the FD&C Act). If the final OTC sunscreen monograph does not include provisions related to the effectiveness of various sun protection factor (SPF) levels and address all dosage forms known to FDA to be used in sunscreens marketed in the United States without approved new drug applications (NDAs), the SIA requires FDA, among other things, to submit a report to Congress explaining these omissions (section 586E(b) of the FD&C Act). As explained in section I.B, in this proposed rule, FDA is addressing multiple conditions of use applicable to sunscreen monograph products, including both the effectiveness of various SPF values and all marketed sunscreen dosage forms (and intends to do so in the final rule as well). This proposed rule does not address the sunscreen active ingredients that were originally submitted under the procedures established in FDA’s time and extent application (TEA) regulation (§ 330.14 (21 CFR 330.14)) (67 FR 3074, January 23, 2002), and are now being addressed through a process set forth in the SIA. B. Summary of the Major Provisions of the Proposed Rule 1. Proposed GRASE Status of Active Ingredients Listed in the Stayed 1999 Final Monograph a. Framework for evaluation of safety data. As previously noted, changed conditions in the time since issuance of the Stayed 1999 Final Monograph have meant that additional safety data are now needed to establish that certain of the active ingredients listed in the Stayed 1999 Final Monograph are GRASE for use in sunscreen products in accordance with the standards established in § 330.10(a)(4) (21 CFR E:\FR\FM\26FEP2.SGM 26FEP2 6206 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules 330.10(a)(4)). FDA’s approach to the clinical safety evaluation of OTC sunscreen active ingredients is based on our current scientific understanding regarding the safety evaluation of topical drug products for chronic use, and is therefore generally consistent with the safety data needed to meet the requirements for approval of an NDA for a chronic-use topical drug product (e.g., topical safety studies (irritation, sensitization, and photosafety); bioavailability (absorption); and evaluation of adverse events observed in clinical studies). Postmarketing safety information is also relevant to our safety evaluation. Our current approach to the nonclinical safety evaluation of these active ingredients takes into account their lengthy marketing history in the United States. Unlike the nonclinical data required to meet the standard for approval of chronic-use topical NDA products (which include comprehensive nonclinical pharmacology and toxicology safety testing), the approach to nonclinical safety testing reflected in this proposed rule is largely focused on potential long-term adverse effects or effects not otherwise readily detected from human use (i.e., carcinogenicity and reproductive toxicity). b. Existing safety data for ingredients listed in Stayed 1999 Final Monograph. In section VIII, we discuss our review of the scientific literature, submissions to the sunscreen monograph docket, and adverse event reports submitted to FDA’s Adverse Event Reporting System (FAERS) for the ingredients listed in the Stayed 1999 Final Monograph and identify any existing gaps. Because our review of this evidence has produced sufficient safety data on both zinc oxide and titanium dioxide to support a proposal that sunscreen products containing these ingredients (at concentrations of up to 25 percent) would be GRASE, we are proposing that these ingredients are Category I. Our evaluation of the available safety data for aminobenzoic acid (PABA) and trolamine salicylate, however, has caused us to conclude that the risks associated with use of these active ingredients in sunscreen products outweigh their benefits. In the case of trolamine salicylate, these risks include the potential for serious detrimental health effects (including bleeding) caused by the anti-coagulation effects of salicylic acid and increased risk of salicylate toxicity when this ingredient is used in sunscreens. For PABA, the risks include significant rates of allergic and photoallergic skin reactions, as well as cross-sensitization with structurally similar compounds. Accordingly, we are VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 proposing that these two ingredients are Category II. Because the public record does not currently contain sufficient data to support positive GRASE determinations for cinoxate, dioxybenzone, ensulizole, homosalate, meradimate, octinoxate, octisalate, octocrylene, padimate O, sulisobenzone, oxybenzone, or avobenzone, we are proposing that these ingredients are Category III. For example, the available literature includes studies indicating that oxybenzone is absorbed through the skin to a greater extent than previously understood and can lead to significant systemic exposure, as well as data showing the presence of oxybenzone in human breast milk, amniotic fluid, urine, and blood plasma. The significant systemic availability of oxybenzone, coupled with a lack of data evaluating the full extent of its absorption potential, is a concern, among other reasons, because of questions raised in the published literature regarding the potential for endocrine activity in connection with systemic oxybenzone exposure. Nearly all of these sunscreen active ingredients also have limited or no data characterizing their absorption. 2. Proposed Requirements Related to Dosage Forms In 2011, FDA published an Advance Notice of Proposed Rulemaking (ANPR) that identified sunscreen dosage forms considered either eligible or ineligible for inclusion in the sunscreen monograph, and specifically requested comments on the safety and efficacy of spray sunscreens. After considering comments received in response (and other available data), we are proposing the following dosage forms as Category I: Oils, lotions, creams, gels, butters, pastes, ointments, and sticks. We are also proposing Category I status for spray sunscreens, subject to testing necessary to minimize potential risks from unintended inhalation (particle size restrictions) and flammability (flammability and drying time testing), together with related labeling requirements. We are proposing to add sunscreen powders to the list of those eligible for inclusion in the monograph and proposing that this dosage form is Category III; we expect that powders would also be subject to particle size restrictions if found to be GRASE in the final monograph. Finally, we are proposing that sunscreens in all other dosage forms—including wipes, towelettes, body washes, and shampoos—are new drugs because we did not receive data showing that they were marketed prior to 1972, as required for inclusion in the monograph. PO 00000 Frm 00004 Fmt 4701 Sfmt 4702 3. Proposed Maximum Sun Protection Factor and Broad Spectrum Requirements In the Stayed 1999 Final Monograph, FDA established SPF 30+ as the maximum labeled SPF value for sunscreen monograph products, and subsequently proposed (in 2011) to raise this value to SPF 50+. Because of evidence showing additional meaningful clinical benefit associated with broad spectrum sunscreen products with an SPF of 60, we are now proposing to raise the maximum labeled SPF value to SPF 60+. Given the lack of data showing that sunscreens with SPF values above 60 provide additional meaningful clinical benefit, we are proposing not to allow labeled SPF values higher than 60+. While our proposed cap for SPF labeling is SPF 60+, we are proposing to permit the marketing of sunscreen products formulated with SPF values up to 80. This formulation margin is intended to provide manufacturers with formulation flexibility that we hope will: (1) Help facilitate the development of products with greater Ultraviolet A (UVA) protection and (2) more fully account for the range of variability in SPF test results (discussed further in sections IX.B.4.b–c) for sunscreen products labeled SPF 60+. We are proposing not to allow the marketing (without an approved NDA) of sunscreen products with SPF values above SPF 80. In addition, since publication of the 2011 ‘‘Labeling and Effectiveness Testing; Sunscreen Drug Products for Over-the-Counter Human Use’’ (L&E Final Rule) (76 FR 35620, June 17, 2011) and Max SPF PR, the body of scientific evidence linking UVA exposure to skin cancers and other harms has grown significantly. This evidence raises concerns about the potential for inadequate UVA protection in marketed sunscreen products—particularly in high SPF sunscreen products that either do not pass the current broad spectrum test or (though they pass our current broad spectrum test) have inadequate uniformity in their UVA protection. Consumers using these products may, while successfully preventing sunburn, accumulate excessively large doses of UVA radiation—thereby exposing themselves to additional risks related to skin cancer and early skin aging. To address these concerns, we are making a number of proposals designed to couple a greater magnitude of UVA protection to increases in SPF values. We are proposing to require that all sunscreen products with SPF values of 15 and above satisfy broad spectrum E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules requirements. Among other things, this proposal eliminates the potential confusion permitted by the current labeling regime, in which a higher numbered product (for example, one labeled SPF 30) may provide inferior protection against UVA radiation than a lower numbered product (for example, one labeled broad spectrum SPF 15). We are also proposing to add to the current broad spectrum test a requirement that broad spectrum products meet a UVA I/ UV ratio of 0.7 or higher. Given how much of the UVA portion of the ultraviolet (UV) spectrum is composed of UVA I radiation, and given what we now know about the skin cancer risks associated with UVA exposure, ensuring that sunscreen products provide adequate protection in the UVA I portion of the spectrum is critical.3 Because sunscreens with SPF 2 to 14 have not been demonstrated to help reduce the risk of skin cancer and early skin aging caused by the sun, whether or not they provide protection against UVA radiation as well as ultraviolet B (UVB) radiation, we are not proposing to require that they pass the revised broad spectrum test. However, we seek comment on whether these low SPF products should remain in the market. Finally, we are proposing to require that sunscreen products with SPF values of 15 or above be labeled with an SPF number corresponding to the lowest number in a range of tested SPF results. For example, sunscreens testing at SPF 15–19 would be labeled ‘‘SPF 15’’; those testing at 40–49 would be labeled ‘‘SPF 40.’’ We are making this proposal because new evidence has caused us to reexamine the variability inherent in the SPF test (which relies on visual assessments of erythema in human subjects). The data we reviewed suggests that the clinical evaluation undertaken during SPF testing creates variability that justifies the use of SPF ranges. As explained further in sections IX.B.4.b–c, because this variability is exacerbated at high SPFs, we are proposing that sunscreens testing at SPF 30 or more be labeled in increments of 10 (i.e., SPF 30, SPF 40, SPF 50, with a proposed maximum of SPF 60+), that sunscreens testing at SPF 15 to 29 be 3 We note that because our proposal to raise the maximum labeled SPF value to 60+ is based on studies that all used broad spectrum sunscreens, the additional clinical benefit we are proposing to recognize in sunscreen products with SPF values greater than 50 cannot be decoupled from the broad spectrum protection provided by those products. As a result, our proposal to raise the maximum labeled SPF value to SPF 60+ is both consistent with and dependent upon our proposal to require that all sunscreen monograph products with SPF values of 15 and above satisfy our broad spectrum requirements. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 labeled in increments of 5 (i.e., SPF 15, SPF 20, SPF 25), and that the requirement that labeled SPF values correspond to ranges (rather than precise numerical values) is not necessary below SPF 15. 4. Proposed PDP Labeling Requirements We are also proposing to partially revise the current requirements for information that must appear on the principal display panel (PDP) of sunscreen products. The PDP is the part of a product label that is most likely to be viewed or examined when the product is displayed for retail sale. A major feature of the PDP is the statement of identity (SOI). We are proposing that the SOI consist of an alphabetical listing of the sunscreen active ingredients in the product, followed by ‘‘Sunscreen’’ and the product’s dosage form (such as lotion or spray). This information would supplement other important elements of the PDP (e.g., SPF, broad spectrum, and water resistance information) to provide a succinct summary of the product’s key characteristics on the front of the package or container, permitting consumers to more readily compare products and either select or avoid a given product accordingly. For sunscreen products that have not been shown to help prevent skin cancer or early skin aging caused by the sun, the SPF statement would be followed by an asterisk (*) directing consumers to see the ‘‘Skin Cancer/Skin Aging alert’’ elsewhere on the label. Finally, to prevent required information from being obscured or overwhelmed by other labeling features, we are revising the format requirements for the SPF, broad spectrum, and water resistance statements on the PDP. 5. Proposed Requirements Related to Final Formulation Testing Processes and Recordkeeping To ensure that FDA can assess compliance with our regulations, we are proposing to require records of required final formulation testing of sunscreen products to be maintained for 1 year after the product expiration date, or, if the product is exempt from expiration dating (as most sunscreens are), for 3 years after distribution of the last lot labeled in reliance on that testing. In addition, we are proposing to require responsible persons (defined in section IX.D.2.b) to keep records of sunscreen formulation testing, and clarifying that required records would be subject to FDA inspection. We are also proposing a number of revisions to our labeling and testing regulations designed to clarify FDA expectations about clinical final formulation testing processes and PO 00000 Frm 00005 Fmt 4701 Sfmt 4702 6207 to ensure that the testing of marketed sunscreen products is conducted in a manner that both protects human subjects and produces reliable results. 6. Proposed Status of Sunscreen-Insect Repellent Combination Products The proposed rule also addresses sunscreen-insect repellent products, which are jointly regulated by FDA as sunscreen drugs and by the Environmental Protection Agency (EPA) as pesticides under the Federal Insecticide, Fungicide and Rodenticide Act (FIFRA). In 2007, FDA and EPA both issued ANPRs requesting comment on the appropriate regulatory status of these products. We are proposing to classify these products as Category II because incompatibilities between FDA and EPA labeling requirements prevent these products from being labeled in a manner that sufficiently ensures safe and effective use of the sunscreen component and provides adequate directions for use. In addition, there are data suggesting that combining some sunscreen active ingredients with the insecticide DEET may increase absorption of either or both components. 7. Proposed Actions To Effectuate Lifting of Stay and Harmonize Impacted Regulations Finally, we are proposing to lift the stay on the 1999 Final Monograph (subject to the revisions to parts 201, 310, 347, and 352 (21 CFR parts 201,4 310, 347, and 352) described in this document), and have proposed revisions to these regulations necessary to effectuate the lifting of the stay and to harmonize any impacted regulations. C. Legal Authority We are issuing this proposed rule under sections 201, 301, 501, 502, 503, 505, 510, 586E, 701, 702, 703, 704, and 721 of the FD&C Act (21 U.S.C. 321, 331, 351, 352, 353, 355, 360, 360fff–5, 371, 372, 373, 374, and 379e) and under section 351 of the Public Health Service Act (42 U.S.C. 262). D. Costs and Benefits If finalized, the proposed rule would update and make effective regulations to ensure the safety and effectiveness of sunscreen products marketed under the OTC drug monograph. The rule would update sunscreen product labeling standards, address the safety of sunscreen active ingredients, revise and 4 We note that, for ease of comprehension, we have included in this document the current provisions of 21 CFR 201.327 that we are not proposing to revise along with the provisions of that regulation that we are proposing to revise. E:\FR\FM\26FEP2.SGM 26FEP2 6208 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules clarify our expectations for testing and recordkeeping by entities that conduct sunscreen testing, and address other sunscreen safety or efficacy concerns, like combination sunscreen-insect repellents and alternative dosage forms. Consumers would benefit from less exposure to sunscreen products containing active ingredients about which safety questions remain, less exposure to sunscreen products labeled with potentially misleading sun protection information, increased consumption of products with better UVA protection, less exposure to flammable spray sunscreens, and less exposure to spray and powder sunscreen products posing inhalation risks. Consumers would also experience transaction cost savings. The costs of the rule to sunscreen manufacturers include administrative costs, costs to fill data gaps for active ingredients and powder dosage forms, product formulation testing costs, and costs to reformulate and relabel sunscreen products. Finally, testing entities would incur recordkeeping costs if they do not already maintain adequate records of testing equipment, methods, and observations in final formulation testing. II. Table of Abbreviations/Commonly Used Acronyms in This Document Abbreviation/ acronym What it means ANDA ................. Abbreviated new drug application. Advance notice of proposed rulemaking. Code of Federal Regulations. Developmental and reproductive toxicity. N,N-Diethyl-meta-toluamide. Environmental Protection Agency. FDA’s Adverse Event Reporting System. Food and Drug Administration. Federal Food, Drug, and Cosmetic Act. Federal Insecticide, Fungicide, and Rodenticide Act. Federal Register. Generally recognized as safe and effective (or general recognition of safety and effectiveness). International Council for Harmonisation of Technical Requirements for Pharmaceuticals for Human Use. Investigational new drug application. Institutional Review Board. Milliliter. Maximal usage trial. New drug application. Nonprescription Drugs Advisory Committee. Nanogram. Nanometer. No observed adverse effect level. National Pesticide Information Center. ANPR ................. CFR ................... DART ................. DEET ................. EPA ................... FAERS ............... FDA or Agency .. FD&C Act .......... FIFRA ................ FR ...................... GRASE .............. ICH .................... IND .................... IRB ..................... mL ...................... MUsT ................. NDA ................... NDAC ................ Ng ...................... Nm ..................... NOAEL .............. NPIC .................. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 Abbreviation/ acronym What it means NTP ................... National Toxicology Program of the National Institutes of Health. Office of Management and Budget. Over-the-counter. Aminobenzoic acid. Reactive oxygen species. Sunscreen Innovation Act. Sun protection factor. Time and extent application. Tentative final monograph. United States Code. United States Pharmacopeia. Ultraviolet A. Ultraviolet B. OMB .................. OTC ................... PABA ................. ROS ................... SIA ..................... SPF .................... TEA .................... TFM ................... U.S.C. ................ USP ................... UVA ................... UVB ................... III. Background A. FDA’s Current Regulatory Framework In the following sections, we provide a brief description of terminology used in the OTC Drug Review regulations as well as an overview of OTC sunscreen products, their intended uses, and FDA’s regulation of them. 1. Terminology a. OTC drug review. The OTC Drug Review is the process established by FDA to evaluate the safety and effectiveness of OTC drug products marketed in the United States before May 11, 1972, and to establish the conditions under which they are considered to be GRASE and not misbranded. As described further below, the OTC Drug Review is generally conducted via a multiphase public rulemaking process (each phase requiring a Federal Register publication), resulting in the establishment of a monograph for an OTC therapeutic drug category. b. Generally recognized as safe and effective (GRASE). An OTC drug is ‘‘generally recognized as safe and effective’’ if it meets each of the conditions contained in an applicable OTC final monograph, the conditions contained in part 330 (21 CFR part 330), and any other applicable regulatory and statutory requirements for OTC drugs, including the labeling requirements in part 201. c. Proposed, tentative final, and final monographs. The proposed monograph, which is typically published in the form of an ANPR, is the end product of the first phase of the rulemaking process described above. After reviewing the report and recommendations of an expert advisory review panel responsible for initially reviewing the safety, effectiveness, and labeling of products in a given therapeutic category, FDA publishes a proposed monograph (together with the report and recommendations of the expert review panel) (see § 330.10(a)(6)). After PO 00000 Frm 00006 Fmt 4701 Sfmt 4702 a period of public comment, FDA publishes a tentative final monograph (TFM) (in the form of a proposed rule, proposing conditions under which OTC drugs in the therapeutic class being considered are GRASE and not misbranded (see § 330.10(a)(7)). Following public comment on the TFM, FDA publishes a final monograph in FDA’s regulations (see 21 CFR chapter I, subchapter D) codifying the conditions under which products in the OTC therapeutic drug category are GRASE and not misbranded (see § 330.10(a)(9)). An OTC drug may be legally marketed without an approved NDA or abbreviated new drug application (ANDA) if it meets each of the conditions contained in an applicable final monograph, the conditions contained in part 330, and any other applicable regulatory and statutory requirements for OTC drugs, including the labeling requirements in part 201. d. Category I, II, and III classifications. In the course of establishing an OTC monograph, active ingredients and other OTC drug conditions are classified in one of three categories: Category I (conditions under which a nonprescription drug in the therapeutic category would be GRASE and not misbranded), Category II (conditions that would result in the drug being classified as not GRASE and/ or misbranded) and Category III (conditions proposed to be excluded from the final monograph because available data are insufficient to classify them as either Category I or Category II) (see § 330.10(a)(6)). 2. OTC Sunscreen Products Regulated Under the OTC Drug Review and Their Intended Uses OTC sunscreen drugs regulated under the OTC Drug Review are topically applied products indicated to help prevent sunburn; some are also indicated to decrease the risk of skin cancer and early skin aging caused by exposure to the sun’s UV radiation (when used as directed with other sun protection measures) (see § 201.327(c)). The active ingredients in sunscreen products achieve these protective effects by absorbing, reflecting, and/or scattering radiation in the UV range (from 290 to 400 nanometers (nm)) (see section 586(10) of the FD&C Act (21 U.S.C. 360fff(10)); see also § 352.3(c) (21 CFR 352.3(c)), stayed). Sunscreen products must be labeled with an SPF value calculated using a standardized SPF testing procedure set forth in FDA regulations (in § 201.327(i)). As discussed in further detail in section IX.B.1, the SPF test E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules measures the amount of UV radiation exposure it takes to cause sunburn when a person is using a sunscreen when compared with how much UV exposure it takes to cause sunburn when the person is not using a sunscreen. Because SPF values represent a sunscreen’s level of sunburn protection, they are primarily (though not exclusively) an indicator of expected protection from UVB radiation (see section IX.B.1 for a discussion of both UVB and UVA radiation). To pass FDA’s current test for the inclusion of the term ‘‘broad spectrum’’ in labeling (which was established in the 2011 L&E Final Rule), sunscreen products must demonstrate that, in addition to UVB protection, they also provide UVA protection. Further, only products that have been demonstrated both to provide broad spectrum protection and to have a minimum SPF value of 15 have been shown to reduce the risk of skin cancer and early skin aging caused by the sun (when used as directed with other sun protection measures). By contrast, sunscreens that have not been demonstrated to provide both broad spectrum protection and an SPF value of at least 15 have only been demonstrated to help prevent sunburn.5 Thus, under the 2011 L&E Final Rule, passing the broad spectrum test in § 201.327(j) (21 CFR 201.327(j)) is necessary, but not itself sufficient, to support inclusion of a skin cancer indication in labeling, although any product that passes the broad spectrum test may be labeled with the term ‘‘Broad Spectrum’’ in conjunction with its SPF value. B. History of This Rulemaking 1. The OTC Sunscreen Drug Review and FDA’s Regulation of OTC Sunscreen Drug Products Our initial call for safety and efficacy data for sunscreen products was issued in 1972 (37 FR 26456, December 12, 1972). The resulting data submissions were reviewed by the Advisory Review Panel on OTC Topical Analgesic, Antirheumatic, Otic, Burn, and Sunburn Prevention and Treatment Products, whose panel report and recommended monograph were published as an ANPR in 1978 (43 FR 38206, August 25, 1978). The ANPR contained a list of the 21 5 As described in further detail in section IXB.2, in the time since the L&E Final Rule was issued in 2011, the body of evidence about the role of UVA radiation in the development of skin cancer has grown. As a result, FDA is making a number of proposals designed (among other things) to couple a greater magnitude of UVA protection to increases in SPF values. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 sunscreen active ingredients 6 that the panel recommended for classification as GRASE when used under the conditions described in the panel’s report (43 FR 38206 at 38219). In 1993, having reviewed the panel’s report and related public comments, FDA published a TFM (58 FR 28194, May 12, 1993) which (with one exception—padimate A) proposed as GRASE all of the active ingredients that had been included in the ANPR. The TFM also included specified maximum concentrations at which the proposed ingredients would be considered GRASE for use in sunscreens. In the years following the publication of the 1993 TFM, FDA removed several additional ingredients from the TFM (see 59 FR 29706, June 8, 1994), as described at 64 FR 27666 at 27681, and proposed the inclusion of two more.7 In 1999, FDA published a final sunscreen monograph, which included the following 16 sunscreen active ingredients along with the conditions (including maximum concentrations) under which these ingredients would be considered GRASE for use in sunscreens: 8 6 The ingredients were: Aminobenzoic acid, digalloyl trioleate, 2-ethylhexyl 2-cyano-3,3diphenylacrylate, glyceryl aminobenzoate, menthyl anthranilate, padimate O, sulisobenzone, cinoxate, dioxybenzone, ethylhexyl p-methoxycinnamate, homosalate, oxybenzone, 2-phenylbenzimidazole-5sulfonic acid, titanium dioxide, diethanoloamine pmethoxycinnamate, ethyl 4-[bis (hydroxylpropyl)] aminobenzoate, 2-ethylhexyl salicylate, lawsone with dihydroxyacetone, padimate A, red petrolatum, and triethanolamine salicylate. 7 In 61 FR 48645 (September 16, 1996) (proposing that avobenzone is GRASE up to 3 percent alone and 2 to 3 percent when in combination with cinoxate, diethanolamine methoxycinnamate, dioxybenzone, homosolate, octocrylene, octyl methoxycinnamate, octyl salicylate, oxybenzone, sulisobenzone, and/or trolamine salicylate) and 63 FR 56584 (October 22, 1998) (proposing that zinc oxide is GRASE alone or in combination with any previously proposed GRASE active ingredient except avobenzone). The list of active ingredients was (and would continue to be) modified because of, among other things, a lack of interest in developing United States Pharmacopeia (USP) compendial monographs for certain of the active ingredients originally proposed (see 64 FR 27666 at 27681). 8 See § 352.10, now stayed; 64 FR 27666. The active ingredient names used in that regulation, as originally published, differ from those used in table 1, which are the current established names for these active ingredients. We note that subsequent to the publication of the Stayed 1999 Final Monograph, we issued another final rule in 2002 amending the names used for four of those ingredients to make them consistent with the renaming of those ingredients in the corresponding USP monographs (67 FR 41821 at 41823, June 20, 2002). Under section 502(e) of the FD&C Act, drug labels are required to bear the established name of each active ingredient, and if FDA has not designated an official name under section 508 of the FD&C Act (21 U.S.C. 358), the compendial name is the established name. To comply with section 502(e) of the FD&C Act, sunscreen drug products must therefore bear the current compendial names for their active PO 00000 Frm 00007 Fmt 4701 Sfmt 4702 6209 TABLE 1—SUNSCREEN ACTIVE INGREDIENTS INCLUDED IN THE STAYED 1999 FINAL MONOGRAPH Active ingredient Aminobenzoic acid (PABA) .. Avobenzone .......................... Cinoxate ................................ Dioxybenzone ....................... Ensulizole ............................. Homosalate ........................... Meradimate ........................... Octinoxate ............................. Octisalate .............................. Octocrylene ........................... Oxybenzone .......................... Padimate O ........................... Sulisobenzone ...................... Titanium dioxide ................... Trolamine salicylate .............. Zinc oxide ............................. Maximum concentration (%) 15 3 3 3 4 15 5 7.5 5 10 6 8 10 25 12 25 Among other things, the Stayed 1999 Final Monograph established a minimum SPF value of 2, and an SPF of 30+ as the maximum labeled SPF value (64 FR 27666). FDA concluded that the above-listed ingredients (at the listed concentrations) could also be used in combination, with limited exceptions, provided that each active ingredient contributed a minimum SPF of 2 to the finished product (64 FR 27666).9 The effective date for complying with the Stayed 1999 Final Monograph was May 21, 2001. This deadline was extended (65 FR 36319, June 8, 2000) and then stayed until further notice (66 FR 67485, December 31, 2001) to provide additional time to resolve various outstanding issues, such as the labeling and testing of finished OTC sunscreen products. As a result, the ingredients, and the current compendial names are used throughout this document. Because the 2002 final rule that changed those names was published after part 352 was stayed, however, those amendments have not yet been incorporated into the published monograph regulation. 9 An exception to this rule involving avobenzone was retained from the TFM: The Stayed 1999 Final Monograph stated that avobenzone may not be combined with PABA, phenylbenzimidazole sulfonic acid, menthyl anthranilate, padimate O, titanium dioxide, or zinc oxide. In 2007, we proposed to include in the monograph a condition permitting the marketing of sunscreens containing avobenzone in combination with either zinc oxide or ensulizole based on safety and effectiveness data about these combinations provided to the docket (‘‘Sunscreen Drug Products for Over-the-Counter Human Use: Proposed Amendment of Final Monograph’’, 72 FR 49070 at 49074, August 27, 2007). As described in section VII.A, we now anticipate finalizing a monograph that would permit all listed active ingredients to be combined without limitation. This approach is consistent with the approach to sunscreen combinations generally taken throughout the OTC Drug Review for sunscreens. E:\FR\FM\26FEP2.SGM 26FEP2 6210 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules Stayed 1999 Final Monograph has never been in effect. In 2011, FDA published a draft guidance for industry, ‘‘Enforcement Policy—OTC Sunscreen Drug Products Marketed Without an Approved Application,’’ addressing the circumstances under which FDA intended to exercise its enforcement discretion with respect to certain marketed OTC sunscreen products in the period until a final OTC sunscreen monograph becomes effective. This guidance was finalized in May 2018 (2018 Final Guidance) (Ref. 1). Unless the failure to pursue regulatory action poses a potential health hazard to the consumer, FDA generally does not intend to object to the marketing of OTC sunscreen products that do not have an approved NDA or ANDA provided that they: (1) Contain as sunscreen active ingredients only the active ingredients or combinations of active ingredients listed in 21 CFR 352.10 and 352.20 (both currently stayed); (2) do not make claims addressed in §§ 201.327(c)(3) and (g) and 310.545(a)(29)(ii); (3) comply with the requirements for OTC drugs set forth in part 201 and § 330.1 (21 CFR 330.1), the requirements for adverse event reporting for OTC drugs set forth in the FD&C Act (see section 760 (21 U.S.C. 379aa)), and the provisions of the FD&C Act addressing adulteration; and (4) follow applicable labeling and testing requirements for OTC sunscreens set forth in § 201.327. 2. Recent Significant Rulemakings Relevant to This Proposed Rule Since publishing the Stayed 1999 Final Monograph, FDA has issued a number of Federal Register notices relating to OTC sunscreens. Major notices pertinent to today’s proposed rule are summarized briefly in table 2 below: TABLE 2—RECENT SIGNIFICANT Federal Register NOTICES PERTINENT TO THIS RULE Federal Register notice Information in notice Insect Repellent-Sunscreen Drug Prod- We issued a notice stating that we were considering amending the Stayed 1999 Final Monograph to include conditions for ucts for Over-the-Counter Human Use: marketing insect repellent-sunscreen drug products and requested information to form a regulatory position on these Request for Information and Comproducts. The Environmental Protection Agency, which regulates the insect repellent component of insect repellent-sunments; 72 FR 7941, February 22, 2007. screen combinations, published a similar notice concurrently with ours, also seeking information and comment on these products. Sunscreen Drug Products for Over-the- We proposed to amend the Stayed 1999 Final Monograph to address, among other things, formulation, labeling, and testCounter Human Use: Proposed ing requirements for both UVA and UVB radiation protection. Amendment of Final Monograph; 72 FR 49070, August 27, 2007. Labeling and Effectiveness Testing: Sun- We issued a final rule establishing labeling and testing requirements for sunscreen products. Among other things, the L&E screen Drug Products for Over-theFinal Rule established optional broad spectrum labeling, created an optional indication relating to decreasing the risk of Counter Human Use (L&E Final Rule); skin cancer and early skin aging for broad spectrum products with an SPF of 15 or higher, and required a labeling 76 FR 35620, June 17, 2011. warning for sunscreens that did not both satisfy the broad spectrum test and provide an SPF of at least 15. 2011 Proposed Rule: Revised Effective- We proposed to raise the limit on the maximum permissible labeled SPF value for sunscreen products to ‘‘50+.’’ Among ness Determination (Max SPF PR); 76 other things, we sought comment on the appropriateness of a formulation cap for sunscreen products. FR 35672, June 17, 2011. 2011 ANPR and Request for Data and We issued an ANPR describing the sunscreen dosage forms that we considered to be part of the OTC Drug Review and Information on Certain Dosage Forms; thus eligible for potential inclusion in a sunscreen monograph, as well as those dosage forms that we did not consider 76 FR 35669, June 17, 2011. eligible. We requested data to enable us to ensure that the administrative record would be adequate to support GRASE determinations for the eligible sunscreen dosage forms. In particular, we emphasized that additional safety and efficacy data would be needed to support final monograph status for spray dosage forms. We also announced that we were issuing a draft guidance document (discussed above) explaining the Agency’s intended enforcement policy for sunscreens marketed pursuant to the monograph system, including with respect to dosage forms. The Agency’s approach to enforcement of spray sunscreens is now described in the 2018 Final Guidance. IV. Scope of This Rulemaking Eligibility for inclusion in an OTC monograph was originally limited to active ingredients and other conditions that had been used in drugs marketed in the United States prior to the inception of the OTC Drug Review in 1972. After publication of the final sunscreen monograph in 1999, FDA published its TEA regulation (§ 330.14), (67 FR 3060 at 3074, January 23, 2002), which sets forth criteria and procedures by which OTC drugs initially marketed in the United States after the OTC Drug Review began and OTC drugs without any U.S. marketing experience can be considered for inclusion in the OTC drug monograph system. Congress later passed the SIA, which, among other things, supplements FDA’s TEA regulations for OTC sunscreen drug products (21 U.S.C. 360fff through 360fff–7) (2014). This proposed rule addresses the GRASE status (and conditions of use applicable to) sunscreen drug products VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 containing active ingredients listed in the Stayed 1999 Final Monograph. It does not address the pending sunscreen active ingredients that were originally submitted under the procedures established in the TEA regulation and are now being addressed through the SIA process.10 As discussed further in section VII, however, the safety data we described as necessary to evaluate the safety and effectiveness of sunscreen products containing those active ingredients are the same as what we are now describing as needed to establish that the active ingredients listed in the Stayed 1999 Final Monograph are GRASE for use in sunscreen products. We are not revisiting the contribution that the active ingredients listed in the Stayed 1999 Final Monograph make to the effectiveness of sunscreens. The Agency has not received information 10 FDA’s proposed sunscreen orders on each of these ingredients can be found at https:// www.fda.gov/drugs/guidancecompliance regulatoryinformation/ucm434843.htm. PO 00000 Frm 00008 Fmt 4701 Sfmt 4702 suggesting that it is necessary to revisit its prior decision about the effectiveness of the active ingredients at this time. V. Legal Authority We are issuing this proposed rule under sections 201, 301, 501, 502, 503, 505, 510, 586E, 701, 702, 703, 704, and 721 of the FD&C Act and under section 351 of the Public Health Service Act (42 U.S.C. 262). VI. Need for Additional Safety Information A. Increased Consumer Exposure to Sunscreen Active Ingredients Consumer exposure to sunscreen active ingredients has increased dramatically since FDA began its initial safety evaluations of the sunscreen active ingredients at issue in this proposed rule. Many factors have influenced this increase, including the following: E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules • Significant increases in the number and types of consumers using sunscreen products (Refs. 2 and 3) • Sunscreen products containing a greater number of active ingredients at greater concentrations (Ref. 4) • Increased awareness of the risks of sun exposure and encouragement of routine sunscreen use by medical and public health authorities (see, e.g., Ref. 5) • Evolving directions for use on sunscreen products instructing consumers to use greater amounts of sunscreen per application and to reapply sunscreen products more frequently (76 FR 35672 at 35678), codified as § 201.327) • Expanding availability and use of many different types of sunscreen products, including daily-use products such as facial makeup, moisturizing creams, and lipstick Relatively few sunscreen products were in use when the U.S. Army initially funded research into the development of effective sunscreen products for use by military personnel on aircraft carriers (and others routinely exposed to long periods of intense sunlight) during World War II (Ref. 2). The reach of sunscreen products began to broaden when they were later marketed for use specifically by consumers who sunburned readily (i.e., fair-skinned individuals) in situations of intentional sun exposure, such as sunbathing on a beach (Ref. 6). Sunscreen products are now routinely used by a much broader range of consumers for protection against many types of sun-induced skin damage, not just sunburn. Accumulating data demonstrate that increased sun exposure increases the risk of developing skin cancers and premature skin aging (Ref. 2). To help reduce the risk of these types of sun-induced skin damage, public health organizations (including FDA) have for years urged consumers to use sunscreen products along with other sun-protective behaviors like limiting time in the sun and wearing protective clothing (Refs. 7, 8, and 9). Another factor driving increased consumer exposure to sunscreen active ingredients has been the introduction and widespread adoption of sunscreen products with higher labeled SPF values. The maximum SPF value proposed for sunscreen labeling has progressively increased from SPF 15 in the 1978 panel report, to SPF 30+ in the Stayed 1999 Final Monograph, to SPF 50+ in the 2011 Max SPF PR. To achieve these higher SPFs, many currently marketed products are formulated with VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 more active ingredients combined together in higher concentrations than were generally combined in products when FDA’s review of OTC sunscreens began. Increased knowledge about the role of UVA radiation in causing skin damage has also encouraged the formulation of broad spectrum products with combinations of active ingredients designed to achieve protection against both UVA and UVB radiation. In addition, other widely used products, such as facial makeup, moisturizing creams, and lipsticks, have had sunscreen active ingredients added to their formulations. These trends are reflected in the evolution of the current labeling provisions for sunscreen products regulated under the OTC monograph system. Changes in the instructions for using these sunscreen products have also contributed to increased use of, and exposure to, sunscreen active ingredients. The labeling recommended by the advisory panel in 1978 simply instructed consumers to apply sunscreen products liberally and to reapply after swimming or excess perspiration (43 FR 38206 at 38215). The labeling currently required, by contrast, encourages consumers to always use a broad spectrum SPF 15 or higher product, to use sunscreen products regularly, and to apply them generously/liberally 15 minutes before sun exposure and at least every 2 hours or more frequently when swimming or sweating (§ 201.327(e)). B. Emerging Safety Concerns In recent years, a growing body of data has suggested that the transdermal absorption of some sunscreen active ingredients is greater than previously thought, and thus may raise previously unevaluated safety concerns, including the potential for reproductive, developmental, or carcinogenic effects. As discussed in further detail in section VIII.C.1.a, newly available information suggests, for example, that there is the potential for toxicity associated with the transdermal absorption and systemic availability of oxybenzone. This new information about absorption and potential safety risks is inadequate, by itself, to support an affirmative conclusion that products containing the active ingredients at issue are not safe. Coupled with the lack of clinical pharmacology and nonclinical safety data for certain sunscreen active ingredients, however, it leads us to conclude that, for some sunscreen active ingredients, the current record does not include adequate evidence of safety to satisfy the applicable legal standards for PO 00000 Frm 00009 Fmt 4701 Sfmt 4702 6211 general recognition of safety and effectiveness as set forth in § 330.10. VII. Framework for Evaluation of Safety Data In light of these safety concerns, FDA held a meeting of its Nonprescription Drugs Advisory Committee (NDAC) on September 4 and 5, 2014, to discuss the scope of safety testing that should be conducted to support general recognition of safety and effectiveness for active ingredients for use in nonprescription sunscreen products. FDA proposed the following safety testing paradigm: Clinical data: • Dermal irritation and sensitization testing • Phototoxicity and photoallergenicity testing • Human maximal use bioavailability studies • Postmarketing adverse event reports Nonclinical (toxicology) data: • Dermal carcinogenicity • Systemic carcinogenicity • Developmental and reproductive toxicity (DART) • Toxicokinetics • Additional testing when data suggest a concern about other longterm effects, such as endocrine effects There was consensus among the committee members that FDA’s proposed framework was a good starting point (Ref. 10). In November 2015, FDA published a draft guidance for industry, ‘‘Over-the-Counter Sunscreens: Safety and Effectiveness Data’’ (Draft Safety and Effectiveness Data Guidance) (see 80 FR 72975, November 23, 2015), which described and requested comment on the safety and effectiveness data necessary to determine whether an OTC sunscreen active ingredient or combination of active ingredients evaluated under the SIA was GRASE when used under specified conditions. FDA finalized this guidance in November 2016, after considering public comment on its draft recommendations (Ref. 11).11 The recommendations in this guidance reflect FDA’s scientific expertise, existing technical guidance, experience from reviewing safety and efficacy data submitted for GRASE review of sunscreen active ingredients under the OTC Drug Review, and input from and 11 FDA’s recommendations regarding the safety and effectiveness data necessary to determine whether an OTC sunscreen active ingredient (or combination of ingredients) evaluated under the SIA was GRASE when used under specified conditions generally remained unchanged in the final guidance. E:\FR\FM\26FEP2.SGM 26FEP2 6212 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules concurrence by outside scientific experts. All sunscreens marketed without an NDA are subject to the same standard: General recognition of safety and effectiveness. Accordingly, as noted previously, the data that we expect to be necessary to evaluate the safety and effectiveness of the sunscreen monograph active ingredients are the same as those we recommended as necessary to evaluate the safety and effectiveness of sunscreen active ingredients previously considered under the procedures established in the TEA regulation and now being considered pursuant to the framework established by the SIA (see Safety and Effectiveness Data Guidance (Ref. 11)). The studies described in this section are generally needed for FDA to determine that a sunscreen active ingredient is GRASE for use in nonprescription sunscreens. Specific data gaps for individual active ingredients depend on the quality and quantity of available safety data, and are identified in section VIII. As described in that section, those active ingredients for which the existing public record contains sufficient data to support a positive GRASE finding are proposed as Category I. Those for which additional data are necessary are proposed as Category III. In addition, in evaluating the existing safety data for the active ingredients listed in the Stayed 1999 Final Monograph, FDA determined that the risks associated with two of these ingredients outweigh their benefits. As discussed in further detail in section VIII.B, FDA is therefore proposing that these two ingredients are Category II because sunscreens containing these ingredients would not be GRASE. A. General FDA’s OTC drug regulations identify the general types of safety information that should be submitted as evidence that an OTC drug is GRASE for use as labeled (§ 330.10(a)(2)) and the standard by which safety is to be judged (§ 330.10(a)(4)(i)). When applying these regulations to each drug, FDA uses its scientific expertise to determine what constitutes ‘‘adequate tests by methods reasonably applicable to show the drug is safe under the prescribed, recommended, or suggested conditions of use’’ (§ 330.10(a)(4)(i)). FDA recognizes the contribution that broad spectrum sunscreens with an SPF value of 15 or higher can make to decreasing the risk of skin cancer and early skin aging caused by the sun if used as directed with other sun protection measures. To protect the public health, however, it is also VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 important for FDA to balance the potential benefits of these sunscreen products to consumers against their potential risks. Providing an adequate safety margin for OTC sunscreen active ingredients and finished sunscreen products is a key element of FDA’s risk assessment. A safety margin calculation takes the highest animal NOAEL and estimates a maximum safe level of exposure for humans. Because animal studies do not always predict effects in humans, the actual threshold for an effect in humans may be different (i.e., higher or lower) than in the species tested. The human sensitivity to a drug is often unknown. To account for this, the predicted safe exposure level in humans that is reflected in the safety margin is well below where toxicities were seen in animals. In determining the specific testing and other data needed to adequately demonstrate that an OTC sunscreen active ingredient is safe, FDA considers both the circumstances under which OTC sunscreen products are intended to be used by consumers (i.e., the conditions of use) and current scientific knowledge and assessment technology. FDA’s approach to the clinical safety evaluation of OTC sunscreen active ingredients is based on our current scientific understanding regarding safety evaluation of topical drug products for chronic use, and thus is generally consistent with the safety data requirements that would apply to an NDA for a chronic-use topical drug product (i.e., topical safety studies (irritation, sensitization, and photosafety); bioavailability (absorption); and evaluation of adverse events observed in clinical studies).12 In addition, the evaluation of adverse events reported during the commercial marketing of sunscreen products containing the ingredient and other postmarketing safety information is also relevant to safety. FDA’s approach to the nonclinical safety evaluation of these active ingredients takes into account their lengthy marketing history in the United States. In contrast to nonclinical data requirements for a chronic-use topical drug product NDA, which include results from comprehensive nonclinical pharmacology and toxicology safety testing, the approach to nonclinical safety testing in this proposed rule is largely focused on potential long-term adverse effects or effects not otherwise readily detected from human use (i.e., carcinogenicity and reproductive 12 Chronic use is defined as continuous or intermittent use for at least 6 months during the course of a lifetime. PO 00000 Frm 00010 Fmt 4701 Sfmt 4702 toxicity). Additional testing beyond what is described below may be recommended for active ingredients for which data suggest a concern about other long-term effects, such as hormonal disruption. In addition, although sunscreen products are typically formulated with two or more active ingredients, the framework described below contemplates that testing will be performed using formulations that include one active ingredient. Generally, unless data suggest that there may be a safety or efficacy concern with a particular combination of active ingredients, we anticipate that an active ingredient that is found to be GRASE for use in sunscreens could be combined with other active ingredients that are also GRASE for use in sunscreens. If data suggest that there may be a safety or efficacy concern with a particular combination of active ingredients (or active and inactive ingredients), additional data may be necessary to support a positive GRASE determination for sunscreens containing that combination. The following sections describe the specific safety data that FDA expects the Agency will need to determine whether an active ingredient is GRASE for use in sunscreens. B. Clinical Safety Testing 1. Human Dermal Safety Studies Human dermal safety studies for topical products in which exposure to light after application is anticipated generally consist of two sets of studies— those conducted without specific exposure to light and those conducted to assess reactions after UV exposure (photosafety studies) (Ref. 12). The studies usually consist of dermal irritation patch testing, dermal sensitization patch testing, dermal phototoxicity testing, and dermal photoallergenicity testing. Because marketed sunscreen products typically contain a combination of active ingredients, and product formulations frequently change, it is difficult to determine causal links between individual active ingredients and reported irritation and hypersensitivity adverse events associated with a particular product. Therefore, FDA generally expects to use data from human dermal irritation studies, human dermal sensitization studies, and human dermal photosafety studies, in conjunction with postmarketing adverse event data, to inform GRASE determinations and labeling. Nonetheless, in some cases, it may be reasonable to omit human E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules dermal irritation studies, human dermal sensitization studies, and/or human dermal photosafety studies, depending on the rigor of available postmarketing safety information. For example, if FDA concludes that there is a positive riskbenefit profile for a sunscreen active ingredient, but that it is known to be a sensitizer, it may be possible to develop safety labeling to address this risk without data generated in the human dermal safety studies described below (see, e.g., section VIII.C.1.a). a. Human dermal irritation and sensitization studies. Studies of dermal irritation and sensitization, using the repeat insult patch test or other relevant tests, are elements in the safety evaluation of topical drug products that, like sunscreens, are applied to the skin repeatedly over long periods of time. Designed to detect the potential for local dermatologic events with fewer subjects than might be observed in larger clinical trials, these tests often employ product application that is more frequent and/or for longer duration than proposed clinical dosing. In dermal irritation studies, a test substance is applied to a small pad (patch) and affixed to the test subject’s skin, usually on the back, to determine whether the ingredient causes direct skin toxicity. Dermal sensitization studies are conducted similarly but are designed to detect immunologically mediated reactions, which require prior exposure to the allergen. Nonprescription sunscreens regulated under the OTC monograph system may be used in many product formulations, including those yet unknown. Therefore, cumulative irritation studies that evaluate the sunscreen active ingredient at the highest concentration for which a GRASE determination is sought should be conducted using the ingredient in an appropriate vehicle, using the vehicle alone, and using both negative and positive controls. The evaluation should include scoring of erythema, edema, and a papular response or skin erosion. Dermal sensitization studies, conducted to detect immunologically mediated reactions, should be conducted in three phases: (1) The induction phase (3 weekly applications for 3 weeks); (2) the rest phase (no product application for 10 to 14 days); and (3) the challenge phase (patch applications to new sites for 48 hours with a confirmatory rechallenge to exclude false positives). Although FDA recommends separate dermal irritation and sensitization studies, it may be appropriate to combine irritation and sensitization studies in the same study as long as a VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 sufficient number of subjects are included for sensitization evaluation. b. Human photosafety studies. Topically applied dermatologic drug products should be tested for photosafety if they absorb light in the UVA, UVB, or visible spectra. Photosafety evaluations of sunscreen active ingredients that absorb light should consist of skin photoallergenicity and skin phototoxicity testing. Photoallergy is an immunologically mediated reaction to a chemical, initiated by the formation of photoproducts (e.g., protein adducts) following a photochemical reaction. Similar to dermal sensitivity testing described above, photoallergy tests use an induction/rest/challenge/rechallenge multiphase design to assess erythema, edema, and vesiculation. Phototoxicity (or photoirritation) is an acute lightinduced tissue response to a photoreactive chemical. Phototoxicity testing typically includes a test patch, a vehicle patch, and a sham patch application for 24 hours, followed by UV light exposure of the test area. A second set of patch application areas not irradiated with light serves as a control. FDA expects that, to support a GRASE finding, photosafety studies of sunscreen active ingredients that absorb light will need to be conducted using the active ingredient at the highest concentration for which a GRASE determination is sought in an appropriate vehicle, using the vehicle alone, and with a negative control. 2. Human Absorption Studies/Maximal Usage Trial Because nonprescription sunscreens are topically applied, a critical safety consideration is whether dermal application results in skin penetration and systemic exposure to their active ingredients and, if so, to what extent. This information helps identify potential safety concerns and helps determine whether an adequate safety margin exists within which an active ingredient is GRASE for use in sunscreens. The principal barrier to topical drug product penetration is the multilayered, lipid-rich stratum corneum. The passage of any drug product through this layer is influenced by many factors, including the drug product’s physicochemical features, molecular weight, and vehicle/ formulation properties. Vehicle/ formulation properties are particularly important because the choice of vehicle can markedly affect the permeation potential of a drug product. Effects can range from simple hydration of the stratum corneum by occlusive vehicles/ formulations to direct permeation PO 00000 Frm 00011 Fmt 4701 Sfmt 4702 6213 enhancement by solvent effects on the lipids in the stratum corneum. Products absorbed through the skin have the potential to cause systemic adverse effects, affecting the safety assessment. Because sunscreens are intended to work at the skin’s surface, systemic absorption may also lower efficacy, affecting the efficacy assessment. Such considerations ultimately weigh into the risk-benefit calculus FDA uses to determine whether an OTC sunscreen containing a given active ingredient is GRASE. Since the mid-1990s, topical product NDAs have included a Maximal Usage Trial (MUsT) as part of the clinical pharmacology/bioavailability assessment. A MUsT is designed to capture the effect of maximal use on absorption into the blood with standard pharmacokinetic assessments (e.g., Cmax, Tmax,13 area under the curve, half-life, clearance, and volume of distribution) (for further information about conduct of a MUsT, see Ref. 13). For a topical product NDA, the MUsT is usually conducted in subjects with the disease of interest, where disrupted skin is a feature. In situations where disrupted skin is not a feature of the condition being treated or the topical product is intended for prevention of disease (e.g., sunscreens), the MUsT for a topical product NDA should be conducted in subjects with healthy, intact skin. The MUsT for a topical product NDA is conducted with the specific product formulation for which approval is sought applied at the upper limit of surface area involvement that is studied in the phase 3 clinical trials and is proposed for labeling. For example, if the proposed labeling of an acne product permits the product to be used on up to 30 percent of body surface area, that would be the coverage evaluated in the MUsT. We expect that data from a MUsT will be needed to support an adequate assessment of safety for most sunscreen active ingredients (Ref. 10). Because sunscreen products regulated pursuant to the OTC monograph system may include active ingredients in a variety of formulations, FDA recommends that a MUsT be conducted under maximal use conditions employing a minimum of four formulations, containing the sunscreen active ingredient as the only active ingredient.14 These formulations 13 C max is the peak plasma concentration and Tmax is the time to peak plasma concentration. 14 We note, however, as described in section VIII.C.1.b, that because of avobenzone’s potential for photodegradation, we recommend that a MUsT for avobenzone evaluate avobenzone in combination with a photostabilizer. In some cases, E:\FR\FM\26FEP2.SGM Continued 26FEP2 6214 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules should be prepared using vehicle/ formulation systems that are appropriate for sunscreen topical products (e.g., they are deployable and spreadable) that represent real-world marketed formulations, and that are expected to produce the highest in vivo absorption. Justification for the formulations chosen, including results of in vitro testing using a human cadaver skin permeation system (e.g., static cell, also known as vertical diffusion cell) (Refs. 14 and 15), should be included in the study protocol. The protocol should contain sufficient detail for others to reproduce the formulations and manufacturing process.15 FDA anticipates that the use of multiple formulations will help identify the overall absorption potential of the sunscreen active ingredient of interest. The MUsT should be conducted in subjects with healthy, intact skin 16 at the highest concentration of the ingredient for which a GRASE determination is sought. Based on recommended sunscreen use on all exposed skin, the exposed area should include at least 75 percent of the body surface area. Data from the formulation that produces the highest in vivo absorption would then be used to determine the safety margin. The assay used in the MUsT should be properly validated according to current good laboratory practices (21 CFR part 58). Additionally, the Agency’s most current guidance on bioanalytical method validation may be found by searching at https://www.fda.gov/ RegulatoryInformation/Guidances/ default.htm. The assay’s limit of quantitation-limit of detection should be sufficiently low to allow a signal-tonoise ratio that ensures confidence in detection of a concentration of 0.5 nanogram (ng)/milliliter (mL) for the compound of interest in the receptor fluid. An important consideration for designing a MUsT is that it should include testing for a duration that allows for the attainment of steady state levels to ensure that maximum sunscreen active ingredients (e.g., octocrylene) can serve as photostabilizers. In such cases, we expect that the MUsT could include such ingredients. 15 FDA has issued draft guidance with recommendations for the conduct of MUsT studies to support the safety of active ingredients that are candidates for inclusion in a topical drug product under an OTC Drug monograph (Ref. 16). When finalized, this guidance will represent FDA’s current thinking on this topic. FDA also encourages persons who are interested in conducting a MUsT to support the safety of an active ingredient to discuss proposed protocols with the Agency. 16 As discussed infra, the MUsT should be conducted on healthy, intact skin because sunscreens are intended for prevention rather than treatment. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 penetration of the ingredient has taken place and to optimize the chances of the ingredient being detected. Thus, for sunscreen active ingredients, FDA expects that single application studies would be inadequate. Because the subjects in a MUsT represent an enriched dataset in the upper range of exposures, safety-related data (such as vital signs, adverse events) from the study’s regularly scheduled physical examinations should also be collected. We strongly encourage consultation with FDA about MUsT protocols before beginning the trial. Finally, as discussed further in section VIII.D, if the sunscreen active ingredient is determined to be GRASE for use in sunscreens, the sunscreen monograph, when finalized, must set out the conditions under which any future sunscreen containing that active ingredient will be GRASE and not misbranded. As such a condition, FDA is considering certain final formulation testing to address the potential for transdermal absorption and its impact on safety. FDA anticipates that the formulation that produces the highest in vivo absorption in the MUsT would be appropriate to designate as a standard control formulation for future in vitro human cadaver skin permeation system testing (e.g., a static or vertical diffusion cell) of each final sunscreen formulation that includes that active ingredient. If such testing were included as a condition in a final sunscreen monograph, and if in vitro permeation of the sunscreen active ingredient in the final product formulation were equal to or less than the value from in vitro testing of the standard control formulation (that was shown by the MUsT to have the highest degree of systemic absorption), FDA anticipates that the safety margin previously calculated would be considered adequate to support the safety of the finished formulation. 3. Pediatric Considerations Young children have a larger ratio of skin surface to body volume than adults, which can increase a child’s systemic exposure to topically applied drug products. In addition, growing children have greater potential to experience deleterious developmental effects from drug exposure. If the calculated safety margin for an active ingredient (based on nonclinical results and human MUsT) is relatively small, FDA will exercise its scientific judgment to determine whether a sunscreen active ingredient MUsT in young children or other studies are warranted to ensure that the safety margin for marketed products containing the ingredient is PO 00000 Frm 00012 Fmt 4701 Sfmt 4702 within an acceptable range for this population. C. Nonclinical Safety Testing 1. Carcinogenicity Studies: Dermal and Systemic FDA generally recommends carcinogenicity studies for any pharmaceutical with an expected clinical use (either intermittent or continuous) of at least 6 months (Ref. 17). The animal carcinogenicity studies help characterize the potential tumor risks associated with use of a sunscreen active ingredient in human beings by identifying any observed tumors by type, the level of exposure at which tumors occur, and the highest level of exposure at which no adverse effects occur, referred to as the NOAEL. As noted earlier, FDA intends to use the NOAEL in determining the safety margin for human exposure to sunscreens containing the active ingredient. In addition to detecting carcinogenic potential, carcinogenicity studies in animals can also help to identify other systemic or organ toxicities that may be associated with the sunscreen active ingredient. FDA expects that a dermal carcinogenicity study involving application of the test article to the skin of mice or rats for 2 years will thus need to be conducted to support a GRASE finding for the active ingredient unless the ingredient has been demonstrated not to reach the viable layers of the skin where it could impact skin tumor development. FDA also considers it important to study the effects of systemic exposure if human bioavailability data show that dermal application of a particular formulation results in skin penetration and systemic exposure to the active ingredient. Therefore, we expect that a second carcinogenicity study by a route that produces systemic exposure will also be needed to support the safety of a sunscreen active ingredient, if systemic exposure is observed in the bioavailability data. This can be a 2-year study or a shorter (usually 6 months) alternative carcinogenicity model, and it should be conducted in a species different from that used in the dermal carcinogenicity study. FDA notes that the absence of a carcinogenicity signal from an alternative transgenic carcinogenicity study (e.g., TgRasH2 mouse) would likely support the safety of a sunscreen active ingredient. If a carcinogenicity signal were observed in such a study, however, the study could not be used to support the safety of a sunscreen active ingredient because there would be no basis for calculating E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules a safety margin with this study (Ref. 18). All carcinogenicity studies, regardless of route, should assess a full panel of tissues.17 FDA expects that a systemic carcinogenicity study would not be needed to support a GRASE determination for a sunscreen active ingredient if an adequately conducted human pharmacokinetic MUsT resulted in a steady state blood level less than 0.5 ng/mL, and an adequately conducted toxicology program did not reveal any other safety signals for the ingredient or any known structurally similar compound indicating the potential for adverse effects at lower levels. The threshold value of 0.5 ng/mL is based on the assessment that the level would approximate the highest plasma level below which the carcinogenic risk of any unknown compound would be less than 1 in 100,000 after a single dose. This threshold value is consistent with the Threshold of Toxicological Concern concept, which was applied to impurities in the ICH guidance for industry ‘‘M7 Assessment and Control of DNA Reactive (Mutagenic) Impurities in Pharmaceuticals to Limit Potential Carcinogenic Risk’’ (Ref. 19). FDA expects that the 0.5 ng/mL concentration will be sufficiently above the assay’s limit of quantitation—limit of detection to allow a signal-to-noise ratio that ensures confidence in either the derived concentrations (in the case of ‘‘exaggerated’’ values) or lack of concentrations. 2. Developmental and Reproductive Toxicity Studies FDA expects that DART studies will need to be conducted to evaluate the potential effects that exposure to the sunscreen active ingredient may have on developing offspring throughout gestation and postnatally until sexual maturation, as well as on the reproductive competence of sexually mature male and female animals (Ref. 20). As with systemic carcinogenicity studies, we expect that studies to assess fertility and early embryonic development, and pre- or postnatal toxicity in rats will not be needed if an adequately conducted human MUsT shows a steady state blood level less than 0.5 ng/mL, and an adequately 17 FDA recommends submitting the carcinogenicity study protocol(s) for review by FDA’s Center for Drug Evaluation and Research’s (CDER’s) Executive Carcinogenicity Assessment Committee before initiating the studies. For further guidance regarding carcinogenicity studies, see the FDA guidance for industry ‘‘Carcinogenicity Study Protocol Submissions,’’ May 2002 (available at https://www.fda.gov/ucm/groups/fdagov-public/ @fdagov-drugs-gen/documents/document/ ucm078924.pdf). VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 conducted toxicology program produces no signals indicating that the ingredient (including its clinically relevant metabolites) or any known structurally similar compound interacts with related pathways.18 We expect that effects on embryofetal development will need to be assessed in rats and rabbits in all cases. Gestational and neonatal stages of development may be particularly sensitive to active ingredients with hormonal activity (endocrine disruption). For this reason, these studies should include assessments of endpoints such as vaginal patency, preputial separation, anogenital distance, and nipple retention, which can be incorporated into traditional DART study designs to assess potential hormonal effects on the developing offspring. Behavioral assessments (e.g., mating behavior) of offspring, which may detect neuroendocrine effects, should also be performed (Ref. 21). 3. Toxicokinetics (Ref. 22) Animal toxicokinetic data should also be collected for sunscreen active ingredients, as these data provide an important bridge between toxic levels seen in animal studies and any potential human adverse events associated with systemic exposure to the sunscreen’s active ingredient. Toxicokinetic measurements are usually obtained during the course of ongoing nonclinical toxicity studies, such as carcinogenicity or DART studies, rather than through separate studies. D. Postmarketing Safety Data In addition to the active ingredient safety data already described, FDA’s GRASE evaluation also takes into consideration publicly available information about serious adverse drug experiences and known or expected adverse effects associated with commercially marketed products that contain the active ingredient(s) under consideration. E. Sunscreens Containing Nanomaterials We note that FDA is not proposing to categorically classify sunscreen products manufactured using nanotechnology (or containing nanomaterials) as GRASE or not GRASE solely based on this characteristic. Nanotechnology is used to create, explore, or manipulate materials measured in nanometers (nm) (billionths of a meter), and has 18 Examples of such pathways could include endocrine function and signaling pathways related to growth and development. PO 00000 Frm 00013 Fmt 4701 Sfmt 4702 6215 applications in a wide range of products, including OTC sunscreens. Such materials generally have dimensions between approximately 1 and 100 nm (Ref. 23). Materials at such small sizes can have different chemical or physical properties or biological effects compared to larger-scale counterparts, making possible a variety of functional effects, and also potentially affecting the safety, effectiveness, or regulatory status of FDA-regulated products. FDA has not established regulatory definitions of nanotechnology, nanomaterial, nanoscale, or other related terms. As described in FDA’s guidance for industry ‘‘Considering Whether an FDA-Regulated Product Involves the Application of Nanotechnology’’ (Nanotechnology Considerations Guidance) (Ref. 24), at this time, when considering whether an FDA-regulated product involves the application of nanotechnology, FDA asks (1) Whether a material or end product is engineered to have at least one external dimension, or an internal or surface structure, in the nanoscale range (approximately 1 nm to 100 nm). In addition, because materials or end products can also exhibit related properties or phenomena attributable to a dimension(s) outside the nanoscale range of approximately 1 nm to 100 nm that are relevant to evaluations of safety, effectiveness, performance, quality, public health impact, or regulatory status of products, we will also ask: (2) Whether a material or end-product is engineered to exhibit properties or phenomena, including physical or chemical properties or biological effects, that are attributable to its dimension(s), even if these dimensions fall outside the nanoscale range, up to 1 micrometer (mm) (1,000 nm). We will apply these considerations broadly to all FDA-regulated products, including sunscreen products. For the purpose of this proposed rule, we use the term ‘‘nanomaterial’’ generally to refer to materials falling within either point 1 or 2 above. The use of this term in this manner is consistent with its use in FDA’s nanotechnology-related guidances, including FDA’s Nanotechnology Considerations Guidance. Nanomaterial forms of the active ingredients zinc oxide and titanium dioxide have been used in marketed OTC sunscreens. In addition to nanomaterial forms of zinc oxide and titanium dioxide, other nanomaterials are also reported to have been used, or promoted or studied for possible use, in sunscreen products (Ref. 25). E:\FR\FM\26FEP2.SGM 26FEP2 6216 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules As discussed in further detail in section VIII.A, having examined the scientific information in the record, including for nanomaterial forms of zinc oxide and titanium dioxide, FDA is not now proposing conditions of use for these two active ingredients under the sunscreen monograph that distinguish nanomaterials from other forms of these ingredients. As indicated above, FDA also does not propose to categorically classify sunscreen products that are manufactured using nanotechnology or contain nanomaterials as GRASE or not, solely on that basis. Manufacturers of products containing nanomaterials marketed under the OTC sunscreen monograph remain responsible for ensuring that the product satisfies all applicable legal requirements. FDA encourages manufacturers of such products to consult with FDA to facilitate a mutual understanding of specific scientific or regulatory issues relevant to their product. FDA invites comment on the following topics: • Specific nanomaterials or types of nanomaterials that have been used or proposed for use in OTC sunscreen products • Concerns about sunscreen product safety, effectiveness, or quality associated with the use of nanomaterials in OTC sunscreen products, with supporting data • Need for, and proposals of, specifications or limitations for particular nanomaterials for use in OTC sunscreen products • Any particular nanomaterials that you believe should not be permitted for use in OTC sunscreen products, along with supporting scientific information • FDA’s proposed regulatory approach and/or alternative regulatory approaches to the use of nanomaterials in OTC sunscreen products VIII. Existing Safety Data for Sunscreen Active Ingredients In the remainder of this section, we discuss the existing data and data gaps for each of the sunscreen monograph active ingredients and explain why we propose that these active ingredients are GRASE or not GRASE for use in sunscreens. Those ingredients for which the existing data are sufficient to support a positive GRASE determination are proposed as Category I. Those ingredients for which additional data are necessary before a GRASE determination can be made are proposed as Category III. In cases where FDA’s evaluation of the existing safety data caused us to determine that the risks associated with the ingredients VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 outweigh their benefits, the ingredients are proposed as Category II. A. Ingredients Proposed as Category I Based on our review of the publicly available data for these ingredients, both zinc oxide and titanium dioxide are proposed as Category I. 1. Zinc Oxide Our review of the scientific literature, submissions to the sunscreen monograph docket, and adverse event reports submitted to FAERS has produced sufficient safety data on zinc oxide to support a proposal that a sunscreen containing up to 25 percent zinc oxide would be GRASE under the conditions proposed in this rulemaking and the general conditions required in part 330. This proposal is based in significant part on the existing, substantial evidence that zinc oxide (including particles on the nanoscale, i.e., approximately 1 to 100 nm) does not penetrate into or through human skin to any great extent and, to the extent any de minimis penetration occurs, does not result in adverse health effects, given the high levels of endogenous zinc in the human system. a. Background. Zinc oxide is an inorganic, mineral compound. Because of its ability to reflect UVA wavelengths, zinc oxide is frequently used in sunscreens to help establish broad spectrum protection (Ref. 26). While larger particles of zinc oxide used in sunscreens (greater than approximately 100 nm) may impart an opaque, white color to the product, zinc oxide is also manufactured in smaller particle sizes (less than approximately 100 nm) to reduce this white/opaque appearance (Refs. 27 and 28). In addition to its use in sunscreens, zinc oxide is also used in non-sunscreen ointments, pastes, and lotions for various skin disorders because of its protective, astringent, and antiseptic properties (Ref. 29). b. Discussion. Zinc oxide is insoluble in water and largely insoluble in biological fluids.19 This insolubility precludes the possibility of its systemic absorption from topical application of sunscreen products beyond a de minimis amount, even if zinc oxide is included at its maximum eligible concentration of 25 percent and regardless of the formulation of the product. The available studies on the dermal penetration of zinc oxide, further discussed below, confirm that its 19 We note that nanoscale zinc oxide can be solubilized to a small extent in the presence of phosphate and lecithin at pH’s that are achievable on the skin. Even under these conditions, however, the amount potentially absorbed is de minimis and far lower than daily nutritional intake of zinc. PO 00000 Frm 00014 Fmt 4701 Sfmt 4702 penetration—regardless of particle size—is primarily limited to the upper layers of the non-living stratum corneum, with most penetration occurring only into skin folds and furrows or hair follicles. These studies show that zinc oxide particles do not penetrate down into the viable dermis to any significant extent. Any de minimis transdermal penetration that may occur does not result in adverse health effects, because the tiny amount of zinc oxide particles that achieve transdermal absorption, if any, would dissociate into zinc and oxygen ions, both of which are naturally occurring elements in the human body (Ref. 30). Zinc is the 14th most common element in the human body and is essential for all living things; the average human body contains about 2.0 to 2.5 grams of zinc, and normal dietary intake of zinc is about 15 milligram (mg) per day (Refs. 30 and 31). Homeostatic mechanisms in the body regulate zinc’s absorption, distribution, cellular uptake, and excretion (Ref. 31). Similarly, any oxygen absorbed through the skin is nonharmful, as oxygen is plentiful in the human body and essential for life. Our search of the literature on zinc oxide revealed four recent studies about zinc oxide’s penetration into human skin, which confirm our expectations based on the physical properties of this compound. The first two studies (conducted by Leite-Silva et al. and Darvin et al.) examined the penetration of zinc oxide into the skin using multiphoton tomography (Refs. 32 and 33). Both studies showed a lack of overall permeation of zinc oxide beyond a few cell layers, except in the case of furrows and wrinkles (Refs. 32 and 33). The second two studies—a pilot and subsequent full trial conducted by Gulson et al.—evaluated the penetration of nanoscale zinc oxide into the skin and the bloodstream using a stable isotope tracing method (Refs. 34 and 35). Although the Gulson studies found that a minimal amount of topically applied zinc was absorbed, the absorption observed was at levels that are orders of magnitude less than daily nutritional intake and well below what would be of concern for a naturally occurring element in the body subject to homeostatic mechanisms (Ref. 36). An additional porcine study found (as discussed in our 2012 response to a citizen petition submitted by the International Center for Technology Assessment and others (Docket No. FDA–2006–P–0213–0003) (ICTA Petition Response)), that although sunburn caused by UVB rays increased the penetration of zinc oxide into the E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules non-living stratum corneum, there remained minimal penetration of zinc oxide into the epidermal and dermal layers of the skin (Ref. 37). Because topically applied zinc oxide particles do not enter systemic circulation to any meaningful extent, we do not consider a MUsT to be necessary to support the safety of this ingredient. In addition to the studies described above, we also located two studies evaluating the clinical safety of topically applied zinc oxide in which zinc oxide (25 percent) was used as a medicated occlusive dressing on the lower arms of healthy volunteers (Refs. 38 and 39). In these studies (which were designed to maximize potential absorption and identify any resulting adverse events), even with the increased dermal or epidermal zinc levels resulting from occlusion, there still were no adverse skin events. Our review of the available human dermal safety studies on zinc oxide 20 also identified data showing that test material containing up to 25 percent zinc oxide did not induce human irritant, photoirritant, allergic, or photoallergic reactions. No human pathological phototoxicity or significant human photosensitization reaction indicative of skin irritation were noted either. The literature supporting the safety of skin protectant drug products containing zinc oxide 21 reinforce these clinical safety findings. Our review in this area is also consistent with the conclusion of the European Commission’s Scientific Committee on Consumer Safety that the use of nanoscale zinc oxide in sunscreens at a concentration of up to 25 percent does not pose a risk of adverse effects in humans after topical application (Ref. 40). A very small number of rash and hypersensitivity reports for sunscreens containing zinc oxide were located in FAERS. With a single exception, the sunscreens involved contained two or 20 This literature included three clinical safety studies conducted by Hill Top Research, Inc. for Procter & Gamble regarding (a) human sensitization (Study Reports 96–6635–76a and 96–6635–76b); (b) human photoirritation/phototoxicity (Study Report 96–6634–76); and (c) human photoallergenicity (Study Report 96–6633–76). See Citizen Petition submitted by Proctor & Gamble, June 24, 1997 (FDA–1978–N–0018–0639) and the ‘‘Opinion concerning Zinc Oxide’’ drafted by the European Commission, Scientific Committee on Cosmetic Products and Non-Food Products Intended for Consumers (SCCNFP), which included five summaries of human clinical safety studies, all evaluating zinc oxide 25 percent (Ref. 40). 21 See, e.g., Beeckman et al. (Ref. 41); 43 FR 34628 at 34641(August 4, 1978) (discussing use of zinc oxide 1 percent to 25 percent as a skin protectant active ingredient: ‘‘Zinc oxide is widely recognized as a skin protectant’’ and ‘‘No reports of topical toxicity were found in the literature’’ on zinc oxide). VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 more active ingredients, making it difficult to attribute causation to a specific active ingredient. Unlike other sunscreen ingredients with a known hypersensitivity risk, we did not identify any reports in FAERS or in the literature with features suggestive of a causative link, such as skin test results positive for zinc oxide. In addition, there is an extremely large safety database of zinc oxide use in other topical products, including for the treatment of diaper rash in infants. This corroborates the negative results in human studies for irritation, photoirritation, allergy, and photoallergy that support our proposed finding regarding the safety of sunscreens containing this ingredient under the conditions proposed. Reports of non-hypersensitivity-related clinical safety issues with zinc oxide were infrequent and not serious. For these reasons, we do not consider additional clinical studies (including photosafety, irritation, or sensitization studies) to be necessary for this ingredient. Dermal carcinogenicity studies have not been conducted for zinc oxide. In general, as discussed in section VII.C.1, adequate tests for safety of an active ingredient for use in topical products for chronic use (such as a sunscreen) would need to include dermal carcinogenicity studies if the active ingredient reaches the viable layers of skin where it could have a biological effect. Given the minimal penetration of zinc oxide below the non-living stratum corneum, there is no plausible mechanism by which zinc oxide could have an effect on skin tumor development. We are therefore proposing to find that zinc oxide is GRASE for use in sunscreens despite the lack of dermal carcinogenicity studies studying this ingredient. Based on the minimal systemic exposure resulting from dermally applied zinc oxide, in particular when compared to endogenous zinc levels, we see no need for further nonclinical studies to support the safety of sunscreens containing zinc oxide, including systemic carcinogenicity studies, developmental and reproductive toxicity studies, or toxicokinetic studies.22 22 Our review of the available nonclinical safety literature on zinc oxide included references for a 90-day dermal toxicity study, genotoxicity, and limited developmental and reproductive toxicity information. The review of this literature suggests that genotoxicity, findings for zinc oxide are mixed, and that there is minimal dermal toxicity in rodents after 90 days. (See Refs. 42 and 43.) Oral rat embryofetal toxicity studies showed some adverse maternal and fetal effects, but only at very high doses (≤200 mg/kg/day) significantly higher than what is at issue here (Refs. 44 and 45). PO 00000 Frm 00015 Fmt 4701 Sfmt 4702 6217 c. Conclusion. Our review of the available data from both animal and human studies and data on physical properties such as solubility leads us to conclude that the transdermal absorption of zinc oxide—regardless of particle size—from any topically applied sunscreen formulation is extremely unlikely, and that any de minimis absorption that may occur would not result in adverse health effects, given the high levels of endogenous zinc. The very low likelihood of any systemic absorption of zinc oxide in turn indicates that the safety margin for zinc oxide is large; accordingly, consistent with our approach to pediatric studies discussed in section VII.B.5, we do not consider pediatric studies to be needed for this ingredient. We propose to find that the currently available safety data provide sufficient evidence to demonstrate the minimal absorption, low dermal irritation, low allergenic sensitization and photoallergenicity, and low phototoxic potential of zinc oxide— regardless of particle size—up to 25 percent, and that these data support a finding that zinc oxide up to 25 percent is GRASE for use in sunscreens under the proposed conditions. Accordingly, we propose that zinc oxide is a Category I active ingredient. 2. Titanium Dioxide For similar reasons, we propose that titanium dioxide is also a Category I active ingredient. Our review of information publicly available in the scientific literature, submissions to the sunscreen monograph docket, and FAERS has produced sufficient information to support a proposal that a sunscreen product containing up to 25 percent titanium dioxide would be GRASE under the conditions proposed in this rulemaking and the general conditions required in part 330. a. Background. Titanium dioxide is an inorganic mineral compound consisting of small, crystallinestructured or amorphous particles. It is widely used as an excipient and is currently listed as an inactive ingredient in more than 60 approved drug products (including topical, oral, and inhalation products, among others) (Ref. 46). Titanium dioxide particles can be manufactured to have a variety of different dimensions, shapes (such as spheres or rods), and crystal polymorphs (such as anatase or rutile). Titanium dioxide (typically with particle dimensions ranging from 200 to 300 nm) is manufactured as a white powder for use as a white color pigment in pharmaceuticals. Manufacturers have also introduced processes that produce E:\FR\FM\26FEP2.SGM 26FEP2 6218 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules titanium dioxide with particle dimensions ranging from 15 to 50 nm to reduce its white/opaque appearance. Titanium dioxide particles used in sunscreens are also now often treated with chemical coatings (such as silicones, metal oxides, or organic acids) that are bonded to the exterior surface of the particles to, among other things, improve the aesthetic characteristics of the final formulation. b. Discussion. Titanium dioxide is essentially insoluble in water and in biologic fluids (Ref. 47). As with zinc oxide, this lack of solubility prevents the transdermal absorption of more than a de minimis amount of titanium dioxide, regardless of either the concentration of titanium dioxide or the formulation of the product (Refs. 48 and 49). Further, unlike zinc oxide, which, if dissolved, would dissociate into zinc and oxygen (Ref. 50), the chemical stability of titanium dioxide is such that it does not dissociate under the conditions that exist in (or on) the human body (Ref. 51). Even if titanium dioxide were to dissociate into titanium and oxygen, titanium is unreactive in physiologic conditions, and (for this, among other, reasons) is frequently used in medical devices and structures implanted in the human body (Refs. 51 and 52). The available studies on the transdermal absorption of titanium dioxide confirm that the skin is an effective barrier to the penetration of titanium dioxide, regardless of particle size—including those on the nanoscale (Refs. 53, 54, and 55). In our 2012 response to the ICTA Petition mentioned earlier, we described the then available information about the absorption of titanium dioxide nanomaterials and concluded that the ‘‘currently available literature indicates that insoluble nanomaterials of titanium dioxide used in sunscreens do not penetrate into or through human skin to produce adverse health effects when applied topically’’ (ICTA Petition Response at 26). Since that time, our search of the available literature has not revealed anything that would change this conclusion. Because topically applied titanium dioxide particles do not enter systemic circulation to any meaningful extent, we do not consider a MUsT to be necessary for this ingredient. Given the lack of transdermal absorption of titanium dioxide beyond a de minims amount and, as a result, the very low likelihood of any systemic effects, we also do not consider additional nonclinical studies (including systemic carcinogenicity, developmental and reproductive VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 toxicity, or toxicokinetic) to be necessary to support the safety of this ingredient.23 Because titanium dioxide penetration beyond the non-living stratum corneum and into the viable layers of the skin is also minimal, as with zinc oxide, we do not consider dermal carcinogenicity studies to be needed for titanium dioxide either. The inability of more than an extremely minimal amount of titanium dioxide to reach viable tissues that could have an immunologic reaction also prevents dermal irritation, sensitization reactions, and photosafety issues for this ingredient. Our search of the available literature on titanium dioxide identified nonclinical data reinforcing this, showing that dermal toxicity after dermal application of titanium dioxide in rodents is minimal (Refs. 57 to 60). Accordingly, we do not consider additional clinical photosafety, irritation, or sensitization studies to be necessary to support the safety of this ingredient. We note that the available studies on titanium dioxide evaluate products with titanium dioxide concentrations up to 10 percent. Given that the physical properties of titanium dioxide both preclude its penetration into or through the human skin regardless of concentration and make it unlikely that there would be dermal photosafety, irritation, or sensitization associated with titanium dioxide exposure (and that there is no data to suggest such photosafety, irritation, or sensitization would exist at higher concentrations), we propose that titanium dioxide—regardless of particle size—is GRASE for use in sunscreens at concentrations up to 25 percent, consistent with the level set in the Stayed 1999 Final Monograph. In evaluating whether titanium dioxide is GRASE for use in sunscreen products, we have considered published literature indicating that nanoscale titanium dioxide can exhibit photocatalytic properties (Ref. 61). The literature indicates that the crystalline structure of titanium dioxide particles plays a role in this photocatalytic activity, and that the anatase crystalline polymorph is associated with greater photocatalytic activity than the rutile polymorph (Ref. 61). The European Commission has established limitations on the percentage of anatase crystalline polymorph in titanium dioxide to minimize photocatalytic activity.24 23 We note that the available literature also includes data showing that oral administration of relatively high doses of titanium dioxide did not produce adverse fetal effects in rats. (See Ref. 56.) 24 In a July 2013 opinion addressing the safe use of titanium dioxide in sunscreen products, the European Commission’s Scientific Committee on PO 00000 Frm 00016 Fmt 4701 Sfmt 4702 Coating titanium dioxide particles has also been shown to minimize photocatalytic activity (and to limit particle clumping, which can have an impact on how products blend).25 In theory, if photocatalytic activity occurred when sunscreen products containing nanoscale titanium dioxide were exposed to light, it could result in the breakdown of other sunscreen active ingredients in these products. We have no evidence, however, that this in fact occurs in sunscreen products containing titanium dioxide or that there are any other negative impacts resulting from such photocatalytic activity. Accordingly, its potential for photocatalytic activity does not undermine our conclusion that titanium dioxide is GRASE for use in sunscreen products. Nonetheless, we invite comment (including supporting data) on whether sunscreens containing titanium dioxide are negatively impacted by the potential photocatalytic effects of that ingredient and, if so, to what extent; and on additional regulatory conditions, if any, that are necessary to address this potential issue. We note, as well, that it is the responsibility of manufacturers to ensure that any inactive ingredients used in a drug product marketed pursuant to the OTC Drug Review, including coatings used to address photocatalytic activity or for other purposes, are safe and suitable for their intended use (see § 330.1(e)). FDA encourages manufacturers to contact the Agency regarding any specific coatings that they are considering for use in a topical sunscreen. c. Conclusion. Given the chemical properties of titanium dioxide as insoluble and unreactive under physiologic conditions and the available studies showing that titanium dioxide does not penetrate into the skin or enter into systemic circulation to any meaningful extent, we consider the available safety data adequate to support a proposal that titanium dioxide is GRASE for use in sunscreens. As with zinc oxide, our proposal rests in significant part on the data showing that absorption of titanium dioxide into or through the skin is very unlikely and Consumer Safety gave its opinion that titanium dioxide particles consisting, among other things, of up to 5 percent anatase crystal ‘‘can be considered to not pose any risk of adverse effects in humans after application on healthy, intact or sunburnt skin’’ (Ref. 62). In 2016, this physicochemical parameter was incorporated by the European Commission into its Regulation on Cosmetic Products (Regulation (EC) No. 1223/2009 11/30/ 2009) permitting the use of titanium dioxide as a UV filter or as a colorant in cosmetics. See Regulation (EC) No 1143/2016 July 13, 2016. 25 Id. E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules that any de minimis absorption that could theoretically occur would not result in adverse health effects. As a result, the safety margin here is large, and consistent with our approach to pediatric studies discussed in section VII.B.5, we therefore consider pediatric studies to be unnecessary for this ingredient. B. Ingredients Proposed as Category II FDA’s review of the available safety data for PABA and trolamine salicylate have caused us to conclude that the risks associated with use of these ingredients in sunscreen products outweigh their benefits. Accordingly, we are proposing that these two ingredients are Category II. 1. Para-Aminobenzoic Acid PABA use has decreased significantly in recent years because of, among other things, its adverse effects on skin and its discoloring and staining effect on clothing. Our review of more than 700 sunscreen brands sold in the United States (Ref. 63) indicates that PABA is in fact no longer being marketed in the United States. A search of the scientific literature, submissions to the sunscreen monograph docket, drug approval documents from FDA and the European Medicines Agency, adverse event reports submitted to FAERS, and FDA Advisory Committee meeting reports (among other sources) has produced clinical safety data on PABA that supports a conclusion that a sunscreen containing PABA would not be GRASE. The available clinical information includes significant numbers of reports of allergic and photoallergic skin reactions to PABA, with rates of PABAinduced skin reactions potentially 8 percent or higher (Refs. 64 to 67). An 8 percent incidence is a serious concern: By comparison, only 34 hypersensitivity reactions associated with sunscreen products have been identified in FAERS since 1969.26 Further, PABA has the ability to cause cross-sensitization to structurally similar aromatic amines and nitro compounds (i.e., it can cause individuals exposed to it to develop sensitivity reactions to similar compounds) (Ref. 69). The list of compounds at issue includes a variety of widely used products, such as sulfonamide antibiotics (commonly used to treat a variety of infections, from urinary tract infections to certain types of pneumonia), thiazide diuretics (the 26 Total sunscreen sales since 1969 are not readily available. However, in 2016 a total of 161,882,779 sunscreen units were sold in the United States (Ref. 68). VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 number one recommended treatment for hypertension for certain communities), certain local anesthetics (such as benzocaine and procaine), and dyes (including para-phenylenediamine (a hair dye) and aniline dyes (used in medical products)) (Refs. 70, 71, and 72). Cross-sensitization to these products is a serious concern, as widespread PABA use could result in a significant increase in cross-reactivity with these agents and the incidence of allergic and photoallergic dermatitis, some of which are likely to be severe. These safety issues alone are reason enough to find PABA not GRASE for use in sunscreens. In addition, however, data obtained from the urine samples of human subjects receiving topical PABA application shows that PABA also penetrates the skin and enters systemic circulation (Ref. 73). Because full MUsT studies for PABA have not been done, it is unclear to what degree such transdermal absorption takes place. However, one article in the published literature suggests that there is an association between autoimmune disorder and PABA use (Ref. 71), and we found one report each of hepatotoxicity (Ref. 74) and chronic interstitial nephritis (Ref. 75) after oral PABA administration. Although it is difficult to determine causality on the basis of such single reports, if a MUsT were to show absorption of PABA, these reports could represent an additional safety concern. In addition, genotoxicity findings with PABA use have been largely negative in the absence of UV irradiation. Adequate assessments of the dermal carcinogenicity potential of PABA are unavailable, as are DART studies. If a MUsT were to show absorption of PABA, therefore, necessary studies would include dermal and systemic carcinogenicity studies, DART studies, and toxicokinetic studies. However, given that the abovedescribed safety concerns associated with PABA are significant enough to place PABA in Category II, conducting such testing is neither appropriate nor ethical. We propose that PABA is not GRASE for use in sunscreens. 2. Trolamine Salicylate We also propose that trolamine salicylate is not GRASE for use in sunscreens, and is, like PABA, a Category II active ingredient. As described in further detail below, there are significant safety concerns associated with the use of trolamine salicylate in sunscreen products. We propose that these concerns are sufficient to support a conclusion that a sunscreen containing trolamine PO 00000 Frm 00017 Fmt 4701 Sfmt 4702 6219 salicylate would not be GRASE. We note that, as with PABA, our review of more than 700 sunscreen brands sold in the United States suggests that trolamine salicylate is no longer being marketed in sunscreens sold in the United States (Ref. 63). a. Background. Trolamine salicylate is comprised of trolamine and salicylic acid. Salicylic acid is a non-steroidal anti-inflammatory drug (NSAID); it is the active moiety in aspirin, and has been widely used as an analgesic (i.e., pain relieving), anti-pyretic (i.e., fever reducing), and anti-inflammatory agent. In addition to these properties, salicylic acid inhibits platelet aggregation, which in turn inhibits blood coagulation. For this reason, some salicylic acidcontaining products (such as aspirin) are used by consumers to help reduce cardiovascular adverse events, including myocardial infarction, stent thrombosis, and transient ischemic attacks. Trolamine salicylate was included in the Stayed 1999 Final Monograph for sunscreens at a concentration of up to 12 percent. It was also proposed as a Category III active ingredient in the tentative final monograph for OTC external analgesic drug products (External Analgesic TFM) (‘‘External Analgesic Drug Products for Over-theCounter Human Use; Tentative Final Monograph,’’ 48 FR 5852 at 5855 (February 8, 1983)). The mechanisms of action for trolamine salicylate for these two drug categories are very different; to be effective as an external analgesic, trolamine salicylate must penetrate the skin and reach the relevant sites of action. The available evidence clearly establishes that trolamine salicylate is transdermally absorbed (Refs. 76 and 77). To be effective as a sunscreen, however, trolamine salicylate must be present on the surface of the skin so that it can reflect, scatter, or absorb UV radiation. The directions for use for the two product categories differ significantly as well. The current requirements for sunscreen labeling include directions that the product should be applied to all skin exposed to the sun, that it should be used ‘‘regularly’’ to decrease the risk of skin cancer and early skin aging,27 and that it should be reapplied at least every 2 hours (21 CFR 201.327). In contrast, currently marketed external analgesic products containing trolamine salicylate include directions for use stating that they should be applied to ‘‘affected areas,’’ that they should be reapplied no more than three to four 27 This direction applies to sunscreens with an SPF of 15 or greater that are also broad spectrum. E:\FR\FM\26FEP2.SGM 26FEP2 6220 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules times a day, and that use should be discontinued after 7 days.28 b. Significant safety concerns associated with use of trolamine salicylate as a sunscreen. FDA is concerned that use of trolamine salicylate as an active ingredient in sunscreens could cause serious detrimental health effects due to the anti-coagulation effects of salicylic acid. FDA located two case reports of serious coagulation-related adverse events associated with liberal dermal application of trolamine salicylate. The first case involved a surgical patient who experienced coagulopathy (impairment of the blood’s ability to coagulate) at surgical sites in connection with use of topical trolamine salicylate (Ref. 76). Although the patient discontinued aspirin use 2 weeks before surgery per her doctor’s instructions, she was unaware that use of a topical cream containing trolamine salicylate should have been stopped as well, and continued liberal application of the product to her knees for arthritis pain in the period leading up to her surgery. Four hours after surgery, the patient returned to the operating room bleeding profusely from all surfaces that had been operated on and experiencing massive bilateral hematomas. She lost more than 900 mL of blood. In the second case, a patient taking warfarin (an anticoagulant) for atrial fibrillation and stroke prevention experienced a considerable increase in prothrombin time (i.e., the time it takes for blood to coagulate) after liberal application of trolamine salicylate to his neck and shoulders for pain relief (Ref. 78). The patient’s prothrombin time had previously been in the therapeutic range of 1.3 to 1.5 times the control, but increased to 2.5 times the control during trolamine salicylate use. When trolamine salicylate use was discontinued, the patient’s prothrombin time returned to 1.3 times the control. FDA is also concerned that sunscreens containing trolamine salicylate could lead to other adverse effects associated with salicylic acid exposure. These include gastrointestinal distress and hemorrhage, ototoxic effects (i.e., impacts on hearing), hypersensitivity reactions, asthma exacerbations, acid-base imbalance, salt and water retention, liver injury, and Reye’s Syndrome (in children). At high doses, acute salicylate toxicity (salicylism) may occur. Early symptoms of salicylism include tinnitus, vertigo, nausea, vomiting, and diarrhea; 28 Based on an evaluation of product labeling available at https://labels.fda.gov (accessed April 4, 2018). See also External Analgesic TFM. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 subsequent symptoms suggesting a more severe intoxication include altered mental status (ranging from agitation to lethargy), hyperpyrexia, noncardiac pulmonary edema, and coma.29 If trolamine salicylate were to be applied to all skin exposed to the sun and reapplied every 2 hours as directed in sunscreen labeling, the potential for transdermal absorption and systemic availability of substantial amounts of salicylic acid raises significant concerns about the potential for increased occurrence of the above-described adverse events. This is a particular concern given the widespread use of other OTC NSAID products with antiinflammatory, analgesic, or anti-pyretic effects, which, combined with the use of sunscreens containing trolamine salicylate, may raise the anti-platelet effects experienced by consumers to problematic levels. Concerns relating to transdermal absorption may be especially acute for children, who have a higher surface-area-to-body-weight ratio than adults. FDA proposes that the above-described safety concerns are enough, by themselves, to support a finding that trolamine salicylate is not GRASE for use in sunscreens, and therefore, is a Category II active ingredient. c. Data gaps. In addition, there are several categories of data about trolamine salicylate that FDA expects would be necessary to support a positive GRASE determination for its use in sunscreen products that are currently missing from the public record. For example, there is insufficient clinical dermal sensitization, irritation, and photosafety data for trolamine salicylate. Although the transdermal absorption of trolamine salicylate is well established, the record currently lacks a MUsT that would allow us to evaluate the extent of exposure to this ingredient when it is used as a sunscreen. Such data is important because it would allow FDA to interpret systemic toxicity findings in animal toxicology studies in the context of the amount likely to be absorbed from sunscreen use. Given the FDA recommendation that a MUsT for sunscreen use include application to a majority (75 percent at a minimum) of the body surface of each test subject, the above described safety concerns 29 The symptoms associated with both acute and chronic salicylate toxicity are well established. Descriptions are available from many sources, including: National Library of Medicine’s Toxicology Data Network (ToxNet), ‘‘Salicylic Acid,’’ September 2008, available at https:// toxnet.nlm.nih.gov/cgi-bin/sis/search/ a?dbs+hsdb:@term+@DOCNO+672 (accessed March 27, 2018). FDA also included a comprehensive summary of salicylism in 21 CFR 343.80. PO 00000 Frm 00018 Fmt 4701 Sfmt 4702 (including the potential for salicylism associated with exposure to high doses of trolamine salicylate) would raise significant ethical concerns about the conduct of a MUsT in these circumstances. Were it possible to ethically conduct a MUsT for this ingredient, and if such a MUsT showed significant transdermal absorption of trolamine salicylate, this would raise questions about whether enough of this ingredient remains present on the surface of the skin for it to function effectively as a sunscreen. As we noted in section VII.B.4, such considerations ultimately weigh into the risk-benefit calculus FDA uses to determine whether an active ingredient would be GRASE for use in sunscreens. Although we have data addressing the toxicology profile of salicylate, adequately detailed nonclinical DART studies for trolamine and toxicokinetic data to interpret DART studies were also not found in the public record. Adequate DART information, if it were available, might reveal additional data needs (for example, to address any potential hormonal effects that may be identified). Dermal carcinogenicity data are available from the National Toxicology Program for trolamine in acetone and trolamine alone (applied neat).30 In the absence of toxicokinetic data to interpret existing carcinogenicity studies, we cannot determine how the exposure in the animal studies relates to human exposure to trolamine from the use of trolamine salicylate as a sunscreen active ingredient. d. Conclusion. For the reasons described above, FDA proposes that trolamine salicylate is not GRASE for use in sunscreens. The safety concerns associated with the use of trolamine salicylate as an active ingredient in sunscreens are significant enough to support classification of trolamine salicylate as a Category II ingredient. In particular, the potential for transdermal absorption and systemic availability of substantial amounts of salicylic acid in connection with the exposure resulting from the use of trolamine salicylate in sunscreens raises concerns about increased occurrence of the abovedescribed serious adverse events (including salicylism and serious coagulation-related issues). The record also contains several significant data gaps that would need to be addressed to support a positive GRASE determination for trolamine salicylate. 30 In mice, liver tumors were identified, providing evidence of systemic absorption of trolamine, but the suspected mechanism of action is likely not relevant to humans (Refs. 79 and 80). A causal link between the proposed mechanism and tumor formation in mice is lacking. E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules Given the safety concerns described above, however, conducting the clinical absorption testing recommended to address these gaps for use as a sunscreen raises ethical concerns. C. Ingredients Proposed as Category III The public record does not contain sufficient data to support a positive GRASE determination for cinoxate, dioxybenzone, ensulizole, homosalate, meradimate, octinoxate, octisalate, octocrylene, padimate O, sulisobenzone, oxybenzone or avobenzone at this time. Accordingly, these ingredients are being proposed as Category III. In the sections that follow, we discuss our review of the available safety evidence for these ingredients and identify the existing data gaps. 1. Ingredients for Which the Record Contains Significant Data Gaps: Cinoxate, Dioxybenzone, Ensulizole, Homosalate, Meradimate, Octinoxate, Octisalate, Octocrylene, Padimate O, and Sulisobenzone The most significant gaps in the administrative record exist for the following active ingredients: Cinoxate, dioxybenzone, ensulizole, homosalate, meradimate, octinoxate, octisalate, octocrylene, padimate O, and sulisobenzone. We expect that data from all the types of studies described in section VII will need to be submitted to support general recognition of safety and effectiveness for each of these ingredients. Only three of these active ingredients (homosalate (Ref. 81)), octinoxate (Refs. 81 to 84), and octisalate (Ref. 81), for example, appear to have been evaluated in human absorption studies, and most of the available absorption studies for these three ingredients had significant limitations. For example, the studies use a limited number of subjects or are based on only a single application of the sunscreen active ingredient to a limited area of the body. Even with this limited sunscreen exposure, some of these studies showed systemic availability of the active ingredient (octinoxate (Refs. 83 and 84)). None of these 10 ingredients has been studied in an adequate and well-controlled MUsT that would determine the amount of systemic exposure to the active ingredients under conditions of maximal use. We note that a recent publication examining the relationship between melting point, molecular weight, and the transdermal delivery rates of the active ingredients in approved drug products shows that products containing active ingredients with melting points and molecular weights VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 similar to many of these 10 sunscreen active ingredients are among those successfully delivered transdermally— and therefore available systemically (Ref. 85). This reinforces the potential for transdermal absorption of and systemic exposure to these sunscreen ingredients. The potential for such systemic exposure is a concern because the available data are inadequate to determine either the level of systemic exposure to these active ingredients or the potential unintended consequences of such exposure. Given the lack of chronic exposure toxicology data for these 10 ingredients—which makes an evaluation of the dermal and systemic effects of chronic use impossible—this is especially concerning. A number of these active ingredients have also shown hormonal effects in mammalian assays (homosalate (Refs. 86 to 92)) and padimate O (64 FR 27666 at 27671) and in in vitro and in vivo assays (homosalate (Refs. 86 to 92), octinoxate (Refs. 93 and 94),and octocrylene (Ref. 95). Although these findings are only preliminary, we do not have adequate DART studies to enable us to assess the impact of these potential hormonal effects on development and reproduction. In addition, several of these 10 ingredients (homosalate (Refs. 81 and 84), octinoxate (Refs. 81 and 96 to 101), octisalate (Refs. 81, 84, and 101 to 105),octocrylene (Refs. 95 and 106), padimate O (Ref. 100), and sulisobenzone (Refs. 107 and 108)) have been studied in dermal penetration studies, which show (in general, with the exception of homosalate) that these ingredients permeate into the epidermis and/or dermis. The studies show that there are several factors (including vehicle composition and the presence of other active ingredients) that can influence, and potentially increase, the permeation and/or penetration of these ingredients. Because the record does not currently contain sufficient data to support their safety, we are proposing that cinoxate, dioxybenzone, ensulizole, homosalate, meradimate, octinoxate, octisalate, octocrylene, padimate O, and sulisobenzone are Category III ingredients. As previously noted, we expect that data from all the types of studies described in section VII will be needed to support general recognition of safety and effectiveness for these ingredients. 2. Ingredients for Which the Record Contains Fewer Data Gaps: Oxybenzone and Avobenzone While the record does not currently contain sufficient data to support PO 00000 Frm 00019 Fmt 4701 Sfmt 4702 6221 positive GRASE findings for oxybenzone and avobenzone, we have significantly more data for these two ingredients than for the ingredients discussed in the preceding section. To help facilitate submission of the remaining data, we describe the data gaps for these two ingredients in greater detail below. a. Oxybenzone data. Although we located substantially more data on oxybenzone than on the ingredients discussed in section VIII.C.1, our review of the scientific literature, submissions to the sunscreen monograph docket, and postmarket safety data publicly available through FAERS revealed significant gaps in the data we expect to be necessary to support a positive GRASE finding for use of oxybenzone at a concentration of up to 6 percent in sunscreen products. The available literature includes studies indicating that oxybenzone is absorbed through the skin and can lead to significant systemic exposure, as well as data showing the presence of oxybenzone in human breast milk, amniotic fluid, urine, and blood plasma. The significant systemic availability of oxybenzone (and, as discussed further below, the lack of data evaluating the full extent of its absorption potential) is a concern, among other reasons, because of questions raised in the published literature regarding the potential for endocrine activity with systemic oxybenzone exposure. Accordingly, we expect that a positive GRASE finding for oxybenzone-containing sunscreens would require, among other things, both a MUsT showing the degree of oxybenzone absorption under maximal usage conditions and DART studies that fully investigate its potential endocrinedisrupting effects. We found neither in the existing record. The record also lacks systemic and dermal carcinogenicity studies for oxybenzone; these (and toxicokinetic data) should also be provided to support a positive GRASE finding for this ingredient. Finally, the available literature also raises questions about the safety of use of oxybenzone-containing sunscreens in young children because of the potential for higher absorption and bioaccumulation of oxybenzone in this population. As discussed in further detail in the sections that follow, we invite input and comment on appropriate studies and/or age restrictions to address these pediatric issues. b. Background of oxybenzone. Unlike zinc oxide and titanium dioxide, both of which are inorganic (or physical) UV filters consisting of metal oxides that primarily reflect or scatter UV radiation, E:\FR\FM\26FEP2.SGM 26FEP2 6222 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules oxybenzone is an organic (or chemical) filter, which absorbs UV radiation. It belongs to a class of aromatic ketones known as benzophenones and has a UV absorption profile covering both UVA and UVB wavelengths (Ref. 109). Because of its superior UVA coverage, oxybenzone was increasingly used through the early 1990s and ultimately replaced PABA in sunscreen products (Ref. 110). Use of oxybenzone in sunscreens increased when ‘‘PABAfree’’ sunscreens were introduced into the market because of recognition that PABA and its esters induced contact and photocontact allergic reactions (Ref. 110). As discussed below, however, evidence shows that oxybenzone also has contact allergenic and photoallergenic potential (Ref. 111). In addition to its use as a sunscreen active ingredient, oxybenzone is used in, among other things, perfumes, lipsticks, hair sprays, and conditioners as a photostabilizer and/or fragrance enhancer (Refs. 112 to 114). c. Data showing transdermal absorption and significant systemic availability of oxybenzone. Data that have become available since publication of the Stayed 1999 Final Monograph suggest that the transdermal absorption of oxybenzone is high (Refs. 82, 115, and 116). One study involving sampling of plasma and urine following topical application of an oxybenzonecontaining formulation showed absorption and significant systemic availability of oxybenzone (Ref. 82). In this study, 15 men and 17 women were dosed once daily, applying a 10 percent oxybenzone cream formulation to approximately 90 percent of the body’s surface area for 4 days. The figures below illustrate the plasma and urine levels observed. BILLING CODE 4164–01–P VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 PO 00000 Frm 00020 Fmt 4701 Sfmt 4702 E:\FR\FM\26FEP2.SGM 26FEP2 EP26FE19.000</GPH> BILLING CODE 4164–01–C Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules Although this study provides important information about the significant absorption potential of oxybenzone, it does not obviate the need for a MUsT. Among other things, once-daily application may result in substantially lower systemic exposure than application at least every 2 hours (as sunscreen labeling directs). This difference in application frequency is a particular concern given that the data show oxybenzone levels would still be increasing at the time of reapplication if a 2-hour application window were observed. Additionally, the cream formulation used in the study was not formulated as a sunscreen product and may have contained ingredients not typically used in sunscreen formulations, and/or lacked other ingredients typically present. Because the formulation can have an impact on absorption, the absorption results produced by the study may not reflect absorption levels that would result from actual use of oxybenzone-containing sunscreen products. Another study, which evaluated the transdermal absorption of a marketed sunscreen containing 4 percent oxybenzone in 16 women and 9 men, showed prolonged systemic availability of oxybenzone following topical exposure (Ref. 116). In this study, which was designed to evaluate the effects of VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 UV radiation on oxybenzone absorption, the sunscreen was applied to study subjects twice daily for 5 days. Although the study concluded that UV exposure did not significantly affect the urinary excretion of oxybenzone, it provided further evidence of the systemic availability of oxybenzone following topical application and showed that renal excretion of oxybenzone continued for 5 days after the last application of the sunscreen. Although the use of a commercial sunscreen formulation, and twicerather than once-daily sunscreen application are improvements over the formulation and application frequency used in the previous study, twice-daily application remains insufficient to approximate the recommended application frequency of sunscreen products in real-world use. Furthermore, because the study used a sunscreen with 4 percent rather than the full 6 percent concentration of oxybenzone eligible for the sunscreen monograph, its results may not fully reflect the absorption that would result from use of a 6 percent oxybenzonecontaining product. To properly characterize the potential for absorption of oxybenzone in sunscreen products and to determine a margin of safety for use of oxybenzone at up to 6 percent in sunscreen products, we expect that a MUsT will be needed. PO 00000 Frm 00021 Fmt 4701 Sfmt 4702 d. Inadequate data on oxybenzone’s developmental and reproductive toxicity. The significant systemic availability of oxybenzone following topical application and the lack of data fully characterizing its absorption levels are concerns, among other reasons, because of literature suggesting that oxybenzone may have endocrine activity (see, e.g., Refs. 88, 92, and 117). Dermal exposure to oxybenzone (in acetone) in rats and mice and oral feeding of oxybenzone to rats and mice resulted in reduced sperm density in males in 13-week general toxicity studies conducted by the National Toxicology Program (NTP) (Ref. 118). In female rats and mice, increased estrous cycle length was observed in 13-week oral feeding studies.31 Importantly, the actual effects of oxybenzone on female fertility were not evaluated. In a preliminary dose range-finding pre- and postnatal development study in rats, findings in male offspring indicated that cells in the testes undergoing programmed cell death were increased in all oxybenzone-exposed animals and that numbers of spermatocytes in the testes were markedly reduced after oral feeding at oxybenzone (Ref. 119). Although these findings are notable, they are all derived from dermal studies 31 These changes could potentially be addressed with historical control data (Ref. 88). E:\FR\FM\26FEP2.SGM 26FEP2 EP26FE19.001</GPH> BILLING CODE 4164–01–C 6223 6224 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules with oxybenzone in acetone and oral feeding studies of oxybenzone; these methods of exposure could potentially lead to higher levels of systemic exposure to oxybenzone than with sunscreen use. Accordingly, a MUsT and toxicokinetic data are needed to determine the relevance of these findings to human use of oxybenzone as a sunscreen active ingredient. In humans, the endocrine effects of oxybenzone have been studied with inconclusive results (see, e.g., Refs. 83, 120, and 121). In biomonitoring studies of pregnant and lactating women, oxybenzone has been detected in breast milk, amniotic fluid, and urine samples (Ref. 83, 120, and 121). High levels of oxybenzone in the urine of mothers have been associated with: (1) Decreased birth weight in girls and (2) increased birth weight and head circumference in boys, both of which can be indications of endocrine effects (Ref. 83). This association is particularly concerning given the widespread exposure of the U.S. population to oxybenzone. Estimates suggest that oxybenzone (from all sources) is present in the urine of 97 percent of the U.S. population, and that oxybenzone concentrations are higher in women than in men (possibly because women are more likely to use sunscreen and other personal care products containing oxybenzone, leading to greater cumulative exposure) (Ref. 83 and 115). Because current data suggest that oxybenzone may affect the human endocrine system, FDA believes that a positive GRASE determination for oxybenzone would require that its potential toxicities have been fully explored, including through DART studies (fertility and early embryonic studies in rodents, embryofetal development studies in rodent and nonrodent species, and pre- and postnatal development studies in rodents). In addition, as noted below, toxicokinetic data are needed to interpret these studies. We note that, if the results of DART studies do not resolve the concerns raised in the literature relating to potential endocrine disruption, it may still be possible to resolve these concerns through additional testing.32 In addition, because of the potential risk posed by metabolites of oxybenzone (existing reports suggest that some oxybenzone metabolites are more hormonally active than the parent drug (Ref. 109)), we recommend that the analytical method used in the MUsT be validated for both the parent and the metabolites of 32 For examples of the type of studies that could be explored at that juncture see Ref. 21. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 interest (Ref. 115) to support a positive GRASE finding for this ingredient. The results from the metabolite study will inform whether additional nonclinical studies assessing oxybenzone’s metabolites should be conducted to support its safety. We note that the NTP is currently conducting additional DART studies on oxybenzone (although their embryofetal studies do not appear to include an assessment in a nonrodent species) (Ref. 122).33 e. Inadequate carcinogenicity and toxicokinetic data for oxybenzone. High population exposure to oxybenzone, coupled with a lack of carcinogenicity testing for this ingredient, caused the National Cancer Institute to nominate oxybenzone for toxicology testing in 1979 (Ref. 123). The NTP reports that 2-year oral (dosed feed) carcinogenicity studies in rats and mice are in a draft report stage, but results are not yet publicly available (Ref. 122). In addition, no reports of either ongoing or planned dermal carcinogenicity studies for oxybenzone have been published. To support a positive GRASE finding for oxybenzone, carcinogenicity data from well-conducted dermal and systemic carcinogenicity studies should be provided. Toxicokinetic data in rodents (oral and dermal) and rabbits (oral) are also recommended; these data could be obtained from either stand-alone studies or as part of DART and dermal carcinogenicity studies. Our search of the available literature also revealed information suggesting that oxybenzone may generate reactive oxygen species (ROS) 34 in the presence of UV light, but that this issue, and the harms associated with it, have not been fully explored (Ref. 124). We invite comment and input on the extent to which ROS generation is a concern for sunscreens containing oxybenzone and whether additional data on this topic are needed. f. Dermal safety of oxybenzone. The available data indicate that oxybenzone (at concentrations up to 6 percent) has a favorable safety profile with respect to irritation and sensitization potential. For example, the North American Contact Dermatitis Group conducted an analysis of patients who were patch tested for allergies between 2001 and 33 As a reminder, such data must be generally available to be considered as part of this rulemaking process. Once available, FDA intends to review such data to determine whether it resolves particular data concerns we have in this area. 34 Reactive oxygen species are ‘‘a type of unstable molecule that contains oxygen and that easily reacts with other molecules in a cell. A buildup of ROS in cells may cause damage to DNA, RNA, and proteins, and may cause cell death.’’ https:// www.cancer.gov/publications/dictionaries/cancerterms?cdrid=687227. PO 00000 Frm 00022 Fmt 4701 Sfmt 4702 2010 (see, e.g., Ref. 125). From 2001 to 2008, oxybenzone was tested at 3 percent; from 2009 to 2010, the concentration used for the test was increased to 10 percent. Of the 23,908 patients patch tested, only 82 patients (0.34 percent) had positive test patch results with oxybenzone. In addition, a search of FAERS for case reports of hypersensitivity reactions to oxybenzone-containing sunscreen products resulted in only 31 cases (4 with anaphylaxis) between 1988 and 2011. Because sufficient data exist to make a determination, we do not consider additional dermal irritation or sensitization studies to be necessary to support a positive GRASE finding for oxybenzone up to 6 percent. As is customary in clinical trials, however, we recommend that dermal safety data for oxybenzone be collected during MUsT studies. Nevertheless, the overwhelming majority of results from available studies (see, e.g., Refs. 125 to 136) addressing allergic contact dermatitis for oxybenzone show that oxybenzone is an allergen for persons with preexisting skin conditions. Because the evidence establishing oxybenzone as a photoallergen in individuals with photosensitivity is clear, no further dermal photosafety studies to characterize this risk are needed. However, if we were to receive adequate data to support a positive GRASE finding for oxybenzone, we would consider requiring labeling language to address the risk of allergic reactions associated with oxybenzone use. We invite comment on whether such labeling should be required for sunscreens containing oxybenzone and, if so, what that labeling should entail. g. Safety questions regarding use of oxybenzone in pediatric populations. Sunscreens are currently labeled for use in children as young as 6 months old. The available literature, however, includes several publications that raise concerns about the use of sunscreens containing oxybenzone in young children. Among these publications is a 2006 report from the Swedish Research Council noting that children under the age of 2 years old have not fully developed the enzymes believed to metabolize oxybenzone (Ref. 137), which suggests, in theory, that small children may not be able to eliminate oxybenzone as easily as adults. The possibility for bioaccumulation in children, taken together with the potential increased absorption of oxybenzone in young children (due to their greater body surface-area-to-weight ratio) and the potential harms associated with absorption discussed above, E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules militates in favor of caution when using oxybenzone products in young children. Accordingly, we are seeking any existing pediatric data on the safety of oxybenzone use in children under 2 years old. We are also requesting input on: (1) Whether additional data on the safety of oxybenzone use in young children is necessary to support the use of oxybenzone-containing sunscreens in children under 2 years of age (taking into consideration the practical hurdles involved in conducting studies in children of this age) or (2) whether sunscreen products containing oxybenzone should instead be contraindicated for use in children younger than 2 years (given, among other things, the availability for use as sunscreen active ingredients of physical UV filters like titanium dioxide and zinc oxide, which do not raise the same questions about safe use in young children). h. Conclusion. Given the available data showing significant transdermal absorption and systemic availability of oxybenzone, as well as the potential for endocrine activity, we propose that oxybenzone is not GRASE for use in sunscreens without further data. As described above, a MUsT should be conducted to fully characterize the absorption of oxybenzone and to calculate a margin of safety for human use. As part of the MUsT, we believe that a study of oxybenzone’s metabolites in humans is also necessary; the results of this study will inform whether additional nonclinical studies with metabolites are needed to address potential endocrine effects. Given that oxybenzone demonstrates significant systemic absorption, FDA believes that data on carcinogenicity (both systemic and dermal) and developmental/ reproductive toxicity are likely to be needed to support the safety of this ingredient, as are toxicokinetic data to 6225 bridge between animal and human data. We seek any existing data on the pediatric safety of oxybenzone. We also seek comment on whether additional safety data are needed to support the use of sunscreens containing oxybenzone on children under 2 years of age, as well as comment on whether these sunscreens should be contraindicated for use in this population. We note that, because of the risk of allergic reactions associated with oxybenzone use, if we receive adequate data to support a positive GRASE finding for oxybenzone, we may require labeling to address this risk. We seek comment on whether such labeling should be required for sunscreens containing oxybenzone and, if so, what such labeling language should entail. In summary, table 3 shows the additional studies that FDA anticipates would be necessary to support a positive GRASE finding for sunscreens containing oxybenzone. TABLE 3—SUMMARY OF RECOMMENDATIONS: STUDIES FOR OXYBENZONE UP TO 6 PERCENT Safety studies FDA proposes are necessary to support a GRASE determination Pharmacological Studies: Human absorption (MUsT) (including metabolite study in humans) Nonclinical Safety Studies: Toxicokinetics .................................................................................... Dermal Carcinogenicity ..................................................................... Systemic Carcinogenicity .................................................................. DART: 1 ..................................................................................................... Fertility and early embryonic development. Embryofetal development in two species (rodent and non-rodent). Prenatal and postnatal development. Clinical Safety Testing: Skin irritation and sensitization ......................................................... Skin photoallergenicity and phototoxicity .......................................... Pediatric studies ................................................................................ Additional studies or data necessary? Yes. Yes. Yes. Yes. Yes. No. No. Seeking input on whether additional studies or contraindication are necessary to support the safety of sunscreens containing oxybenzone for children under 2 years of age. 1 As noted above, if DART studies do not resolve the concerns raised in the literature relating to potential endocrine disruption, it may be possible to resolve these concerns through additional testing. i. Avobenzone data. Our review of the available scientific literature, submissions to the sunscreen monograph docket, and publicly available FAERS data also revealed significant gaps in the data we expect to be necessary to support a finding that avobenzone (at up to either 3 percent or 5 percent, as discussed below) is GRASE for use in sunscreens. Most critically, we encountered no studies examining the absorption of avobenzone in vivo, and those in vitro studies we located had several weaknesses that limit their usefulness in assessing the potential absorption of avobenzone from formulated sunscreen products. This is a concern given that, as explained in further detail below, certain of VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 avobenzone’s chemical properties suggest that sunscreen products containing avobenzone have a potential for absorption. There are also other gaps in the record, including (as discussed below) dermal carcinogenicity data, toxicokinetic data, and—potentially, depending on the outcome of MUsT studies assessing the absorption of avobenzone—systemic carcinogenicity and additional DART studies. Accordingly, we propose to find that avobenzone is Category III. j. Background of avobenzone. Avobenzone, like oxybenzone, is an organic (chemical) UV filter. Because avobenzone primarily absorbs radiation in the UVA portion of the UV spectrum, it is typically combined with another PO 00000 Frm 00023 Fmt 4701 Sfmt 4702 sunscreen active ingredient that provides protection in the UVB range. Avobenzone exhibits greater photoinstability than other UV absorbers; the available evidence shows that avobenzone degrades quickly upon exposure to sunlight, which can cause its efficacy to be decreased by between 50 and 90 percent after 60 minutes of exposure to sunlight (Refs. 138 and 139).35 To address this, avobenzone is typically combined with a photostabilizer to prevent rapid photodegradation (Refs. 138 and 139). 35 Avobenzone’s photodegradation also results in the formation of free radicals, which could, in theory, create sensitization and irritation responses and increase long-term risk of skin cancers and photoaging (Ref. 139). E:\FR\FM\26FEP2.SGM 26FEP2 6226 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules k. Potential for absorption of avobenzone. Although avobenzone is not soluble to any great extent in water, it is soluble in organic solvents. These include oils (which are present on human skin), alcohols, and other substances regularly included in sunscreen product formulations. Although this solubility is not enough, by itself, to determine whether transdermal absorption will take place, it is a necessary precondition (Ref. 140). In addition, like the 10 active ingredients described in section VIII.C.1, avobenzone’s melting point and molecular weight are similar to those of active ingredients in approved drug products that are successfully delivered transdermally and therefore available systemically (Ref. 85). As with the 10 sunscreen active ingredients previously discussed, this suggests a potential for transdermal absorption of avobenzone. l. Lack of adequate data on transdermal absorption of avobenzone. Nevertheless, our review of the available literature on avobenzone failed to produce any studies evaluating the in vivo absorption of avobenzone at 3 percent or higher under (or even approaching) maximal usage conditions. While we were able to locate a few studies evaluating avobenzone’s absorption in vitro, these studies had a number of weaknesses that significantly limited the conclusions that could be drawn from them. The first in vitro study we located evaluated the penetration—through excised human skin—of five sunscreen ingredients (including avobenzone) that had been diluted in mineral oil and water (Ref. 100). The study used a static cell technique. As discussed in section VIII.D, in a static cell study, the test product (here, a sunscreen/mineral oil/ water formulation) is placed on the upper side of a membrane (here, the excised skin) in the open donor chamber of a static cell, and a sampling fluid is placed on the other side of the membrane in a receptor cell. Diffusion of the ingredient (here the avobenzone) from the topically applied product to and across the membrane is monitored by examining sequentially collected samples of the receptor fluid. To ensure that all transdermal penetration of the ingredient that takes place is fully reflected in the receptor fluid, the receptor fluid must be optimized for absorption (in other words, sink conditions must be created in the fluid). In this study, the use of skin as the membrane in the system allowed for an evaluation of the presence and depth of permeation via skin stripping—the sequential application and removal of VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 adhesive tape to the skin samples. However, it is unclear whether the receptor phase of the study created adequate sink conditions. In addition, the formulations used in the study (which, as noted previously, consisted of only water, mineral oil, and the sunscreen ingredient) did not contain any of the other types of excipients (such as emollients, stabilizers, or solubilizers) that can also function as permeation/absorption enhancers and that are typically present in sunscreen product formulations. The study results showed that there was avobenzone present in the stratum corneum, the epidermis, and the viable dermis of the skin used as the membrane, but not in the receptor fluid. Although the lack of avobenzone in the receptor fluid is encouraging, the other characteristics of the study limit its value in assessing the actual absorption potential of avobenzone used in sunscreen products. The second in vitro study (Ref. 141) we located suffered from similar limitations. This study assessed the avobenzone permeation observed using a static cell (as generally described above), and then took the skin from the static cell and subjected it to multiple rounds of tape stripping to assess the presence of avobenzone at various levels of the skin. Following tape stripping, the skin was subjected to digestion (i.e., the skin sample was subjected to a chemical treatment that breaks down the cell membranes to release any sunscreen that might be either bound to proteins or bound up in the cells). The study results showed significant retention of avobenzone in the stratum corneum, a lesser amount in the epidermis, and none in the dermis or receptor fluid. Like the previous study, however, the test material used in this study did not include any of the permeation enhancers typically included in commercial sunscreen formulations. It is also unclear whether sink conditions existed in the receptor phase of the study. The final in vitro study used a static cell to evaluate the transdermal penetration of six sunscreen formulations collected from a health spa that marketed its own line of skin care products (Ref. 96). This study improved on the design of the previous two studies in several respects. First, the receptor fluid contained ethanol, a permeation enhancer often used in sunscreen products, which produced sink conditions in the receptor phase. Secondly, to create favorable conditions for absorption, the products were applied at a thickness of 20 mg/square centimeters (cm2) on the skin’s surface (i.e., 10 times the skin loading typically PO 00000 Frm 00024 Fmt 4701 Sfmt 4702 expected (Refs. 142 and 143)). In addition, the study’s use of commercially marketed sunscreen formulations (which, as discussed above, typically contain multiple permeation/absorption-enhancing excipients) more accurately reflects the absorption potential of marketed sunscreen products. Despite these improvements, the usefulness of the study was limited by its use of an analytical method that prevented the detection of any avobenzone absorption below 100 ng/ mL. This level of absorption is hundreds of times higher than what is relevant for our considerations in assessing the acceptable absorption level from a topically applied product. The concentration of avobenzone used in the study (ranging from 0.2 percent to 1 percent) is also significantly lower than what is relevant for our current consideration of maximum concentration of this ingredient. Although avobenzone was only absorbed to a very small extent (between 3 percent and 3.96 percent) under these study conditions, these weaknesses in the study’s design significantly limit the conclusions that can be reached from its results. Given that avobenzone’s chemical properties suggest that it has a potential for transdermal absorption in sunscreen products, the lack of adequate data assessing its absorption in realistic sunscreen formulations is a concern. We therefore expect that a MUsT demonstrating the degree of absorption of avobenzone into the human body under maximal use conditions will be needed to support a positive GRASE determination for sunscreens containing avobenzone. Further, in light of the above-described data showing avobenzone’s photoinstability, we also expect that, if sufficient data are provided to support the safety of avobenzone, any future sunscreen monograph including avobenzone as an active ingredient will include the limitation that avobenzone is not GRASE for use in sunscreen products unless it has been photostabilized (via use of a photostabilizing UV filter or other photostabilizing ingredient/ mechanism) to prevent its photodegradation and (among other concerns) the attendant reduction in avobenzone efficacy. Because photodegradation can reduce the amount of avobenzone absorbed transdermally, we also expect that a MUsT sufficient to support the general recognition of safety of avobenzone for sunscreen use would need to test formulations of avobenzone that include a photostabilizer. Including E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules photostabilizers in MUsT formulations will allow for accurate assessment of absorption levels in final formulated sunscreen products containing avobenzone. This proposal is consistent with our general recommendation that materials evaluated under the MUsT paradigm represent real-world sunscreen formulations, rather than overly simplified solutions that fail to replicate the absorption potential of marketed formulations. As noted in section VII.B.4, we encourage sunscreen manufacturers to discuss their MUsT protocol with FDA before beginning the trial. m. Data supporting dermal safety of avobenzone. The available clinical dermal studies indicate that avobenzone at concentrations up to 5 percent have a favorable safety profile with respect to potential irritation, sensitization, and photosafety. In 2009, in conjunction with a citizen petition 36 (L’Oreal Petition, Docket No. FDA–1978–N– 0018–0675) asking FDA to take action to permit the marketing of sunscreen products containing avobenzone up to 5 percent, L’Oreal USA Products, Inc. (L’Oreal) submitted nine human repeat insult patch, phototoxicity, and photoallergy studies with six different sunscreen formulations containing avobenzone (3.4 percent, 4 percent, or 5 percent). The studies showed that the formulations were well tolerated for topical use (i.e., essentially nonallergenic, non-irritating, and nonsensitizing, with mild to moderate reactions occurring only rarely) (L’Oreal Petition).37 A separate search of the available scientific literature on the clinical safety of avobenzone did not reveal anything to undermine these findings. Although the available literature included a small number of reports of contact irritation and photosensitization in connection with avobenzone-containing products, details about the composition of the formulations at issue (and the concentrations of avobenzone) were frequently missing from the literature, making it difficult to determine the cause of these responses. A small number of serious hypersensitivity reports for sunscreens containing avobenzone were also located in FAERS. Because the sunscreens at issue usually contained three or more active ingredients, however, it is difficult to determine what caused the reaction. Because sufficient data exist to make a determination, we do not consider additional dermal clinical studies 36 FDA–1978–N–0018–0675, two volume submission (February 20, 2009) (L’Oreal Petition). 37 Id., volume I, pp. 5–8. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 (including photosafety, irritation, or sensitization studies) to be necessary to support the safety of this ingredient for sunscreen use at up to 5 percent. As is customary in clinical trials, however, we recommend that dermal safety data for avobenzone be collected during MUsT studies. n. Other nonclinical safety studies for avobenzone. Dermal carcinogenicity studies have not been conducted for avobenzone. The available data on the permeation of avobenzone suggest that it may permeate into at least the dermis and epidermis, which means that it is possible for avobenzone to impact skin tumor development. We therefore expect that dermal carcinogenicity studies will be necessary to support a positive GRASE finding for sunscreens containing this ingredient. Available embryofetal development studies in rats and rabbits did not reveal any findings of concern. However, our review of the nonclinical data for avobenzone 38 also revealed that toxicokinetic data following repeat-dose exposure will be needed to interpret pivotal nonclinical safety studies (including the embryofetal development studies in rats and rabbits) once the MUsT data become available. (As explained in section VII.B.4, these data are used to compare drug levels achieved in animal studies with those observed in humans under maximal exposure conditions.) In addition, if results of a MUsT demonstrate that there is significant systemic absorption of avobenzone, additional fertility and early embryonic development and prenatal and postnatal development studies in rats will be needed to support a positive GRASE finding. Depending on the results of the MUsT, systemic carcinogenicity studies may also be needed. o. Avobenzone in combination with other sunscreen active ingredients. As noted in section III.B, our finding in the Stayed 1999 Final Monograph that avobenzone was GRASE for use in sunscreens would have allowed its combination only with certain other sunscreen active ingredients (64 FR 27666 at 27688) because we did not 38 The available nonclinical data for avobenzone include acute oral and dermal toxicity studies in rats; a 13-week oral toxicity study in rats; a 28-day dermal toxicity study in rats; a 21-day dermal toxicity study in rabbits; several in vitro genotoxicity tests; an in vivo micronucleus test in mice, as well as a sensitization test in guinea pigs; a primary skin irritation test in rabbits; an ocular irritation test in rabbits; a phototoxicity study in guinea pigs; a photoallergenicity study in guinea pigs; and embryofetal development studies in rats and rabbits (Givaudan-Roure Petition, Docket No. FDA–1978–N–0018–0751). Importantly, (except for the embryofetal development studies) these studies are not sufficient to resolve safety concerns for a chronically used product. PO 00000 Frm 00025 Fmt 4701 Sfmt 4702 6227 have targeted evidence to support the safety and effectiveness of avobenzone when combined with the remaining active ingredients. We believe this limitation was inconsistent with the approach to evaluating sunscreen combinations that the Agency has generally taken throughout the OTC Drug Review for sunscreens. For this reason, unless evidence is submitted to suggest that there is a safety or efficacy concern associated with the combination of avobenzone with another active ingredient, we expect to conclude that a positive GRASE determination for avobenzone will support its use in sunscreens either alone or in combination with all other sunscreen active ingredients. p. L’Oreal request to increase concentration of avobenzone to 5 percent. Avobenzone is currently listed in the Stayed 1999 Final Monograph at concentrations up to 3 percent. As described earlier, in 2009 FDA received a citizen petition from L’Oreal requesting, among other things, that we amend the sunscreen monograph to increase the allowable level of avobenzone to 5 percent (L’Oreal Petition at 1). In the Stayed 1999 Final Monograph, the Agency determined that avobenzone at concentrations up to 3 percent is an effective sunscreen active ingredient. We now likewise conclude that the record contains sufficient information to satisfy the effectiveness prong of the GRASE standard for sunscreens containing avobenzone at concentrations up to 5 percent. As described above, data submitted with that L’Oreal Petition were sufficient to establish that avobenzone at a concentration of up to 5 percent has a favorable safety profile with respect to potential irritation, sensitization, and photosafety. To support a finding that avobenzone at concentrations up to 5 percent is GRASE for use in sunscreens, however, FDA expects that a MUsT evaluating the transdermal absorption of avobenzone up to 5 percent, as well as dermal carcinogenicity studies and toxicokinetic data for avobenzone at a concentration of at least 5 percent, will also be needed. Depending on the outcome of the MUsT, we may also need systemic carcinogenicity data and additional DART studies, including fertility and early embryonic development, and pre- and postnatal development studies in rats for avobenzone at 5 percent. The record does not currently include any of these data. However, if FDA were to receive sufficient data to support a positive GRASE finding for avobenzone up to 5 percent, we would expect to include E:\FR\FM\26FEP2.SGM 26FEP2 6228 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules avobenzone at this percentage in a final sunscreen monograph. q. Conclusion. Given that: (1) Avobenzone’s organic solubility, molecular weight, and melting point suggest it has a potential for transdermal absorption; (2) there is a lack of available data on the transdermal absorption of avobenzone in vivo (including under maximal use conditions); and (3) there are limitations in the available in vitro studies assessing avobenzone absorption, we expect that a properly designed MUsT will be necessary to support a positive GRASE finding for avobenzone use in sunscreens. We expect that, to be GRASE for sunscreen use, avobenzone will need to be photostabilized to address its potential for degradation, and we therefore expect that any future sunscreen monograph including avobenzone as an active ingredient will include the limitation that avobenzone is not GRASE for use in sunscreen products unless it has been photostabilized to prevent its photodegradation. In addition, we believe that an adequate MUsT evaluating the absorption potential of avobenzone will need to include a photostabilizer to ensure that the potential transdermal absorption of avobenzone from avobenzonecontaining sunscreens is accurately assessed. We also expect that dermal carcinogenicity and toxicokinetic data will be necessary to support a positive GRASE finding for sunscreens containing avobenzone. Depending on the outcome of a MUsT assessing the absorption of avobenzone, systemic carcinogenicity testing and additional DART studies, including fertility and early embryonic development and preand postnatal development studies in rats may be needed as well. We will also determine the extent to which additional DART studies may be needed based on the results of the MUsT. Depending on the results of the nonclinical and pharmacology studies for this ingredient and the safety margin that is calculated from these results, pediatric studies for avobenzone may also be needed to support the use of sunscreens containing avobenzone in pediatric populations. TABLE 4—SUMMARY OF RECOMMENDATIONS: STUDIES FOR AVOBENZONE UP TO 3 (OR 5) PERCENT Safety studies FDA proposes are necessary to support a GRASE determination Pharmacological Studies: Human absorption (MUsT) (including metabolite study in humans) Nonclinical Safety Studies: Toxicokinetics .................................................................................... Dermal Carcinogenicity ..................................................................... Systemic Carcinogenicity .................................................................. DART: Fertility and early embryonic development ....................................... Embryofetal development in two species (rodent and non-rodent) .. Prenatal and postnatal development ................................................ Clinical Safety Testing: Skin irritation and sensitization ......................................................... Skin photoallergenicity and phototoxicity .......................................... Pediatric studies ................................................................................ D. Anticipated Final Formulation In Vitro Permeation Testing As noted earlier, a final sunscreen monograph will need to set out the conditions under which any product marketed pursuant to it would be GRASE and not misbranded. Variations among individual sunscreen product formulations—in particular, characteristics of the specific vehicle (e.g., the cream, lotion, or oil) in which active ingredients are delivered—can affect the transdermal absorption of sunscreens, and thus, have an impact on their safety and effectiveness. To address this, FDA currently requires final formulation testing of OTC sunscreen products to support labeled claims regarding their effectiveness— namely, testing for SPF value as well as broad spectrum protection and water resistance where those attributes are claimed in product labels.39 For 39 See § 201.327 for the current labeling requirements, and underlying testing, for OTC sunscreens containing one or more of the 16 active VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 Additional studies or data necessary? Yes. Yes. Yes. Dependent on results of the MUsT. Dependent on results of the MUsT. No. Dependent on results of the MUsT. No. No. Pediatric studies may be required depending on the outcome of the MUsT. purposes of this proposed rule, we use the term final formulation testing to refer to testing conducted on the sunscreen product formulation to be marketed. Our expectation is that final formulation testing would also generally be necessary to ensure that the active ingredient in any given sunscreen formulation permitted under the monograph would not be systemically absorbed beyond the amount FDA determined to be safe. The discussion that follows provides FDA’s thinking about such testing of ingredients that are addressed in this rulemaking, for use in products marketed without approved NDAs. OTC sunscreens marketed under NDAs provide similar information in their productspecific applications to substantiate their labeling. For proposed changes to § 201.327, see codified section of this document. The Stayed 1999 Final Monograph also required SPF testing of final formulations as a GRASE condition. Elsewhere in this proposed rule, we propose to establish monograph conditions in 21 CFR part 352 that ensure that all sunscreens are tested for SPF in accordance with § 201.327(i) and achieve a minimum SPF of 2, and that certain sunscreens pass the broad spectrum test in § 201.327(j). PO 00000 Frm 00026 Fmt 4701 Sfmt 4702 final formulations, which we anticipate requiring in the future for sunscreen products marketed under the sunscreen monograph (unless FDA determines that the ingredient or ingredients contained in the product are unlikely to be absorbed through the skin). Because this testing would not be required for sunscreens containing only those active ingredients proposed here as Category I (zinc oxide and titanium dioxide), FDA has not yet reached a final determination as to the particular parameters that might be required for such final formulation testing. We anticipate that we may specify final formulation testing requirements in the monograph in the future, however, as active ingredients that we are now proposing as Category III may be included in the monograph in the future if FDA receives data supporting their GRASE status. Final formulation testing requirements applicable to such ingredients would be established on an ingredient-specific basis, taking into consideration the data provided to E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules support a positive GRASE determination for the specific ingredient (for example, whether any safety signals are detected in well-conducted nonclinical carcinogenicity and DART studies). We encourage interested parties to provide information and comment for each sunscreen active ingredient that is relevant to establishing this kind of final formulation testing for each active ingredient. FDA’s expectation is that this testing would not generally call for an in vivo study. Instead, FDA expects that the conditions of marketing specified for sunscreens containing a given active ingredient would require manufacturers to perform in vitro permeation testing before marketing each sunscreen formulation containing that ingredient. Consistent with the approach for SPF and broad spectrum final formulation testing set forth in § 201.327 (for proposed changes to § 201.327, see codified section of this document), FDA anticipates that it would not review the results of the in vitro permeation testing before product marketing. Rather, FDA expects that any future conditions pertaining to final formulation in vitro permeation testing in the sunscreen monograph would include a requirement that manufacturers maintain records of this testing, and that those records be available for FDA inspection upon request. FDA anticipates establishing a standard control formulation for each sunscreen active ingredient to be used in the in vitro permeation testing of products containing that ingredient. The standard control formulation would be the formulation that produces the highest in vivo absorption in the MUsT. The results of in vitro permeation testing using this control formulation would then be used as a bridge to a corresponding level of in vivo absorption from the MUsT that is used to establish the safety margin for the ingredient. Then, FDA anticipates establishing conditions to ensure that final formulation in vitro permeation testing would be conducted for each formulation intended to be marketed, using the specified vertical diffusion cell described below. The results of the in vitro permeation testing of each final formulation would be compared to the absorption found in the standard control formulation for the active ingredient it contains. In vitro permeation testing is a methodology that has been used in dermal formulation development for over 30 years and, as used here, specifically refers to use of the ‘‘Vertical Diffusion Cell’’ (Ref. 144). A vertical VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 diffusion cell is comprised of three major units: (1) An upper chamber (into which the sunscreen formulation is placed); (2) the rate-limiting membrane (the prepared human skin); (3) and the lower chamber/fluid channel (containing a receptor fluid that is evaluated to determine how much of the sunscreen it ‘‘receives’’) (Refs. 145 to 147). The vertical diffusion cell system has been commercialized and is available as both single and multiple unit models that can be automated. Other relevant parameters FDA expects to consider in establishing future requirements for in vitro permeation testing include (among other things) the thickness and integrity of collected skin, storage conditions used for collected skin, receptor fluid composition, skin and receptor fluid temperature, the number of skin samples (and donors) used, study duration, sampling period, application method, and number of experimenters. We note that if a final sunscreen formulation contains a combination of sunscreen active ingredients, FDA anticipates requiring that this final formulation be tested against the standard control formulations for each of the sunscreen active ingredients it contains. As noted above, a standard control formulation might not be specified for (and final formulation in vitro permeation testing might not be necessary to establish safety for) a sunscreen containing a particular active ingredient if FDA determines that the ingredient is unlikely to be absorbed through the skin. As mentioned above, we therefore do not propose to require final formulation in vitro permeation testing for sunscreen formulations containing only zinc oxide and/or titanium dioxide. In cases in which such testing is required, FDA anticipates that if the in vitro permeation of each sunscreen active ingredient in the final formulated product is equal to or less than the value obtained from in vitro permeation testing of the standard control formulation for that active ingredient, the product’s safety margin would be considered to fall within the parameters judged to be GRASE, and thus to support marketing of the formulation. However, if the in vitro permeation of the active ingredient from the specific final formulation is greater than the value obtained from in vitro permeation testing of the standard control formulation for that active ingredient, FDA anticipates that the drug product(s) using that formulation would not be considered GRASE. In that situation, the sponsor would have the option to either: (1) Reformulate the product and PO 00000 Frm 00027 Fmt 4701 Sfmt 4702 6229 conduct in vitro permeation testing to establish that the reformulated product satisfies the final formulation in vitro permeation testing requirements set out in the sunscreen monograph or (2) seek NDA approval for the new formulation. IX. Additional Proposed Conditions of Use A. Proposed Requirements Related to Dosage Form OTC sunscreens have been marketed in a variety of dosage forms over the years. Responding in part to the growing market acceptance of spray sunscreens, on June 17, 2011, FDA issued an ANPR addressing sunscreen dosage forms (Dosage Forms ANPR) (76 FR 35669, June 17, 2011). The ANPR identified dosage forms considered eligible or ineligible for review and potential inclusion in the OTC sunscreen monograph, based on FDA’s knowledge, at that time, of their history of marketing before the OTC Drug Review began in 1972. It also solicited specific information about the safety, effectiveness, and directions for use of spray sunscreens. 1. Summary of Eligible and Ineligible Dosage Forms In this proposed rule, FDA is confirming that the following dosage forms identified in the Dosage Forms ANPR are eligible for review and potential inclusion in the OTC sunscreen monograph based on their history of sunscreen marketing before 1972: Oil, lotion, cream, gel, butter, paste, ointment, stick, spray, and powder. With the exception of powder, FDA proposes that sunscreens in these dosage forms are GRASE subject to certain conditions described below and elsewhere in this proposed rule. We note that sunscreen powders were classified as ineligible for review in the Dosage Forms ANPR because, at that time, we were unable to identify any sunscreen products in powder form that were marketed before the OTC Drug Review began. Based on marketing data submitted to the ANPR docket and in a related citizen petition (Docket No. 1978–N–0018–0741), we have determined that the powder dosage form is eligible to be considered for inclusion in the OTC sunscreen monograph. However, as described in section IX.A.4, we tentatively conclude that additional safety and efficacy data will be necessary to classify sunscreens in the powder dosage form as GRASE and include them in the final monograph. We are proposing that sunscreens in all dosage forms other than those identified as eligible for consideration above— E:\FR\FM\26FEP2.SGM 26FEP2 6230 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules including wipes, towelettes, body washes, and shampoos—are new drugs because we did not receive data showing that they were marketed prior to 1972. 2. Overview of Comments on the Dosage Forms ANPR FDA received a total of 14 comments on the Dosage Forms ANPR. Six of the comments provided no new data, but generally supported the advantages of spray sunscreens, agreed with the need to address concerns about spray sunscreens’ performance and/or safety (especially when used on children), opined that existing SPF methods would not need to be modified for sprays, or (in most cases) agreed with FDA’s suggested directions for use. Other comments argued for the inclusion of additional dosage forms identified as ineligible in the Dosage Forms ANPR, but failed to provide supporting marketing data. One comment contained marketing information showing that sunscreen products in powder form, which we had previously identified as ineligible for the monograph, had been marketed in the United States before 1972. The remaining comments (all from industry) provided data and information that directly or indirectly addressed questions raised in the Dosage Forms ANPR concerning the safety, effectiveness, and labeling of spray sunscreens. These comments are discussed in sections IX.A.3 and IX.A.4 below. 3. Safety and Effectiveness of Spray Sunscreens As we recognized in the Dosage Forms ANPR, compared to traditional lotions, oils, and the like, spray sunscreens raise potential concerns of both safety and efficacy that FDA must consider in determining whether sunscreens in the spray dosage form would be GRASE. With respect to efficacy, FDA must consider factors such as whether spraying sunscreen rather than applying it by hand provides effective coverage on exposed skin, how consumers use spray products, and whether current test methods for SPF and broad spectrum protection can be relied on for adequate labeling of spray products. With respect to safety, spray sunscreens raise the question of potential harm from inhalation of sunscreen components as well as potential flammability risks. a. Characteristics of sunscreen spray products. Spray sunscreens use varying technologies to package and deliver a sunscreen formulation as an aerosol spray, i.e., an airborne suspension of VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 fine droplets or particles. In some spray products, the sunscreen formulation is mixed in a canister with a liquefied gas propellant that supplies the force to generate an aerosol containing both dissolved sunscreen formulation and propellant upon activation of a valve system. There are also pump spray sunscreen products that are not packaged under pressure but generate spray by applied mechanical force without the need for a propellant. Many currently marketed spray sunscreen products use a delivery technology referred to as a bag-on-valve system, in which the sunscreen formulation is contained in a bag with an attached valve inside a canister filled with propellant, so as not to mix the sunscreen formulation and propellant ingredients. For purposes of this document, a spray sunscreen product is one discharged from either a pressurized or nonpressurized container, with the understanding that the degree of atomization will likely vary according to the formulation, the container system used, and the design of the spray actuator, among other factors. b. Spray sunscreen performance and effectiveness. The Dosage Form ANPR asked a series of questions relating to the performance and effectiveness of spray sunscreens, including questions about the amount of spray sunscreen typically applied by consumers, uniformity of coverage, how frequently consumers reapply spray sunscreens, whether consumers rub spray sunscreens into the skin when directed to do so and the resulting effect on effectiveness, and whether—and if so, how—the SPF and/or broad spectrum tests need to be modified to address sunscreen sprays. The Dosage Forms ANPR also solicited studies comparing spray sunscreens to other eligible dosage forms to see whether the dosage forms are comparable. Four comments provided data from multiple studies examining and comparing the performance of spray and lotion sunscreens on a variety of parameters, including amounts applied, uniformity of coverage as measured with UV filter photography, comparative SPF results, and consumer ratings of ease and effectiveness of application, among others. FDA’s evaluation of the information submitted indicated that key questions asked in the Dosage Forms ANPR were directly or indirectly addressed by these studies. These studies indicated that consumers like the convenience of spray sunscreens and adapt their use of these products to achieve effective coverage. Data provided on application uniformity lacked study reports and were difficult PO 00000 Frm 00028 Fmt 4701 Sfmt 4702 to compare directly, but—taken together—they suggest a high degree of uniformity between sprays and lotions in coverage of exposed skin, as well as between different spray application scenarios such as spraying directly on skin or spraying followed by rubbing. Information submitted indicated that the amount of spray sunscreen dispensed is higher than the amount dispensed for sunscreen lotions, and that consumers are more likely to reapply sprays than lotions. There was no response from any stakeholder regarding consumers’ compliance with directions to rub a spray sunscreen into the skin. However, data was provided suggesting that rubbing spray sunscreens into the skin did not enhance effectiveness. Based on these comments and the available data, we are not proposing to require that labeling provide instructions to rub spray sunscreens into the skin. Comments on the Dosage Forms ANPR also agreed, and we concur, that the current FDA-required SPF and broad spectrum tests are appropriate for evaluating the efficacy of sunscreens in spray dosage forms. SPF testing requires application of a set amount of sunscreen (2 mg/cm2 on each test subject), which can readily be done for spray sunscreen formulations. For example, comments on the Dosage Form ANPR stated that the SPF testing of sunscreen spray products can be conducted following the method described in the current rule by weighing out the liquid form and applying it to the skin. This premise is supported by data from SPF testing submitted in the comments. For example, one comment submitted five SPF testing reports conducted on sprays using the FDA-required methods, in which the expected SPF values for the test formulations were almost identical to the SPF testing results. The same logic applies to broad spectrum testing, which also uses a defined amount of sunscreen by weight. Based on this information, we conclude that the current and proposed SPF and broad spectrum testing methods are also appropriate for spray dosage forms. c. Spray sunscreen safety. FDA has identified two primary safety concerns specific to spray sunscreen dosage forms: (1) The potential risk of respiratory harm from inhaling sunscreen ingredients and (2) the potential flammability risk when consumers are exposed to flame or heat before spray solvents have completely dried. For the reasons described below, we believe that both potential risks can be acceptably mitigated by proposed formulation limitations, labeling requirements, and adequate testing, and E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules thus propose to establish these as additional conditions in the monograph to ensure that sunscreen products in a spray dosage form would be GRASE. d. Inhalational toxicity. Broadly speaking, the human respiratory system consists of the upper respiratory tract (i.e., the airways of the nose to the larynx) and lower respiratory tract (the trachea and branching airways of the lung, including bronchi, bronchioles, and alveoli) (see generally Refs. 148 and 149). Much of the respiratory system is lined with a layer consisting of mucus cells and cilia that mechanically propel inhaled particles out of the lower respiratory tract toward the mouth, where they may be swallowed or expectorated (Refs. 148 and 149). The most significant concern associated with any product that may be accidentally inhaled is the potential risk of adverse effects associated with deep lung deposition, which occurs when particles in an aerosol (i.e., a suspension of airborne particles such as a sunscreen spray) reach the unciliated airways in the lung. Particles that can reach the unciliated airways of the deep lung are described as respirable and may be associated with serious adverse effects such as asthma, emphysema, bronchospasm, or chronic obstructive pulmonary disease; particles that do not reach the deep lung may be associated with less harmful adverse events such as local irritation of the upper airway, coughing, or sneezing (Refs. 149 to 151). The potential health risk associated with inhalation of hazardous aerosols depends on how much of a toxic substance is deposited in a given region of the respiratory tract and how much remains after physiological clearance occurs through mechanisms such as coughing, sneezing, mechanical transport, or, in the deep lung, engulfment by specialized cells or other protective action (Refs. 148 and 152). The pathogenic potential of inhaled aerosols depends on where in the respiratory tract a particle is deposited (Ref. 152). Whether spray particles that enter the body through inhalation at the nose or mouth will be deposited in the lung depends largely on their physical characteristics: Most notably particle size, with the likelihood of respirability increasing as particle size decreases (Refs. 148 to 153). The effects of particle size on respirability of inhaled particles is well studied. There is general agreement that particles greater than 10 micrometers (mm) in diameter may enter the mouth and the airway up to the larynx. Approximately 50 percent of particles up to 10 mm in diameter can penetrate beyond the larynx to the thoracic region of the respiratory tract, VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 while only particles smaller than 4 mm reach the unciliated airways and alveolar region of the lungs (see generally Refs. 148 to 153). Thus, although there are little or no data on the potential inhalation toxicity of particular spray sunscreen ingredients, we are proposing that exposure to harmful levels of such ingredients can effectively be minimized by imposing particle size limitations on spray sunscreen products. Several comments on the Dosage Forms ANPR submitted results of particle size distribution testing using available methods and apparatus, with the aim of showing that exposure to inhaled sunscreen products or ingredients would be minimal and thus unlikely to cause adverse effects. The data submitted were similar and in some cases overlapping. In an analysis of pooled particle size distribution data from all submissions, representing 50 U.S.-marketed spray sunscreen products, 32 had particles smaller than 4 mm in diameter and thus within the respirable portion of the total particle size distribution. However, the great majority of the particle sizes observed were nonrespirable. The highest percentage that any product had of particles smaller than 4 mm in diameter was 0.43 percent and the mean was 0.22 percent, which is extremely low. In addition to reviewing information from comments on the Dosage Forms ANPR, FDA conducted its own analysis of particle size distribution for 14 marketed spray sunscreens. In those tests, no sunscreen had more than 10 percent of particles in sizes less than 10 mm in diameter and only three had particles smaller than 5 mm (Ref. 154). To limit the risks of unintentional exposure and potential associated adverse events to respirable particles in spray sunscreens, we are proposing limits on the size of particles dispensed from the consumer container for finished spray sunscreens in order for those products to be GRASE. We propose that 90 percent of the particles dispensed from the consumer container must be at least 10 mm or greater in order to limit exposure beyond the larynx, and to prevent deposition in the deep lung, the minimum particle size dispensed from the consumer container must be no less than 5 mm. This limit was chosen because it is the lowest whole number above the generally accepted threshold (4 mm) at which particles enter the unciliated airway and because it allows for experimental error that may be inherent in particle size measurements. Sunscreen products that do not meet both limitations would not be GRASE because there is not sufficient PO 00000 Frm 00029 Fmt 4701 Sfmt 4702 6231 information in the record to support a positive finding about their safety. We believe that, taken together, these two limitations would significantly reduce inhalation risk from spray sunscreens by reducing particle exposure to the larynx and deeper lung tissues. The particle size data submitted in response to the Dosage Forms ANPR also suggest that these limitations would be readily achievable without unduly burdening sunscreen spray manufacturers. With the establishment of these two limits, FDA believes that the risks of adverse events related to unintentional inhalation of spray sunscreens will be minimal. Stakeholders asserted that the risk of inhalation toxicity is already low, primarily based on particle size of marketed sprays. Limited data on adverse event reports and animal toxicity studies were also submitted in a few comments on the Dosage Forms ANPR, but were inadequate to support the safety of spray sunscreens in the absence of particle size limitations. If the particle size limitations proposed here are adopted, however, we do not believe that additional animal toxicity or other safety data need to be provided to support a GRASE finding for spray sunscreens. We are proposing that particle size testing to demonstrate compliance with the proposed limitations must be conducted on spray products as they are dispensed from the consumer container as part of the lot release testing that would be routinely completed as part of current good manufacturing practice (CGMP) compliance under part 211 (21 CFR part 211). It is necessary to test the size of particles dispensed from the consumer container to ensure that particle size requirements are met under conditions of use by consumers. For purposes of these proposed particle size requirements, we are using the term particle size broadly to mean the discrete unit emitted from the spray container that is available for inhalation by a consumer when the product is applied. If the particle dispensed from the consumer container is a droplet that meets the size requirements, the consumer will not accidentally inhale it into the deep lung. However, if that same droplet breaks apart into smaller fractions when it is dispensed from the consumer container, those fractions would be the particles that must meet the size requirement to ensure that consumers will not inadvertently inhale them past the larynx. We are not proposing a specific test methodology for spray sunscreen particle size. Rather, sunscreen manufacturers would be obligated to ensure that particle size testing for their E:\FR\FM\26FEP2.SGM 26FEP2 6232 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules sunscreen sprays would be conducted on each lot of the final product as dispensed from the consumer container in accordance with adequate written specifications. USP General Chapter 601 part B provides methodology and requirements for sprays, aerosols, and powders that include methodology to determine droplet/particle size distribution, and we expect to consider testing done in accordance with the USP as adequate to meet this proposed requirement (Ref. 155). We note that several comments on the Dosage Forms ANPR expressed concern about the potential inhalation risk from exposure to spray sunscreens that contain nanomaterials (as both active and inactive ingredients). One comment also recommended that FDA require the presence of such ingredients to be disclosed on spray sunscreen labels. FDA’s approach to nanotechnology and nanomaterials in sunscreen products is discussed in section VII.E. FDA is not now proposing conditions of use, including labeling, for spray sunscreens that distinguish based on the presence of nanomaterials because we are proposing that any sunscreen spray that contains any particles smaller than 5 mm when it is dispensed from the consumer container would not be GRASE. With respect to nanomaterials in spray sunscreens, we note that the primary determinant of inhalation risk is the size of the particles in emitted sprays, which may be larger than individual formulation components. Nanoscale ingredients would not pass the particle size limitations for spray sunscreens; therefore, if they were to be detected when sprayed from the consumer container during particle size testing, the sunscreen could not be marketed under the OTC monograph. In addition to the proposed limitations on particle size for sunscreen sprays and related testing, we are proposing to require that the following labeling be included in the directions for sunscreen sprays to minimize unintended inhalation: • Hold container 4 to 6 inches from skin to apply. • Do not spray directly into face. Spray on hands then apply to face. • Do not apply in windy conditions. • Use in a well-ventilated area and avoid inhalation. This language is the same as that published in the Dosage Forms ANPR. Its adoption was supported by comments on the Dosage Forms ANPR, and the language is widely used on currently marketed spray sunscreens consistent with the 2018 Final Guidance. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 e. Flammability risk. In July 2013, FDA issued a Consumer Update regarding persons catching on fire while wearing spray sunscreen products near an open flame: The Food and Drug Administration (FDA) has become aware of five separate incidents in which people wearing sunscreen spray near sources of flame suffered significant burns that required medical treatment. The specific products reported to have been used in these cases were voluntarily recalled from the market, so should no longer be on store shelves. . . . In the five incidents reported to FDA, however, the burns occurred after the sunscreen spray had been applied. The ignition sources were varied and involved lighting a cigarette, standing too close to a lit citronella candle, approaching a grill, and in one case, doing some welding (Ref. 156). These cases all involved a single manufacturer’s product that has since been voluntarily recalled. Review of adverse event reports since the voluntary recall of this product indicates that no additional cases involving spray sunscreens have been reported. However, sunscreens are often used in very hot outdoor environments with high ambient air temperatures. Sunscreens are also frequently used around sources of flame or sparks, such as grills, bonfires, smoking, or other ignition sources. To ensure safe use of spray sunscreens and to better inform consumers about potential flammability risks, we are proposing to limit the flammability and require flammability labeling of spray sunscreens under the OTC sunscreen monograph. FDA’s general labeling regulations for OTC drugs provide for OTC monographs to require flammability labeling in suitable cases (§ 201.66(c)(5)(ii)(C)) (21 CFR 201.66(c)(5)(ii)(C))), and we have done so for products such as topical antitussives (21 CFR 341.74) and wart removers (21 CFR 358.150). As we did for those products, we are proposing to require each spray sunscreen formulation to be labeled for flammability in accordance with the testing methodology described in a regulatory provision issued by the Consumer Product Safety Commission (CPSC) (see 16 CFR 1500.43a). We have proposed to incorporate this flash point testing methodology to address our concern regarding the flammability of sunscreen in the spray dosage form after it has been dispensed onto the skin. We therefore propose that all batches of sunscreen spray products be tested for flammability in accordance with 16 CFR 1500.43a as part of batch release testing conducted in accordance with CGMP requirements. We are also proposing to define three flammability categories for use in PO 00000 Frm 00030 Fmt 4701 Sfmt 4702 regulating and labeling sunscreens: (1) Extremely flammable, (2) flammable, and (3) combustible. These definitions refer to flash point testing to be performed using the method described in 16 CFR 1500.43a. These definitions are analogous to certain CPSC definitions located at 16 CFR 1500.3. Given the conditions under which sunscreens may be used, we are proposing that spray sunscreens found to meet the definition of extremely flammable in proposed § 352.3(f) are not GRASE and may not be marketed under the OTC sunscreen monograph. Products found to meet the definition of flammable or combustible in proposed § 352.3(g) or (h) would be required to include the following language in the ‘‘Warnings’’ section of the drug facts labeling: [bullet] ‘‘Flammable’’ or ‘‘Combustible’’ [as applicable] followed by a colon and the statement ‘‘Keep away from fire or flame’’. A further concern related to flammability is the time required for volatile solvents in a spray product to dry on the skin before a consumer can safely approach a source of heat or flame or can smoke without danger of fire. Typical sunscreen spray formulations contain 50 to 80 percent of a volatile carrier, most commonly ethyl alcohol. These volatile solvents are necessary to the formulation to allow the product to be sprayed onto the skin. After spraying, the solvents are intended to rapidly evaporate leaving a film of UV filters on the skin surface as the product dries. Once a spray product is dry, the solvent is no longer present so the flammability risk is low. However, prior to this point, the flammability risk would be higher. We think that consumers should be warned to stay away from sources of flame while a flammable or combustible sunscreen spray dries. For this reason, we propose to require that each batch of a sunscreen spray product that meets the definition of flammable or combustible at § 352.3(g) or (h) be tested for drying time in accordance with written specifications. If the drying time is less than 5 minutes, we propose to require that the labeling state, ‘‘Wait 5 minutes after application before approaching a source of heat or flame, or before smoking.’’ If the drying time is at least 5 minutes but less than 10 minutes, we propose that the labeling would state, ‘‘Wait 10 minutes after application before approaching a source of heat or flame, or before smoking.’’ We propose that a sunscreen spray that is flammable or combustible and that takes 10 minutes or more to dry would not be GRASE because of the possibility of consumers approaching sources of fire E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules during such an extended drying period. We invite comment on this approach. 4. Powder Dosage Forms Although we have found powder sunscreens to be eligible for consideration in the OTC sunscreen rulemaking, we have tentatively determined that additional data as outlined below will be needed to support a conclusion that sunscreens in this dosage form are GRASE and to support consideration of appropriate labeling. Also, like sprays, powder sunscreens pose the potential for unintended inhalation, and for this reason, if admitted to the sunscreen monograph, the same limitations as to particle size here proposed for sprays would be expected to apply. For powder sunscreens that meet the particle size limitations proposed for sprays, we do not expect that additional toxicology data would be needed to address the potential health risks associated with inhalation. One comment on the Dosage Forms ANPR provided data on SPF and broad spectrum performance of five powder formulations, as well as data from repeated insult patch tests and photosensitivity studies that were asserted not to show any safety issues. FDA has conducted particle distribution testing on five powder sunscreens. The powder sunscreens tested had a larger proportion of relatively small particles compared to the sprays. Only one of the five powder sunscreens would have complied with the requirement we are considering that no more than 10 percent of the particles could be smaller than 10 mm in diameter, and that product was also the only one that would have met the prospective limitation of no particles smaller than 5 mm in diameter (Refs. 153 and 154). Based on the data submitted, we believe that (current and proposed) SPF and broad spectrum test methods are appropriate for use with powder sunscreens, and we are not requesting additional respiratory safety information for powders that meet the same particle size limitations proposed for spray sunscreens. FDA invites comments and data on the following topics related to powder sunscreens: • What amounts of powder sunscreens do consumers typically dispense? • What amounts of powder sunscreens are effectively transferred to the skin? • How uniform is the sunscreen application across the sun-exposed area of the skin? VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 • How frequently do consumers reapply the product? • Does rubbing a powder into the skin change sunscreen effectiveness? • Are powder dosage forms waterresistant? If they are not water-resistant, is a direction to reapply every 2 hours sufficient to assure their safe and effective use? • Can the powder dosage form be used safely and effectively over all areas of skin exposed to the sun, or should this dosage form be limited to the face? • What factors, if any, should FDA consider in connection with particle size limitations or test methods for sunscreen powders? • Are there important differences among powder types (e.g., loose, compact) or applicators that would affect particle size testing? FDA will evaluate data and information submitted in response to these questions, as well as any other submitted or available data, to determine whether additional data are needed to support a final GRASE determination for this dosage form. B. Proposed Maximum SPF and Broad Spectrum Requirements In the Stayed 1999 Final Monograph, FDA established SPF 30+ as the maximum labeled SPF value for sunscreen monograph products, and required that each sunscreen monograph active ingredient contribute a minimum SPF of 2 to finished sunscreen products (64 FR 27666 at 27672, 27674 and 27675). The final monograph did not include any broad spectrum protection provisions. In its 2001 decision to stay the final monograph, however, FDA indicated that it was issuing the stay because the Agency intended to amend the sunscreen monograph to address requirements for both UVA and UVB radiation protection (66 FR 67485). FDA later addressed these issues in the 2011 L&E Final Rule, which, among other things: (1) Established optional broad spectrum labeling based on satisfaction of a critical wavelength test, (2) created an optional indication relating to skin cancer and early skin aging risk reduction for broad spectrum products with an SPF of 15 or higher, and (3) required a labeling warning for sunscreens that did not both satisfy the broad spectrum test and provide an SPF of at least 15 (76 FR 35620 at 35626– 35628) (L&E Final Rule). Concurrently with publication of the L&E Final Rule, FDA issued a proposed rule to raise the maximum labeled SPF value for sunscreen products containing sunscreen monograph active ingredients PO 00000 Frm 00031 Fmt 4701 Sfmt 4702 6233 to SPF 50+ (76 FR 35672, June 17, 2011). In the time since these 2011 publications, the body of evidence in the published literature on UVA radiation (particularly UVA I radiation) and its role in the development of skin cancer has grown. This new data about the harms of UVA exposure is a significant concern given, among other things, that with currently available sunscreens, consumers may unknowingly accumulate excessively large UVA doses by using sunscreens with high SPF values that either: (1) Do not pass FDA’s current critical wavelength-based broad spectrum test or (2) have inadequate uniformity in their UVA protection. Because of these concerns, we are making a number of proposals designed, among other things, to couple a greater magnitude of UVA protection to increases in SPF values. 1. Background UV radiation includes both UVA and UVB rays. UVB rays (i.e., those with wavelengths from 290 to 320 nm) are higher energy, are much more effective at producing sunburn, and produce greater amounts of cellular damage (including DNA lesions, which can result in gene mutations linked to skin cancers) (Refs. 157 and 158). UVA rays (i.e., those with wavelengths from 320 to 400 nm) are lower energy and less effective at producing sunburn, but make up the majority of UV radiation, and penetrate much deeper into the skin, potentially causing oxidative damage (through formation of ROS) to skin pigment cells (Ref. 159). UVA rays also contribute to photo-aging (Ref. 157 and 160). Although the current scientific literature attributes UVsignature DNA lesions primarily to UVB wavelengths, UVA wavelengths can also produce DNA lesions. Although UVA wavelengths produce DNA lesions to a significantly lesser degree than UVB wavelengths do, DNA lesions produced by UVA rays have been reported to have slower repair rates (Ref. 157). UVA rays are comprised of UVA I rays (340 to 400 nm) and UVA II rays (320 to 340 nm). As discussed below, until recently, UVA I rays were generally not considered to contribute significantly to the harms associated with UV exposure. Sunscreen products must be labeled with an SPF value calculated using a standardized SPF testing procedure set forth in FDA regulations (see § 201.327(i)). ISO 17166 CIE S 007/E was approved for incorporation by reference into § 201.327(i) as of June 18, 2012 (76 FR 35619, June 17, 2011). The SPF test measures the amount of UV radiation exposure it takes to cause E:\FR\FM\26FEP2.SGM 26FEP2 6234 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules sunburn when a person is using a sunscreen compared with how much UV exposure it takes to cause sunburn when the person is not using a sunscreen. Sunscreens with increasing SPF values (up to a certain point) have been demonstrated to provide increased sunburn protection. Because SPF values represent a sunscreen’s level of sunburn protection, they are primarily (though not exclusively) an indicator of expected protection from UVB radiation. To pass FDA’s current test for broad spectrum labeling (§ 201.327(j)), however, sunscreens must demonstrate that, in addition to UVB protection, they also provide some UVA protection. Only products that have been determined to have a minimum SPF value of 15 and to pass our broad spectrum test may include statements in their labeling indicating that they decrease the risk of skin cancer and early skin aging caused by the sun when used as directed with other sun protection measures (§ 201.327(c)(2)). In contrast, sunscreens that have not been determined to provide both broad spectrum protection and an SPF value of at least 15 must include a skin cancer/skin aging alert warning to consumers that ‘‘[s]pending time in the sun increases your risk of skin cancer and early skin aging’’ and that ‘‘[t]his product has been shown only to help prevent sunburn, not skin cancer or early skin aging’’ (§ 201.327(d)(2)). 2. Increased Evidence of Harms Associated With Exposure to UVA Radiation Since publication of the 2011 L&E Final Rule and Max SPF PR, the strength of scientific evidence linking UVA exposure to skin cancers and other harms has increased. This evidence suggests that UVA wavelengths continue generating DNA lesions hours after UV exposure (Ref. 161) and that if left unrepaired, these DNA lesions can form UV-induced mutations in many genes that have been detected in both melanoma and nonmelanoma skin cancers (Refs. 162 to 165). Further, unlike UVB-induced DNA lesions, which attenuate with skin depth, recent evidence indicates that DNA lesions induced by UVA I exposure show the opposite pattern, with both increased DNA lesions in the basal layer of the epidermis (where melanocytes and proliferating keratinocytes reside) and VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 less efficient DNA lesion repair in the basal layer (Refs. 166 and 167). Damage to cells in the basal layer (if left unrepaired or if inefficiently repaired) can lead to mutations in critical genes that increase the possibility that normal cells will transform into cancer cells. While inefficient DNA repair is a concern for all individuals exposed to UV radiation, this concern is particularly acute in those with xeroderma pigmentosum (a disease caused by a disorder of the DNA repair system), who have extreme sensitivity to UV radiation, and who develop both nonmelanoma skin cancer and melanoma with a high frequency and very early in life (Ref. 168). In addition to the skin cancer-related risks associated with UVA exposure, increasing evidence shows that UVA I radiation also produces immunosuppression (Refs. 169 and 170). This, too, is a general concern for all individuals, but is especially dangerous for certain at-risk populations (such as organ transplant recipients and others on immunosuppressive drugs). Given the above-described evidence, we are concerned about the existing potential for inadequate UVA protection in marketed sunscreen products. This is a particular concern with respect to high SPF sunscreen products that do not pass FDA’s current critical wavelength-based broad spectrum test or that (though they pass our current broad spectrum test) have inadequate uniformity in their UVA protection. Consumers using these products may, while successfully preventing sunburn, accumulate excessively large doses of UVA radiation, thereby exposing themselves to additional risks related to skin cancer and early skin aging. The International Agency for Research on Cancer has found that high SPF sunscreen products are associated with longer intentional UV exposures (Ref. 171), raising the concern that use of these products may result in significant doses of UVA radiation. We note that concerns relating to inadequate UVA protection came up in several comments we received in response to the 2011 Max SPF PR, and that these comments raised particular concerns about inadequate UVA protection in high SPF products. This concern has also grown over time in the published literature (Refs. 172 to 175). For all of these reasons, we are proposing a number of steps designed to PO 00000 Frm 00032 Fmt 4701 Sfmt 4702 couple a greater magnitude of UVA protection to increases in SPF values. As discussed in further detail below, we are also making proposals designed to address evidence of variability in SPF values and evidence showing additional clinical benefits associated with SPF 60 sunscreens. 3. Broad Spectrum Proposals a. UVA I/UV ratio required to pass the broad spectrum test. We are proposing certain changes to the requirements to pass the broad spectrum test. Specifically, we are proposing to add to the current broad spectrum test a requirement that products meet a UVA I/UV ratio of 0.7 or higher. We note that the current broad spectrum test procedure would remain unchanged 40 and that this new ratio would be calculated using data from the existing test, which should help minimize burden on manufacturers. The current labeling regulation requires that sunscreens labeled as broad spectrum achieve a critical wavelength of 370 nm or greater (§ 201.327(j)). A sunscreen product’s UV protection is often displayed as a curve on a graph showing the amount of UV absorbance the product provides at each wavelength in the UV spectrum (i.e., from 290 to 400 nm). The ‘‘critical wavelength’’ of the product is the wavelength corresponding to 90 percent of the area under this curve. Higher critical wavelengths, therefore, illustrate greater breadths of UV protection across the 290 to 400 nm spectrum. Most sunscreen products—even if they achieve a critical wavelength of 370 nm or greater and therefore meet the current criteria for broad spectrum labeling—have historically covered the UVB and UVA II ranges preferentially. Given how much of the UVA portion of the UV spectrum is composed of UVA I radiation (see Figure 3 below) and given what we now know about the risks associated with UVA exposure, and with UVA I exposure in particular, ensuring that sunscreen products provide adequate protection in the UVA I portion of the spectrum is critical. 40 We note that, as described in section IX.D.2.i, we are proposing a minor revision in equipment specifications for the broad spectrum test to respond to feedback that FDA received on this issue and proposing some minor revisions to current language to make clear our existing expectations. E:\FR\FM\26FEP2.SGM 26FEP2 We are therefore proposing to require that in order to pass the broad spectrum test, a product must demonstrate that it provides a UVA I/UV ratio of 0.7 or higher, indicating that the product provides a minimum measure of UVA I radiation absorbance relative to total UV radiation (i.e., UVB + UVA) absorbance, in addition satisfying to the 370 nm critical wavelength requirement. Requiring a UVA I/UV ratio of 0.7 or higher for broad spectrum products would mean that these products would have a more uniform amount of radiation protection across the UVA I, UVA II, and UVB ranges. This improved fidelity across the UV spectrum is especially important for high SPF products which, as discussed above, are associated with longer intentional sun exposure, which in turn can result in significant doses of UVA radiation. This proposed UVA I/UV ratio would also help eliminate the current potential for a product labeled as broad spectrum that has a higher SPF value to provide (unbeknownst to the consumer) poorer broad spectrum protection than a product labeled as broad spectrum with a lower SPF value (depending on the VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 particular combination of active ingredients used in the product and which parts of the UV spectrum they absorb). For example, under the current testing regime, a sunscreen that is labeled ‘‘broad spectrum SPF 30’’ could provide less UVA protection than a sunscreen labeled ‘‘broad spectrum SPF 15.’’ We note that FDA first raised concerns relating to the adequacy of UVA protection in sunscreen products in 2007 (see 72 FR 49070 at 49104 to 49107). At that time, we proposed a similar ratio to the one we are proposing today as part of a different, more complex proposal for testing and labeling to address broad spectrum protection that, among other things, included both in vitro (spectrophotometric) and in vivo (clinical) testing for UVA radiation, as well as a four-tier UVA star rating labeling system. In response to comments describing purported disadvantages of that proposal, including general comments that the proposal was overcomplicated, specific comments on the proposed in vitro testing method, and comments PO 00000 Frm 00033 Fmt 4701 Sfmt 4702 6235 indicating that ‘‘[t]he proposed ratio places too much emphasis on the UVA I region, which is not generally considered to contribute significantly to the harmful effects of exposure to UV radiation’’ (76 FR 35620 at 35650), we made a number of changes to our 2007 proposal in the 2011 L&E Final Rule. Those changes included elimination of the UVA I/UV ratio and adoption of the above-described critical wavelength test for establishing broad spectrum protection instead. As we noted in the preamble to the L&E Final Rule, our decision not to require the UVA I/UV ratio at that time was based, in part, on our agreement with comments stating that the scientific evidence available at that time indicated that UVA I exposure did not pose sufficient risk of harm to justify the emphasis placed on it by the ratio, and that the critical wavelength test provided a superior measure of broad spectrum protection (id. at 35650). As described above, in the time since issuance of the L&E Final Rule, the body of evidence showing the harms of UVA exposure, and of UVA I exposure, in particular, has grown significantly (Refs. E:\FR\FM\26FEP2.SGM 26FEP2 EP26FE19.002</GPH> Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules 6236 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules 159, 161, 162, 166, 167, and 169). It is now clear that in addition to producing the immunosuppression described above, UVA I exposure also results in increasing DNA damage with increasing skin depth (in contrast to UVB-induced DNA damage, which is reduced as skin depth increases). In addition, given that UVA I is the predominant portion of UVA radiation, new evidence (discussed in section IX.B.2) strengthening the link between UVA radiation and skin cancer development raises our concerns about the potential for inadequate protection in the UVA I portion of the UV spectrum. Accordingly, we no longer agree with the earlier comments suggesting that UVA I does not contribute significantly to the harmful effects of exposure to UV radiation, or with our 2011 conclusion that a UVA I/UV ratio requirement would therefore place too much emphasis on this portion of the UV spectrum. We emphasize that we are not proposing to replace the existing critical wavelength test, and that the proposed ratio would supplement (and be calculated using data from) the existing broad spectrum test. We also note that the UVA I/UV ratio we are proposing would result in a level of UVA protection similar to what is achieved via the European Union’s recommended minimum UVA protection factor of 1⁄3 of the labeled SPF and via the United Kingdom’s Boots 3-star rating (the United Kingdom has for decades used a tiered star rating system based on an alternative ratio method) (Refs. 173 and 174). We note that data collected in 2009 about 330 sunscreen products commercially available in the United States showed that, at that time, more than half of these products already satisfied the broad spectrum test we are now proposing (see Comment, Docket No. FDA–1978–N–0018–0690). b. Broad spectrum requirement for all products that are ≥SPF 15. We are also proposing to require that all sunscreen products with SPF values of 15 and above demonstrate that they provide more uniform protection across the UVA I, UVA II, and UVB ranges of the UV spectrum by satisfying FDA’s revised broad spectrum test. This proposal is designed to link increases in SPF value not only to increases in UVB protection, but to increases in the magnitude of UVA protection as well. We note that a consumer using a sunscreen that provides robust protection against sunburn but that does not pass FDA’s revised broad spectrum test—and therefore provides inadequate UVA protection—may fail to get out of the sun, thereby exposing themselves to VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 higher levels of UVA radiation than if they had not been protected from sunburn. Given the increasing evidence of major health risks associated with UVA exposure, we propose to find that such products (those with SPF values of 15 and greater that do not provide sufficient protection across the UV spectrum (as demonstrated by satisfying FDA’s revised broad spectrum requirement)) are not GRASE. At the same time, we conclude that the evidence described above regarding the contribution of UVA I to skin carcinogenesis, coupled with the evidence reviewed in the 2011 L&E Final Rule (see 76 FR 35620 at 35630– 35634), supports the proposal to include sunscreen products that have an SPF of 15 or higher and also pass the revised broad spectrum test in the sunscreen monograph with indications both for use to help prevent sunburn and for use, as directed with other sun protection measures, to reduce the risk of skin cancer and early skin aging caused by the sun. As we indicated in the L&E Final Rule, the whole range of UV radiation, and not specific wavelengths, is a human carcinogen, and the exact wavelengths most responsible for these harmful effects are not known (see id. at 35631, 35633). To assure that a clinically meaningful reduction in the risks of skin cancer and early skin aging is achieved, then, a product must contribute to substantially limiting overall UVB and UVA exposure (see id. at 35630, 35631–35632), as will be assured by our proposal to couple the enhanced breadth of protection across the UVA spectrum provided by the revised pass criteria for the broad spectrum test with the magnitude of protection assured by requiring a minimum SPF of 15. By requiring that all sunscreens with SPF values of 15 or more satisfy the (new) broad spectrum standard (including the new ratio requiring proportionate protection), this proposal will also enable consumers to select a product primarily by numerical (SPF) value on the label, having assurance that, when used as directed, a product labeled with a higher numerical SPF value provides proportionately more protection not only against sunburn, but also against skin cancer and skin aging than lower numbered products 41 (provided that the product provides an SPF of at least 15). In doing so, this proposal also eliminates another source of potential confusion permitted by the 41 As noted in section III.A.2, only those broad spectrum sunscreen products that have an SPF of 15 or higher have been shown to help prevent skin cancer and early skin aging. PO 00000 Frm 00034 Fmt 4701 Sfmt 4702 current labeling regime, in which a higher numbered product (for example, one labeled SPF 30) may provide inferior protection against UVA radiation than a lower numbered product (for example, one labeled Broad Spectrum SPF 15). c. Sunscreen products with SPFs <15. As noted above and in section III.A.2, sunscreen products with SPF values below 15 have not been shown to reduce the risk of skin cancer or early skin aging caused by the sun, whether or not they provide broad spectrum protection. Because of this limitation, we considered proposing to remove from the monograph sunscreen products with SPF values lower than 15. However, as the Surgeon General has acknowledged (Ref. 5), some consumers may seek intentional sun exposure because (for example) they associate tanned skin with attractiveness and health. These consumers may seek some protection from sunburns and therefore, select a low SPF product (i.e., one with an SPF value below 15). If such products are removed from the market, these consumers may choose not to use a sunscreen product at all rather than use a broad spectrum product with an SPF of 15 or above. Although the benefits of sunscreen products with SPFs below 15 (which are not indicated to reduce the risk of skin cancer or early skin aging) are limited, FDA believes that the use of such products is preferable to the use of no sunscreen at all. Thus, to provide sunburn protection for these consumers, FDA is proposing that sunscreens with SPF 2 to 14 that bear prominent labeling regarding their limited use for sunburn prevention and the risks associated with spending time in the sun (see sections IX.B.1 and IX.C) may remain on the market without approved NDAs. Because products with SPFs below 15 have not been demonstrated to reduce the risk of skin cancer, FDA is not proposing to require products with SPF values under 15 to pass the broad spectrum test. However, we seek comment on whether the limited benefits such sunscreen products confer outweigh the risks of sunscreen drug exposure and the potential false sense of security provided regarding UV protection (i.e., whether such sunburnonly sunscreen products are GRASE and should remain on the market without approved NDAs). 4. Maximum SPF Value Proposals a. Maximum labeled SPF value would be SPF 60+. In conjunction with the broad spectrum proposals described above, we are also proposing to raise the maximum labeled SPF value for E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules products containing sunscreen monograph active ingredients to SPF 60+. Under this proposal, sunscreen products with SPF values of 60 or greater would be labeled ‘‘SPF 60+.’’ FDA has proposed to raise the maximum SPF value that sunscreens marketed pursuant to the OTC Monograph System can display on their labeling several times. In the 1978 notice of proposed rulemaking, we proposed that such sunscreens be labeled with a maximum SPF value of 15 (43 FR 38206 at 38213 to 38214). In the 1999 final monograph, we determined that that cap should be increased to SPF 30+ (64 FR 27666 at 27675). In 2007 (72 FR 49070 at 49085 to 49087) and then in 2011 (Max SPF PR), we tentatively concluded that data existed to show that sunscreens with labeled SPF values of up to 50+ provide additional clinical benefit to consumers. Our proposal today to increase the maximum labeled SPF value to 60+ is similarly based on data showing the additional clinical benefit provided by SPF 60 sunscreen products when those products also provide broad spectrum protection. In the 2011 Max SPF PR proposing an SPF 50+ cap, we noted that the record, at that time, lacked adequate data demonstrating that sunscreen products with SPF values above 50 provided additional meaningful clinical benefit over and above what was provided by SPF 50 protection (76 FR 35672 at 35672 to 35674). We requested data showing that such clinical benefits existed (id.). In response to both the 2007 and 2011 proposals, we received comments providing citations to data showing the additional meaningful clinical benefit provided by sunscreen products with SPF values of 60 for certain at-risk populations when those sunscreens also included broad spectrum protection. (See, e.g., Ulrich et al. (showing statistically significant protection of organ transplant recipients, who are highly susceptible to nonmelanoma skin cancer, from squamous cell carcinoma with use of broad spectrum SPF 60 sunscreen) (Ref. 176); see also Comment FDA–1978–N– 0018–0710, August 31, 2011, citing Kuhn et al. (showing statistically significant prevention of skin lesions in topical lupus erythematosus patients with use of broad spectrum SPF 60 sunscreen after exposure to either UVA I source or UVA II/UVB source) (Ref. 177); Faurschou et al. (showing prevention of urticarial reaction in subjects with idiopathic solar urticaria with use of broad spectrum SPF 60 sunscreen) (Ref. 178); Fourtanier et al. (showing lower levels of polymorphous VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 light eruption in subjects using broad spectrum SPF 60 versus SPF 50 products (Ref. 179)). Based on the additional meaningful clinical benefit provided by broad spectrum SPF 60 sunscreens shown in these studies, we are proposing to raise the maximum labeled SPF value to SPF 60+. Because the studies demonstrating the additional meaningful clinical benefit provided by SPF 60 sunscreens all used sunscreens that also provided broad spectrum protection, however, the additional clinical benefit shown to exist at SPF 60 cannot be decoupled from the broad spectrum protection provided by those products. That is, the additional meaningful clinical benefit shown in these studies may have been the result of the sunscreens’ protection against rays in the UVB range or in the UVA range, or both. For this reason, our proposal to recognize the additional meaningful clinical benefit provided by sunscreens with SPF values above 50 is consistent with, and dependent upon, our proposal that all sunscreen products with SPF values of 15 and above be required to provide broad spectrum protection. Given the lack of data showing that sunscreens with SPF values above 60 provide additional meaningful clinical benefit, however, we are proposing not to allow labeled SPF values higher than 60+. Labeling sunscreen products with SPF values higher than what has been shown to provide additional meaningful clinical benefit could have unintended negative consequences. For example, as discussed above, such products may inadvertently promote extended solar exposures because consumers feel protected and assume that the higher SPF value implies that greater UV exposure is safe (see, e.g., Autier, et al., 2007 (Ref. 171)). b. Formulation cap for sunscreen products of SPF 80. Although we are proposing that the maximum labeled SPF value will be SPF 60+, we are proposing to permit the marketing of sunscreen products formulated with determined 42 SPF values up to 80. We are proposing to permit this additional formulation margin in part because of the inherent variability in SPF test results. A sunscreen product’s SPF value is calculated from measurements that are based on an investigator’s visual evaluation of an individual test subject’s erythema response to a series of UV doses administered in successive sites 42 As used in this preamble, the determined SPF value is the SPF value that equals the largest whole number less than SPF¥(t*SE), determined for a sunscreen product in accordance with § 201.327(i). See also section IX.D.2.b, where we propose to define this term in the regulation. PO 00000 Frm 00035 Fmt 4701 Sfmt 4702 6237 on the subject’s back. Because the administered UV dose series for the final minimal erythema dose (MED) 43 of a sunscreen with an expected SPF of 60 increases by 15 percent with each successive dose (see § 201.327(i)(5)(iii)), a difference in judgment of one site in opposing directions would result in up to approximately 30 percent variability in the assessment of the amount of exposure that resulted in the erythema.44 Allowing the marketing of sunscreen monograph products with determined SPF test results up to 80 would, therefore, more fully account for the range of variability in SPF test results for sunscreen products labeled SPF 60+. We are also proposing this formulation margin to provide manufacturers with additional formulation flexibility that we hope will help facilitate the development of products with greater UVA protection, given our expectation that active ingredients added for the primary purpose of increasing UVA protection would contribute to a sunscreen’s determined SPF value as well. We seek comment on whether SPF 80 is the appropriate formulation cap to accomplish these objectives. We are proposing not to allow the marketing (without an approved NDA) of sunscreen products with determined SPF values above SPF 80. This proposal follows from the principle that if the addition of ingredients to a drug does not provide additional clinical benefit but potentially increases the risk associated with the drug, this shifts the benefit-risk calculation and renders the drug not GRASE (see, e.g., 76 FR 35673 at 35675). In light of this principle, we solicited comments in 2011 on the appropriateness of a formulation cap for sunscreen products (id.). Some of the comments that we received in response to the 2011 Max SPF PR expressed concerns (in general) about the safety of unnecessary exposure to sunscreen active ingredients. We received only one comment, however, directly addressing the question of an SPF formulation cap. That comment emphasized that there was no formulation limit in other countries using an SPF labeling cap, and 43 The minimal erythema dose (MED) is the smallest UV dose that produces perceptible redness of the skin (erythema) with clearly defined borders at 16 to 24 hours after UV exposure (§ 201.327(i)(5)(i)). 44 The determination of SPF for each subject is calculated via a ratio of the MED of protected skin over the final MED of unprotected skin. In a scenario in which the final MED of unprotected skin is underestimated by 15 percent and the MED of protected skin is overestimated by 15 percent, this would present approximately 30 percent variability for the individual subject. E:\FR\FM\26FEP2.SGM 26FEP2 6238 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules that the list of permitted active ingredients in the monograph itself establishes an SPF ceiling for the formulation as a whole. FDA rejects the premise that the list of permitted active ingredients establishes an adequate SPF cap for sunscreen formulations, as this theory does not take into account the potential addition of new GRASE ingredients to the list of active ingredients under the monograph. This comment also appears to imply that the maximum concentration of each active ingredient correlates specifically to a particular numerical contribution to the total SPF value of the product. This has not been established (see 64 FR 27666 at 27674 and 27675 (noting that formulation techniques may enable increases in SPF without use of higher concentrations of active ingredients)). In addition, as mentioned in 2011 in the Max SPF PR (76 FR 35672 at 35674), the theoretical increase in protection implied by higher SPF values generated in a laboratory does not necessarily correspond to meaningful additional sunburn protection for consumers in actual use conditions. Given that a solar simulator in a lab can produce much higher UV doses than a consumer would receive from the sun (even in the most extreme situations), it is unlikely that a consumer could ever actually reach the theoretical ceiling created by the list of permitted active ingredients. Given the lack of demonstrated clinical benefit for sunscreens with determined SPF values above SPF 60, and the potential for risks—discussed elsewhere in this document—associated with exposure to sunscreen active ingredients, we propose not to permit the marketing (without an approved NDA) of sunscreen products with determined SPF values above SPF 80 (which reflects a formulation margin intended both to give full effect to the SPF 60 limit and to enable formulation flexibility). c. Proposal for ≥SPF 15 labeling. Finally, we are proposing to require that sunscreen monograph products with determined SPF values of 15 or above be labeled with an SPF number corresponding to the lowest number in a range of tested SPF results, as shown in table 5.45 For example, sunscreens testing at SPF 15 to 19 would be labeled ‘‘SPF 15’’; those testing at 40 to 49 would be labeled ‘‘SPF 40.’’ 46 45 We note that the use of ranges to represent SPF values on product labeling is already in use in Australia and the European Union (Refs. 180 and 181). 46 The proposed labeled values are expressed in increments of 5 for products with determined SPF results of 15 to 29.9 (i.e., SPF 15, SPF 20, SPF 25), but for determined SPF results of 30 or more, the VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 This proposal is designed to avoid misleading consumers about the relative efficacy of sunscreen products, given the lack of clinical data showing meaningful efficacy differences between closely grouped SPF values. We note that in the 2011 L&E Final Rule, FDA declined a request that SPF be labeled in multiples of five, stating that there was no mathematical or statistical basis for this labeling approach because SPF values could generally be determined with a precision that allowed for SPF values to be labeled in intervals of less than five units. New data showing variability both between tested SPF values for individual study subjects and for determined SPF results achieved across multiple labs testing the same sunscreen formulation (i.e., variability inherent in a clinical test that relies on visual assessments) (FDA–1978–N– 0018–0740, 2011; Ref. 182), however, has caused us to reexamine this issue. As described above, the clinical SPF test is conducted using a solar simulator to administer several specified doses of UV radiation that increase by 15 to 25 percent with each successive dose to a human subject’s back in both sunscreentreated and untreated areas (with the specific UV doses being derived from the expected SPF of the product and a determination of the individual subject’s UV sensitivity). The clinical investigator then visually evaluates both the sunscreen-treated and untreated areas of the subject’s back to identify the areas with perceptible skin redness (erythema) that has clearly defined borders. Determining which of several areas on a single subject’s back should be considered to meet this ‘‘clearly defined borders’’ criteria is an exercise of clinical judgment. Once the investigator has made this judgment, he or she then records the smallest dose of UV radiation it took to create an area with the observed skin reaction of erythema with clearly defined borders. After assessing multiple individual test subjects this way, the resulting UV exposure information is used in calculating the determined SPF value of the sunscreen being tested. The data we reviewed suggest that the clinical evaluation undertaken during this process creates variability that justifies the use of SPF ranges. For example, in a study using panels of five subjects, the mean SPF values observed across multiple labs ranged from 54 to 82 for a target SPF 80 (FDA– 1978–N–0018–0740, 2011). This same study also evaluated a scenario where a proposed labeled values are expressed in increments of 10 (i.e., SPF 30, SPF 40, SPF 50, with a proposed maximum of SPF 60+.). PO 00000 Frm 00036 Fmt 4701 Sfmt 4702 lab was not told the target SPF, but was rather given a range of SPF 20 to 100 for a product with an expected SPF of 100. The results showed that it was extremely difficult for labs to reproduce the labeled SPF 100, with mean SPF values ranging from 37 to 75. In a second study with multiple panels of 25 subjects that was controlled and randomized, the determined SPF of two sunscreen formulations tested across four labs ranged from 63 to 69 for a target SPF 70 and from 82 to 89 for a target SPF 90 (Ref. 182). Although the magnitude of the differences observed in this second study were not statistically significant, the fact that multiple labs determined different specific numerical values for a single formulation suggests that the use of labeled values representing ranges more accurately represents the sun protection provided by a product, and therefore is appropriate to avoid misleading consumers. We note that variability in SPF values is exacerbated at high SPFs. For example, individual test results with 30 percent variability from a determined SPF value of 20 would range from SPF 14 to SPF 26; individual test results with 30 percent variability from a determined SPF value of 50 would range from SPF 35 to SPF 65. Accordingly, as shown in table 5, we propose that the range of tested values reflected in the labeled SPF number should be wider at higher SPF values and narrower at lower ones, and that the requirement that labeled SPF values correspond to ranges rather than precise numerical values is not necessary below SPF 15. TABLE 5—PROPOSED SPF LABELING RANGES Range of determined SPF values Associated labeled SPF value 60–80 .................... 50–59 .................... 40–49 .................... 30–39 .................... 25–29 .................... 20–24 .................... 15–19 .................... 2–14 ...................... 60+. 50. 40. 30. 25. 20. 15. Determined SPF Value. C. Proposed PDP Labeling Requirements We are also proposing some revisions to the principal display panel (PDP) for sunscreen products (the PDP is the portion of an OTC drug product label that is most evident when the product is displayed for retail sale (§ 201.60)). In addition to satisfying general OTC drug labeling requirements found in part 201, E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules sunscreen product PDPs are currently required to satisfy specific labeling requirements in § 201.327. We are proposing to amend these requirements for sunscreen PDP labeling (currently codified in § 201.327(a) and (b), and (for the statement of identity of products that also include skin protectants) in § 201.327(h)) to help consumers better understand, evaluate, and compare sunscreen products by providing additional information on the PDP, and by ensuring the prominence and readability of information required to appear on the front of the container or package. We are also proposing to renumber and consolidate provisions on PDP labeling and the statement of identity (SOI) in § 201.327(b) to incorporate new proposed provisions in § 201.327(a), as described in section IX.D.2.b of this preamble. In addition, we are proposing that labeling a sunscreen product in accordance with proposed § 201.327(b) would be a condition for marketing a sunscreen under the OTC sunscreen monograph in part 352. We are proposing to revise the current SOI, which is required to appear on the PDP by both current and proposed § 201.327. Currently, the SOI for sunscreens under this regulation contains ‘‘the established name of the drug, if any’’ and identifies the product as a ‘‘sunscreen.’’ The revised SOI would consist of an alphabetical listing of all sunscreen active ingredients in the product using the names shown in § 201.327, followed by ‘‘Sunscreen’’ and the product’s dosage form (such as lotion or spray). In light of these proposed changes to the SOI for sunscreens, we are also proposing harmonizing changes to the provisions that address the SOI for products that combine sunscreen and skin protectant active ingredients (proposed § 201.327(h) and cross-referenced in the sunscreen monograph in § 352.60 (21 CFR 352.60) and in the skin protectant monograph in § 347.60 (21 CFR 347.60)). The proposal to list all active ingredients as part of the SOI is generally consistent with SOI labeling of other OTC and prescription drugs. Providing information about a product’s active ingredients and dosage form would supplement other important elements of the PDP (SPF, broad spectrum, and water resistance information) to provide a succinct summary of the product’s key characteristics on the front of the package or container. We expect that this approach would enable consumers to more readily compare differing products and either select or avoid a VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 given product accordingly. As an indication that consumers value information about a sunscreen’s active ingredients, an analysis of top-rated sunscreen product reviews on Amazon.com found that product ingredients were listed as a positive factor in 17 percent of responses, and a negative factor in 10 percent of responses (Ref. 183). Based on a review of marketed sunscreen product labels, FDA is concerned that the SOI may currently be obscured by the inclusion and prominence of other printed or graphic information on the PDP. For this reason, we also propose to require the SOI to appear in direct conjunction with the most prominent display of the proprietary name, in a boldface font at least one-fourth the size of the most prominent printed matter on the PDP, and displayed so that the text is generally parallel to the base of the packaging. We propose that the entire SOI appear in the same font style, size, and color with the same background color, and as continuous text with no intervening text or graphic material other than text provided in accordance with the requirements for the SOI for a product that also includes a skin protectant, where applicable. These requirements would supplement, and not replace, the general requirements regarding the PDP and SOI for all nonprescription products in §§ 201.60 and 201.61. Proposed § 201.327(b) would incorporate the ‘‘Broad Spectrum SPF,’’ ‘‘SPF,’’ and ‘‘Water Resistant’’ statements that already must appear on the PDP as described in current § 201.327(a). Additionally, for all products with SPF values below 15, we propose to require that the SPF statement be followed by an asterisk (*) directing the consumer to the statement ‘‘*See Skin Cancer/Skin Aging Alert.’’ We propose that the quoted statement must appear in the bottom 30 percent of the PDP. This statement is intended to draw the consumer’s attention to the Skin Cancer/Skin Aging Alert that would continue to be required for these products as part of the ‘‘Warnings’’ in the Drug Facts portion of the label (§ 301.327(d)), because there is evidence that some sunscreen consumers are not reading this information in its current location (Refs. 184 and 185). Under the current regulation, the entirety of the ‘‘Broad Spectrum SPF’’ or ‘‘SPF’’ statement, as applicable, must appear on the sunscreen PDP in the same font style, size, and color and with the same background color, and, if used, the ‘‘Broad Spectrum SPF’’ statement must also appear as continuous text PO 00000 Frm 00037 Fmt 4701 Sfmt 4702 6239 with no intervening text or graphic. To further ensure the prominence and readability of information that is important for consumers to evaluate and compare sunscreen products, we propose that these statements must also appear in bold typeface at least onefourth the size of the most prominent printed matter on the PDP, and as text generally parallel to the base of the packaging. The proposed new ‘‘*See Skin Cancer/Skin Aging Alert’’ statement would also be required to appear in bold typeface at least one-fourth the size of the most prominent printed matter on the PDP, and as text generally parallel to the base of the packaging. In addition, the entire statement would appear in the same font style, size, and color with the same background color, and as continuous text with no intervening text or graphic. Finally, because water resistance is also an important characteristic for consumers when choosing a sunscreen, we also propose to apply comparable format requirements to the current ‘‘Water Resistant’’ statement. The statement would also be required to appear in bold typeface at least onefourth the size of the most prominent printed matter on the PDP, and displayed so that the text is generally parallel to the base of the packaging. In addition, the entire statement would appear in the same font style, size, and color with the same background color, and as continuous text with no intervening text or graphic. D. Proposed Requirements Related to Final Formulation Testing and Recordkeeping We are also proposing a number of revisions in § 201.327: (1) To ensure that efficacy testing of the sunscreen formulation to be marketed is conducted in a way that protects human subjects and produces reliable results and (2) to enable FDA to assess compliance with this section’s provisions going forward. We also propose to make compliance with these requirements a monograph condition in part 352. 1. General Approach to Final Formulation Testing Current § 201.327 includes technical instructions for conducting the final formulation testing required to support the SPF values, water resistance statements, and broad spectrum statements shown in sunscreen product labeling. However, the current regulation does not explicitly address important broader considerations that are essential to ensure that final formulation testing is conducted and E:\FR\FM\26FEP2.SGM 26FEP2 6240 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules documented in a way that verifiably provides for protection of human subjects in SPF and water resistance testing, as well as ensuring the reliability of all the testing data that underlies sunscreen labeling. We expect that persons responsible for conducting final formulation testing should already be following best practices in their current testing programs. However, we are concerned that many entities may not uniformly observe such practices and/or may not maintain the records needed to document compliance with the final formulation testing procedures set forth in § 201.327. FDA’s experience in conducting inspections and other actions to verify testing under the current provisions of § 201.327 have suggested latent problems in these areas. Although limited, this experience reinforces FDA’s belief that further clarification of regulatory expectations is necessary given the public health importance of ensuring that sunscreen products are effective and accurately labeled, and the broad range of entities that may be involved in bringing sunscreen products to market. Thus, we are proposing to incorporate FDA’s current expectations more explicitly in the revised provisions. The proposed provisions are broadly consistent with current best practices for efficacy testing conducted in human subjects, and are not expected to require significant changes by reputable and experienced testing establishments. Key areas of concern that are addressed by the proposed revisions include the following. a. Protection of human subjects and oversight of clinical final formulation testing. Ensuring that clinical final formulation testing is both designed and conducted in a manner that will yield reliable results is critical, as is ensuring the protection of the human subjects on whom SPF and water resistance testing are conducted. Existing provisions within the SPF test in § 201.327(i)(3)(iv) require that informed consent be obtained, but do not otherwise specify what this should involve or how clinical final formulation testing should be overseen. Across disciplines, testing involving human subjects is ordinarily conducted under institutional review board (IRB) oversight as a means of ensuring that informed consent and other human subject protections are provided and ensuring the integrity of study design and execution. FDA likewise expects that IRB review is already routinely being obtained by many establishments for SPF and water resistance testing. Nonetheless, our experience in conducting inspections and other VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 actions to verify the reliability of final formulation testing under the current provisions of § 201.327 have raised some questions about current practices. For example, FDA’s observations have raised questions about whether and how entities conducting final formulation testing have put in place protocols and IRB oversight to ensure that test subjects do not repeat participation in testing with a frequency that could both compromise the ability to distinguish erythemic reactions to the test article and raise other questions about human subject protection. We are concerned that the lack of explicit requirements with regard to IRB oversight, as well as the cursory nature of the informed consent requirement in the current sunscreen labeling regulation, may result in inconsistent practices in the conduct of SPF testing that would compromise the reliability of results. Among other things, IRB review is critical to verify the adequacy of informed consent and to ensure that study protocols incorporate appropriate inclusion/exclusion criteria for subject selection (both to protect test subjects and to ensure the accuracy of results). b. Qualifications of study personnel. In some instances, it may not be clear upon inspection whether all aspects of a study were conducted by appropriately qualified personnel. For example, FDA would not consider it adequate for a technician, rather than an appropriately trained medical professional (such as, for example, a nurse or dermatologist), to perform a physical examination for potential nevi, moles, or other dermal lesions. As with all clinical and nonclinical testing done to support labeling, the use of properly trained and appropriately qualified personnel is essential to ensure the reliability and accuracy of test results. Documentation of the qualifications and training of personnel is also necessary to enable FDA’s efficient enforcement of the FD&C Act. c. Documentation of equipment maintenance, study methods, and observations. Failure to maintain adequate records of testing equipment, methods, and observations can raise broad questions about the reliability of final formulation testing. In FDA’s experience since the promulgation of current § 201.327, there has been a lack of uniformity in testing entities’ approaches to recordkeeping for final formulation testing, raising concerns about the adequacy of recordkeeping procedures. Failure of testing entities to keep adequate records to support final formulation testing may leave FDA unable to verify that the UV doses provided in SPF and water resistance PO 00000 Frm 00038 Fmt 4701 Sfmt 4702 test reports are accurate and valid. This is also true with respect to documentation of emission spectrum, the percentage of erythema-effective radiation contribution, and changes to solar simulator components and the UV meter/dose controller system. Failure to accurately calibrate and maintain equipment at one testing entity may affect data across multiple clinical SPF testing studies and/or broad spectrum testing for multiple different final formulations that are ultimately sold under different labels. Inadequate recordkeeping may interfere with efficient enforcement. We propose to address these concerns and align the regulation with our existing expectations through revised regulatory provisions that are described further in the following sections. 2. Specific Regulatory Proposals a. Consequences of failure to observe best practices. We propose to clarify in the introductory paragraph of § 201.327 that a product is deemed misbranded if its labeling relies on the results of final formulation testing that was not conducted in compliance with all of the applicable provisions of § 201.327. Unless testing is conducted in compliance with all applicable provisions of § 201.327, FDA does not have adequate assurance that the labeling reliably reflects the properties of the sunscreen product. Therefore, if final formulation testing is not properly conducted in accordance with this section, labeling a sunscreen with an SPF value or representation of water resistance or broad spectrum properties based on that testing is a misrepresentation to the consumer that the labeling reliably states the product’s properties, which should also be consistent with a system of standardized sunscreen labeling that can be used to make cross-product comparisons. We propose to incorporate the provisions of § 201.327(a) through (l) into part 352 as conditions under which a sunscreen is GRASE and not misbranded. If these provisions are finalized, failure to comply with these conditions would make a drug subject to regulatory action as misbranded and an unapproved new drug. b. General obligations of responsible persons. We are aware that many different business relationships involving numerous entities are commonly used in the manufacturing, testing, and labeling of nonprescription sunscreen drug products. To clarify the locus of responsibility for ensuring that adequate final formulation testing procedures are in place, and to clearly delineate responsibility for E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules recordkeeping related to final formulation testing, FDA proposes a new defined term, responsible person. We propose to define the term responsible person in a way that is consistent with FDA’s treatment of regulatory responsibilities for other OTC drug products and that is in alignment with requirements for adverse event reporting for over-the-counter drug products, in section 760(b)(1) of the FD&C Act. The proposed definition for responsible person is ‘‘the manufacturer, packer, or distributor whose name appears on the labeling of a sunscreen product covered by this section.’’ Defining responsible person in this way will enable FDA to better assess compliance with § 201.327 because it creates a chain of responsibility that is immediately apparent from the product’s labeling. The responsible person, as identified on the labeling, is ultimately responsible for ensuring that the product bearing its name is labeled in accordance with the requirements of § 201.327. The proposed revision of § 201.327(a) would broadly set forth the general obligations of responsible persons with respect to final formulation testing under § 201.327(i) and (j), and it would make clear that the responsible person is charged with ensuring that sunscreen products are appropriately tested. The obligations of responsible persons as enumerated in § 201.327 are modeled after those of investigational new drug application (IND) sponsors under part 312 (21 CFR part 312), but are somewhat modified to accommodate unique aspects of clinical and nonclinical sunscreen formulation testing. Because final formulation testing under § 201.327(i) and (j) is intended to verify the claimed properties of a final formulation, and because this purpose is narrower in scope and duration than most clinical testing performed under FDA’s IND regulations in part 312, a responsible person under proposed § 201.327 would have responsibilities that incorporate some of the traditional responsibilities of investigators as well as those of sponsors under part 312. For example, FDA proposes to clarify that responsible persons must select appropriately qualified personnel to conduct testing, ensure compliance with the requirements for IRB review and obtaining informed consent, and monitor the compliance of personnel with investigators’ statements. This proposed approach accounts for situations in which investigators and other personnel conducting final formulation testing are employees of the responsible person. We also propose to clarify that the responsible person must VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 ensure that investigators and other personnel conducting investigations under § 201.327(i) comply with requirements related to human subject protection and the appropriate conduct of clinical testing. We believe that this better reflects the employer/employee relationships that are more common in connection with final formulation testing rather than with clinical testing conducted under an IND. These proposed provisions regarding selection of personnel are also consistent with the existing obligations of manufacturers under parts 210 and 211 (21 CFR parts 210 and 211), both of which govern compliance with CGMPs. The proposed revision of § 201.327(a)(1) permits a responsible person to transfer some or all of its obligations to another entity, consistent with current industry practice, except for obligations with respect to recordkeeping. The recordkeeping proposal is discussed in section IX.D. Failure of an entity to comply with provisions of this part governing responsibilities it has assumed would subject that entity to the same regulatory action as if it were a responsible person who had failed to comply with those obligations. This provision is analogous to the provision in FDA’s regulations at part 312 allowing for transfer of obligations of IND sponsors. c. Adequate clinical testing procedures and conditions. Although current § 201.327 requires ‘‘legally effective written informed consent from all test subjects’’ (§ 201.327(i)(3)(iv)), it does not address broader underlying requirements for conducting clinical testing. In light of the concerns we identified regarding current clinical testing procedures and conditions, we propose to amend § 201.327 by adding paragraph (i)(1), ‘‘Adequate Clinical Testing Procedures and Conditions.’’ We expect that final formulation testing conducted in compliance with the proposals in this paragraph will be more likely to ensure protection of human subjects while also more reliably determining the SPF value and water resistance properties of the final formulations being tested. Unless appropriate clinical testing procedures and conditions are adhered to, FDA cannot have confidence in the resulting labeled SPF and water resistance properties of the product. Proposed § 201.327(i)1(B) and (C) have been added to make clear that FDA’s regulations governing informed consent (part 50 (21 CFR part 50)) and IRB approval of research (part 56 (21 CFR part 56)) apply to clinical final formulation testing that is conducted under § 201.327(i). In our view, as a PO 00000 Frm 00039 Fmt 4701 Sfmt 4702 6241 matter of good clinical practice, IRB approval should already be routinely currently obtained for clinical final formulation testing under current § 201.327 because it is essential to producing results that are scientifically sound and ethically appropriate. Because clinical final formulation testing required to support labeling under current § 201.327 is not conducted under an IND or in support of a GRASE determination in the OTC sunscreen monograph, it was not previously included explicitly in the scope of testing covered by parts 50 and 56. We propose to rectify this omission by explicitly cross-referencing parts 50 and 56 in revised § 201.327(i). This will clarify that both of these parts apply to clinical final formulation testing and will resolve any inconsistency in current practice. The proposed reference to part 50 clarifies FDA’s position that legally effective written informed consent to participate in clinical final formulation testing should share the same properties as informed consent required for all other clinical testing covered by FDA’s regulations in part 50. Similarly, by referencing part 56, the proposal ensures that final formulation testing is held to the same standards for IRB review as other clinical testing covered by FDA’s regulations. In reviewing clinical protocols, IRBs have the ability to determine whether the protocol is adequately designed to study the endpoints sought, and to ensure that protocol elements, such as enrollment criteria, adequately protect both human subjects and the scientific rigor of the experiment. d. Control of personnel. We propose to place responsibility on the responsible person to ensure that investigators and other personnel conducting clinical final formulation testing adhere to the investigational plan, the signed investigator statement, and all applicable regulations. We also propose to place responsibility on the responsible person for ensuring human subjects’ protection, including through appropriately reporting changes in the testing to IRBs, and by appropriately seeking prior IRB approval for any changes to the testing, except where necessary to eliminate apparent immediate hazards to human subjects. Under the proposed rule, responsible persons are also expected to obtain from each investigator, and retain for their records, a signed investigator statement. This is similar to what is required of sponsors of INDs, and it helps to ensure that the investigator is qualified, understands his or her obligations, and will comply with the requirements of E:\FR\FM\26FEP2.SGM 26FEP2 6242 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules this paragraph and with the protocol. It also enables better oversight of clinical investigations by FDA because it creates a record of the investigator’s relevant experience and qualifications. e. Research monitoring. A number of changes in § 201.327(i)(1) are being proposed to ensure adequate monitoring of clinical final formulation testing. Revised § 201.327(i)(1) would require that responsible parties inform all investigators testing a formulation if there are new observations about the drug, particularly with regard to adverse events or safe use. This is necessary to ensure proper communication between study personnel and protection of human subjects. Responsible persons must also monitor the conduct of investigations to ensure that clinical testing is being conducted in accordance with the protocol and with applicable regulations. If a responsible person discovers noncompliance by study personnel, then the responsible person must either secure compliance or remove the noncompliant personnel from conducting testing. Finally, we propose to require that investigators report adverse events and/ or safety concerns to the responsible person, and that investigators also provide responsible persons with final reports at the conclusion of testing. We believe that this will ensure there is appropriate documentation and communication of adverse events and/ or safety concerns that arise during testing. It will also ensure there is a record of SPF testing conducted under § 201.327(i) that can be relied upon should questions related to a particular formulation arise when the sunscreen formulation is marketed. The proposed requirements are consistent with reporting required in the IND context, although, because of the short duration of the clinical final formulation testing conducted under § 201.327(i), we are not proposing to require annual reporting. f. Test subject selection. We propose additional language regarding the selection of test subjects in § 201.327(i)(4). This is an area in which FDA’s inspections of testing entities have suggested a lack of consistency. We are particularly concerned that inclusion/exclusion criteria provide for adequate time between study and enrollment and prior UV exposure, such as from participation in a previous SPF test, sunbathing, or sunlamp use. Erythemal responses can remain for days after sunbathing, and it is known that pigmentation development takes up to a week after initial exposure and remains for weeks to months (Ref. 186). SPF clinical studies should not include VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 individuals who have participated in sunbathing, tanning bed use, or another SPF clinical study for at least the past 4 weeks or perhaps longer if UVinduced responses remain. The proposed clarification regarding conduct of physical examinations of test subjects reflects this consideration, and our additional proposal for IRB review, addressed elsewhere, will help ensure it is appropriately acted on. g. Applicability of registration and CGMP requirements. Proposed § 201.327(k) reflects FDA’s existing view that final formulation testing conducted under § 201.327 constitutes the ‘‘manufacture’’ of a drug. As such, this testing must be conducted in an establishment registered in accordance with part 207 (21 CFR part 207) and section 510 of the FD&C Act. This interpretation is consistent with the definition of manufacture in part 207, which includes ‘‘each step in the manufacture, preparation, propagation, compounding, or processing of a drug . . . .’’ (§ 207.1). The definition of manufacture as used in part 207 also ‘‘includes manipulation, sampling, testing, or control procedures applied to the final product or to any part of the process, including, for example, analytical testing of drugs for another registered establishment’s drug’’ (id). Accordingly, a sunscreen product labeled in reliance on final formulation testing done in an unregistered establishment is misbranded under section 502(o) of the FD&C Act. This interpretation is also consistent with FDA’s regulations in § 330.1, which require that OTC monograph drug products be manufactured in a registered establishment in order to be generally recognized as safe and effective and not misbranded. The incorporation of this provision in § 201.327, therefore, is intended to clarify an existing requirement for facilities performing this type of testing. We also propose to clarify that, as a manufacturing activity, final formulation testing conducted under this paragraph is expected to be done in accordance with CGMPs as set forth in parts 210 and 211 (see § 210.3(b)(12), indicating that for the purposes of parts 210 and 211, ‘‘Manufacture, processing, packing or holding of a drug product includes packaging and labeling operations, testing, and quality control of drug products’’). This is consistent with FDA’s regulations in § 330.1, which require compliance with CGMPs as a condition for OTC drug products to be GRASE and not misbranded when otherwise marketed consistent with conditions in a final monograph. Adherence to CGMP requirements in PO 00000 Frm 00040 Fmt 4701 Sfmt 4702 parts 210 and 211 includes compliance with the requirements to keep certain records and to have appropriately trained and qualified personnel. Failure to comply with CGMPs results in a product being adulterated under section 501(a)(2)(B) of the FD&C Act. h. Recordkeeping. To enable FDA to better monitor compliance with the requirements of § 201.327, we propose to include specific recordkeeping requirements for final formulation testing. Accordingly, proposed § 201.327(l) clarifies what records of testing performed under this section must be kept, by whom, and for how long. This provision also allocates responsibility for records maintenance and specifies what records must be made available to FDA for inspection. Recordkeeping is essential for FDA to evaluate whether required testing of final formulations is being conducted in accordance with § 201.327(i) and (j), and to enable the Agency to investigate postmarketing product failures or adverse events. Appropriate recordkeeping also enables FDA to conduct better and more efficient inspections of entities conducting final formulation testing. These recordkeeping requirements are in alignment with what is required for other types of manufacturing under CGMPs as set forth in parts 210 and 211. The proposed provisions are intended to clarify how, and for how long, records must be kept to substantiate required final formulation testing. We are proposing that records of testing must be kept by the responsible person (as newly defined in § 201.327(a), discussed previously), as well as by any other entity that actually performs testing (under a transfer of obligations per § 201.327(a)(1) or otherwise). Requiring that records be kept by both the responsible person and the testing entity (if different) will enable FDA to more easily identify records supporting the labeling of any given final formulation even when the product is labeled with the responsible person’s information, but testing and manufacturing was completed by a third party. The proposed recordkeeping requirements reflect FDA’s experience in interacting with regulated industry. By requiring that records be kept by both the responsible person and any other entity that performs final formulation testing, the proposed rule will enable more efficient enforcement of the FD&C Act by, for example, allowing FDA to identify the source of formulation failures or apparent inconsistencies between the product labeling and consumer experience. The proposed recordkeeping requirements E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules will also assist FDA when it is conducting inspections of entities that perform final formulation testing for a number of different responsible persons and products, as we believe is the norm in this industry. Having ready access to records reflecting the overall conduct of final formulation testing during an inspection of such an entity is important because it will enable FDA to identify potential systemic problems in final formulation testing that may have an impact on the reliability of results supporting the labeling of multiple different sunscreen products marketed by a variety of responsible persons. We note that these recordkeeping requirements should not be understood to mandate duplicative records within the files of a single testing entity or single responsible party. For example, if one investigator is responsible for testing multiple final formulations, one copy of the signed investigator statement and Curriculum Vitae (CV) would be sufficient to support all formulations tested by that investigator. Consistent with FDA’s view that final formulation testing is manufacturing, and thus is subject to CGMPs, equipment maintenance records and other records documenting compliance with CGMPs are expected to be maintained as required by parts 210 and 211. Accordingly, we clarify in proposed § 201.327(l) that records documenting proper maintenance of equipment used in final formulation testing must be kept, consistent with existing obligations in 21 CFR 211.68. In our view, this clarification will promote uniformity in adherence to best practices and will help ensure more accurate and reliable labeling of sunscreen products based on final formulation testing. Additional specificity has been proposed here to clarify how the more general recordkeeping provisions of part 211 apply to final formulation testing. To provide assurance that the test results are not compromised by faulty equipment maintenance or equipment failure, FDA proposes that testing entities must keep documentation demonstrating that equipment used for final formulation testing has been maintained in accordance with established written specifications. This requirement will enable FDA to more efficiently monitor compliance. Failure to keep required records of final formulation testing will render a product whose labeling relies on that testing adulterated under section 501(a)(2)(B) of the FD&C Act. Without recordkeeping, there is no assurance that a sunscreen drug product has the VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 identity and strength, and meets the quality and purity characteristics, which it purports or is represented to possess. This proposal also elaborates on recordkeeping necessary to document compliance with the requirements of proposed § 201.327 regarding conduct of final formulation testing. Proposed required records for SPF testing include records that: (1) Identify the facility conducting the testing; (2) identify the equipment used; (3) identify product samples and lots; (4) characterize the SPF standard that is used; (5) document parameters for water resistance testing; and (6) demonstrate compliance with the provisions governing adequate clinical testing procedures and conditions. For example, these would include documentation of IRB review, case histories for each human subject (which must document protocol deviations or injuries), administration of the sunscreen, and reading of test results. These proposed recordkeeping obligations are consistent with those required of parties engaged in human subjects testing governed by other portions of FDA’s regulations. Required records of broad spectrum testing conducted under proposed § 201.327(j) would include those records necessary for identifying the facility conducting the testing, providing information associated with the sample, identifying equipment used, and documenting sunscreen product application. These proposed requirements provide greater specificity than existing requirements in FDA’s CGMP regulations, and are expected to increase uniformity in current practice. We propose to clarify FDA’s expectations regarding access to records that responsible persons and other testing entities are required to keep under this paragraph. These provisions are consistent with FDA’s inspection authorities in section 704 of the FD&C Act. i. Minor proposed revisions to test procedures. In addition to the changes discussed in section IX.D, we are proposing several modifications to the technical instructions for sunscreen final formulation testing (§ 201.327(i) and (j)) to clarify how the testing should be conducted. We are concerned that manufacturers conducting the SPF test procedure may be relying on determinations of the initial minimal erythema dose of unprotected skin (MEDu) generated too far in advance of testing the sunscreen product. The current regulation in § 201.327(i)(5) addresses four different determinations of MED for each test subject: (1) An initial MED for PO 00000 Frm 00041 Fmt 4701 Sfmt 4702 6243 unprotected skin (initial MEDu); (2) a final MED for unprotected skin (final MEDu); (3) an MED for skin to which the SPF standard has been applied (ssMEDp); and (4) an MED for skin to which the sunscreen test product has been applied (tpMEDp). The initial MEDu is used to set the UV exposures administered to determine final MEDu, ssMEDp, and tpMEDp (see § 201.327(i)(5)(iii)). Although the regulation already requires that each of the MED values be determined 16 to 24 hours after UV exposure, it merely notes that the final MEDu, ssMEDp, and tpMEDp are ‘‘typically determined the day following determination of the initial MEDu’’ (see current § 201.327(i)(5)(iv)). Because the skin reactivity of a test subject changes over time, we propose to clarify that the initial MEDu of a person’s unprotected skin must be determined no more than 1 day before the UV exposures for final MEDu, ssMEDp, and tpMEDp are administered. We are also clarifying that to calculate the SPF value for each test subject, under proposed paragraph § 201.327(i)(6), it is the subject’s final MEDu that should be used. In our review of the testing requirements as part of this rulemaking, we also revisited our position on the input slit bandwidth specification in the in vitro broad spectrum test. In the 2011 L&E Final Rule, we modified the in vitro broad spectrum test that was proposed in the 2007 proposed rule to change the input slit spectrometer bandwidth specification from ≤5 nm to ≤1 nm. After the 2011 final rule published, FDA received a comment from a spectrometer manufacturer arguing that the 1 nm input slit bandwidth specification was unreasonable. The manufacturer argued that common spectrometer models that are currently used to test sunscreens cannot comply with the ≤1 nm input slit bandwidth specification, and those that can are more expensive, more difficult to use, and take more time to use. The manufacturer provided data that indicate that spectrometers with ≤1 nm input slit bandwidths do not produce more reliable results than spectrometers with larger input slit bandwidths (see Comment, Docket No. FDA–2010–D– 0509–0004). In light of this submission, FDA reassessed the input slit bandwidth parameters and concluded that ≤5 nm will be sufficient for the broad spectrum procedure. Although decreasing bandwidth improves the ability to resolve closely spaced peaks (i.e., the spectral resolution), this is not a significant consideration for in vitro broad spectrum testing of sunscreen products because transmittance/ absorbance curves for sunscreen E:\FR\FM\26FEP2.SGM 26FEP2 6244 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules products are typically smooth with no individual sharp peaks. Accordingly, we propose to revise § 201.327(j)(1)(iv) to require that spectrometer input slits be set to provide a bandwidth that is ≤5 nm. Establishing standardized testing procedures for sunscreen products and basing the products’ labeling on this testing not only helps assure the safety and effectiveness of each product, it also provides consumers with consistent information about the sun protection properties of sunscreen products across brands, which in turn facilitates consumer comparisons when selecting products. Accordingly, we propose to delete the provision in § 352.77 (21 CFR 352.77) addressing test modifications or alternative testing procedures. Section 352.77 indicates that such test modifications or alternative testing procedures require submission of a petition in accordance with § 10.30 (21 CFR 10.30). The proposed removal of § 352.77 does not alter the existing ability of a firm or individual to petition the Agency to amend the monograph (see §§ 330.10(a)(12) and 10.30) to change the conditions that apply to products marketed under its provisions, such as to modify testing procedures for all products having some particular set of characteristics. Rather, the proposed deletion will clarify that the sunscreen monograph does not permit variation for individual products from the standardized testing procedures that are monograph conditions, because such variation could undermine important values supported by standardization. We are also proposing to correct a minor inaccuracy in the existing regulatory language describing testing procedures. Specifically, § 201.327(i)(1)(ii)(C) currently states that ‘‘emission spectrum must be determined using a handheld radiometer.’’ As written, this statement is inaccurate because a handheld radiometer cannot determine the emission spectrum of a solar simulator. We propose to resolve this error by clarifying that the handheld radiometer measures the solar simulator radiation intensity rather than the emission spectrum. Finally, we have proposed edits to certain provisions describing final formulation testing procedures to clarify our long-standing intention that these provisions of the test are requirements, not merely suggestions. E. Proposed Status of Sunscreen-Insect Repellent Combination Products 1. Background Sunscreen-insect repellent combination drugs are products used on human skin that contain both a sunscreen drug component and an insect repellent component. A list of insect repellent products on the EPA website identified a number of such products as of November 2017 (including multiple products within a single brand line).47 Among those products, the majority contained either N,N-Diethyl-meta-toluamide (also called DEET) or IR3535 as the insect repellant, and a few contained oil of citronella as the insect repellent. Combination insect repellent-sunscreen products have been marketed in a variety of dosage forms (see section IX.A for a discussion of dosage forms), with labeled SPF levels ranging from 15 to 30 (Ref. 187). Some products are also labeled as water resistant or very water resistant (Ref. 187). The products are generally labeled for use without regard to age (Ref. 187). FDA regulates sunscreens as drug products under the FD&C Act, and EPA concurrently regulates insect repellents as pesticides under FIFRA.48 FIFRA defines a ‘‘pesticide’’ in relevant part as ‘‘any substance . . . intended for repelling . . . any pest,’’ including insects (7 U.S.C. 136)(u)). Before they can be marketed, most skin-applied insect repellents must be registered by EPA, although a few plant-derived insect repellent active ingredients are exempt from registration because EPA has determined they present minimum risk potential to humans (Ref. 189). Sunscreen-insect repellent combination products have been marketed in the United States since before the OTC review began, but they have not previously been addressed in the rulemaking for the OTC sunscreen monograph (72 FR 7941 at 7943). Both FDA and EPA have historically declined to object to the marketing of these products pending the issuance of a final sunscreen monograph, provided that the sunscreen active ingredient(s) is listed in the stayed final monograph and the insect repellent component is registered with the EPA (79 FR 7941 at 7943). In 2011, FDA issued a draft enforcement guidance intended for manufacturers who market OTC sunscreen products without an approved application, which recommended that manufacturers of sunscreen-insect repellent combination products should comply as closely as possible with FDA’s sunscreen testing and labeling requirements in § 201.327. This guidance was finalized in May 2018 (Ref. 1). In the Federal Register of February 22, 2007 (72 FR 7941), FDA issued a notice seeking public comments on sunscreen-insect repellent combination products, and, in particular, whether FDA should amend the OTC sunscreen monograph to add conditions for marketing insect repellent-sunscreen drug products (FDA Call for Data or call for data). The call for data summarized the regulatory status and history of both sunscreens and insect repellents, and sought public input on a number of issues (see table 6). On that same date (February 22, 2007, 79 FR 7979), EPA published a similar notice announcing that it was also seeking information to determine how insect repellentsunscreen combination products should be regulated. TABLE 6—KEY ISSUES AND INFORMATION REQUESTS IN FDA’S 2007 CALL FOR DATA General issue Key concerns and information requests Possible manufacturing conflicts ............. Possible formulation conflicts .................. Requested information about whether there are known conflicts between FDA and EPA manufacturing requirements and, if so, how to resolve them. Asked how FDA should address EPA-registered insect repellents in finalizing the OTC sunscreen monograph; which requirements should FDA retain, revise, or eliminate? Inquired about manufacturer testing of sunscreen-insect repellent combination products and whether any problems were encountered. Requested comments on the significance of published research suggesting a potential formulation conflict. 47 EPA Product List (Ref. 187); a similar list of insecticide products on the National Pesticide Information Center (NPIC) website produced similar results (Ref. 188). 48 Some insect repellents are also regulated by FDA as human drugs (e.g., pediculicides and VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 scabicides intended to control parasites on humans) or animal drugs (e.g., pesticide products for oral administration to animals) (7 U.S.C. 136 et seq.); see also ‘‘MOU 225–73–8010 Memorandum of Understanding Between the Environmental Protection Agency and the United States PO 00000 Frm 00042 Fmt 4701 Sfmt 4702 Department of Health, Education and Welfare Food and Drug Administration,’’ (available at https:// www.fda.gov/aboutfda/partnershipscollaborations/ memorandaofunderstandingmous/domesticmous/ ucm115873.htm (accessed April 17, 2018). E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules 6245 TABLE 6—KEY ISSUES AND INFORMATION REQUESTS IN FDA’S 2007 CALL FOR DATA—Continued General issue Key concerns and information requests Possible labeling conflicts between OTC sunscreen monograph and EPA registration requirements. Note: Since publication of the call for data, FDA has established additional labeling regulations for certain OTC sunscreen products marketed without approved applications. However, the labeling concerns expressed in the call for data remain relevant. Labeling differences noted: • FDA uses ‘‘warning’’; EPA uses ‘‘caution’’ (and only uses the word ‘‘warning’’ to indicate toxicity levels). • Many differences in required warning/caution section headings. • Directions for sunscreen use call for liberal application and frequent reapplication; EPA directions may limit where and how to apply product and restrict frequency of application. Asked whether different directions for use can be integrated without leading to improper application, overexposure to insect repellent, and/or underexposure to sunscreen. FDA requires the outside container or wrapper of the retail package or the immediate container label to list all active and inactive ingredients (see section 502(e)(1)(A)(iii) of the FD&C Act; § 201.66(c)). EPA requires listing of the percentage of each active ingredient, and the total percentage of all ‘‘inert’’ or ‘‘other’’ ingredients, in the pesticide. Inert ingredients are not required to be identified individually on the product except in certain cases (in which case all inert ingredients are listed). Asked whether there is a way to label combination sunscreen-insect repellent drug products in a way that satisfies both the requirements of the FD&C Act and the FIFRA, and whether ‘‘inert’’ ingredients under the FIFRA are equivalent to ‘‘inactive’’ ingredients under the FD&C Act. More safety data needed given published animal studies indicating increased absorption of DEET and various sunscreens active ingredients when the components are combined. Asked for more safety data on combined products. Requested data on whether increased absorption of a sunscreen ingredient occurs when combined with an insect repellent. Information needed about incidence of skin irritation from combination products. Requested information on: • Possible effects of insect repellent on sunscreen SPF; possible decreased sunscreen efficacy or increased exposure to insect repellent without greater efficacy resulting from inconsistent reapplication intervals. • Potential chemical or physical incompatibilities between particular sunscreens and insect repellents. • Potential need to specify minimum SPF for these combinations. • Any potential performance benefits of these combination products other than convenience. • Possible adjustments to formulations to minimize application time disparities. Safety issues ........................................... Effectiveness issues ................................ 2. FDA’s Evaluation of Sunscreen-Insect Repellent Combination Products FDA has reviewed the comments submitted in response to FDA’s and EPA’s calls for data, as well as pertinent scientific literature and publicly available EPA regulatory documents. Based on that review, we have tentatively concluded that sunscreeninsect repellent combination products, as a class, are not GRASE (i.e., are Category II) and are misbranded because conflicting labeling requirements for their sunscreen and insect repellent components cannot be reconciled to create labeling that will sufficiently ensure safe and effective use of the sunscreen component, as well as adequate directions for use as a sunscreen, as required by section 502(f) of the FD&C Act. Also, if we did not have this labeling concern, we would still tentatively determine that available data regarding the safety and effectiveness of these products for their use as sunscreens are insufficient to classify these sunscreen products as GRASE for such use (i.e., Category III). Specifically, evidence suggests that interactions between some sunscreen active ingredients and insect repellents may decrease safety by increasing systemic absorption of one or both components, and potential synergistic effects on the efficacy of sunscreen active ingredients apparently have not been studied. Although the available data are limited and not conclusive, they give rise to questions about the safety and effectiveness of these products. Our reasons for these tentative VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 conclusions are detailed in the discussion that follows. a. Public comments on the 2007 call for data. FDA received six submissions in response to the 2007 call for data. None of the comments included substantive data, although some cited published scientific and medical literature, which is addressed in the following section of this document. Five of the six comments were from manufacturers or a trade association. Industry comments generally favored retaining joint regulation between EPA and FDA (perhaps with enhanced coordination and information-sharing) and amending the stayed OTC sunscreen monograph to address sunscreen-insect repellent combinations. Several industry comments claimed there was an absence of conflicting requirements relating to manufacturing, formulation, and/or labeling. Others suggested approaches for minimizing labeling conflicts, such as permitting exemptions to FDA’s Drug Facts labeling requirements to accommodate EPA-required information, or placing FDA- and EPArequired information in separate areas of the label. The remaining comment was submitted by a medical association that opposed continued marketing of sunscreen-insect repellent products, emphasizing concerns about children’s exposure to DEET. Industry comments favoring the continued marketing of combination sunscreen-insect repellent drug products also contended that combining sunscreen and insect repellent ingredients in a single product is more convenient and cost-effective PO 00000 Frm 00043 Fmt 4701 Sfmt 4702 than using separate products. Two comments stated that properly formulated, tested, and labeled, combination products are better than the unpredictable effects that could arise when consumers use two different products. Regarding safety, one comment asserted various flaws in the studies cited in the call for data that questioned the safety of these combination products. (These studies are discussed in section IX.E.2.d.) In general, the comments that we received in response to the 2007 call for data were not accompanied or corroborated by data. Although the comments did not identify further concerns relating to product manufacturing or formulation, they did not adequately address FDA’s concerns about safety, effectiveness, and labeling of these products. FDA renews its request for data to support labeling and safety for sunscreens with insect repellent added. b. Pesticide-related information. Pesticides that are or have been used in combination products that also contain sunscreens include DEET, IR3535, and oil of citronella. In evaluating combination insect repellent-sunscreen products for the purposes of this rule, FDA defers to EPA’s expertise and authority regarding insect repellent ingredients. We have not independently evaluated these pesticides, but instead have focused on potential sunscreeninsect repellent ingredient interactions and the feasibility of effectively labeling these combination products for their use as sunscreens. E:\FR\FM\26FEP2.SGM 26FEP2 6246 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules As of June 2017, DEET was by far the most commonly used insect repellent. According to the EPA Product list, the amount of DEET in combination sunscreen-insect repellent products ranged from 10 to 20 percent. DEET product labels recommend that users avoid over-application, use just enough repellent to cover exposed skin and/or clothing, and not apply to hands or near the eyes or mouth of young children (Ref. 190). DEET-containing products listed on the EPA website in 2017 had concentrations ranging from 5 percent to 98 percent and provided protection from mosquitos for 2 to 12 hours, with many products having protection times of 4 hours or more (Ref. 187). The American Academy of Pediatrics recommends that repellents should contain no more than 30 percent DEET when used on children, and that insect repellent should not be used on children younger than 2 months (Ref. 191). EPA classifies the acute toxicity of insect repellents and other pesticides into one of four toxicity categories (ranging from Category I, highly toxic, to Category IV, practically nontoxic) (see 40 FR 156.62). DEET is classified in Category III based on EPA’s review of available animal studies, indicating slight acute toxicity for acute oral, dermal, ocular, and inhalation tests in animals, and low acute toxicity for the human health risk assessment (Ref. 192). Although DEET is registered for use in humans of any age, adverse events related to DEET toxicity have been documented and these events primarily relate to the central nervous system. As summarized by Katz et al., DEET has been associated with seizures and other central nervous system symptoms, cardiovascular symptoms, and topical and allergic symptoms (Ref. 193). Most reported cases of adverse or lethal events involved overuse or otherwise incorrect use of the product (Ref. 193), and EPA concluded that available data were insufficient to identify DEET as the cause of the reported adverse events (Ref. 192). EPA is currently in the process of updating its registration of a number of older pesticides, including DEET, and is deferring decision on the regulatory status of combination DEET/sunscreen products as described in the EPA Call for Data.49 However, EPA has stated that 49 DEET 2014 reregistration interim review final decision (EPA–HQ–OPP–2012–0162) (available at https://www3.epa.gov/pesticides/chem_search/reg_ actions/reregistration/red_PC-080301_1-Apr-98.pdf (accessed April 17, 2018). VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 DEET does not pose a significant health risk to the U.S. population.50 IR3535 is classified by EPA as a biopesticide because it is biochemically, functionally identical to beta-alanine, a naturally occurring substance that repels insects (Ref. 194). IR3535 is classified in Toxicity Category IV (practically nontoxic) for acute oral, dermal, and inhalation toxicity and Category III (slightly toxic) for eye irritation (Ref. 195). Overall, EPA has assessed IR3535 as not harmful when ingested, inhaled, or used on skin (Ref. 195). Eye irritation could occur if the chemical enters a person’s eyes (Ref. 195). IR3535 is used at concentrations of 7.5 percent to 20 percent in a popular line of sunscreen-insect repellent combination products (EPA Product List) (Ref. 187). Products containing IR3535 identified on EPA’s website in summer 2017 had concentrations ranging from 7.5 percent to approximately 20 percent and listed protection time against mosquitoes of 2 to 8 hours (EPA Product List) (Ref. 187). Oil of citronella is a plant-derived biochemical insect repellent (72 FR 7979 at 7981). Depending on its source, it may be categorized as ‘‘Ceylon’’ type or ‘‘Java’’ type. It is currently listed by EPA as a minimum risk pesticide (registration generally not required if formulated only with EPA-permitted inert ingredients and not labeled as effective against disease-causing pests) (40 FR 152.25(f)). Oil of citronella is also an approved food additive for use as a flavoring agent in foods and beverages (Ref. 196). EPA has designated oil of citronella as Toxicity Category III (slightly toxic) for acute oral toxicity (Java type only), dermal toxicity, dermal irritation, and acute eye irritation (both types), and Category IV (practically nontoxic) for acute oral toxicity (Ceylon type) and acute inhalation (Ref. 197). The National Pesticide Information Center (NPIC) fact sheet on oil of citronella states that oil of citronella products should not be used on children less than 6 months old (Ref. 198). c. Disparities in required labeling of sunscreens and insect repellents. FDA and EPA regulate the format and content of the labeling of nonprescription sunscreen products and pesticides, respectively. FDA regulations on nonprescription sunscreen labeling include the general drug labeling 50 Id. In June 2014, EPA issued an interim review of DEET and did not identify any specific new concerns. The proposed interim registration review decision became final on September 24, 2014. DEET 2014 reregistration interim review final decision (EPA–HQ–OPP–2012–0162) (available at https:// www.regulations.gov/document?D=EPA-HQ-OPP2012-0162-0012 (accessed April 17, 2018). PO 00000 Frm 00044 Fmt 4701 Sfmt 4702 regulations in subpart A of part 201; the ‘‘Drug Facts’’ format and other OTC drug labeling requirements in subpart B of part 201; and the sunscreen-specific labeling requirements that apply to sunscreens marketed without an approved NDA, including those based on the current requirements for SPF and broad spectrum testing in § 201.327. The labeling of registered insect repellents is subject to EPA labeling requirements under FIFRA (40 CFR 156), as well as specific language specified in individual product registration documents. Although the FDA and EPA labeling requirements for nonprescription sunscreens and registered pesticides cover some of the same information (such as ingredient lists, net quantity statements, and warnings/precautions), there is considerable variation in the language, format, and placement of common label elements between the two Agencies, while other elements do not overlap. Furthermore, both Agencies limit the degree to which a drug manufacturer or pesticide registrant may depart from the prescribed text, format, and/or location of required labeling elements. This is particularly true for the wording and format of ‘‘drug facts’’ information for OTC drugs (see § 201.66). Similarly, EPA regulations state that although a registrant may choose to place nonFIFRA-required information on a pesticide label, it may not replace, obscure, conflict with, or supersede the FIFRA-required text (Ref. 199). The intended uses of sunscreens and insect repellents are quite different, as are the associated labeling requirements; in particular, the instructions for using the two types of products are different. Required labeling for OTC sunscreens marketed without approved NDAs calls for reapplication at least every 2 hours (see § 201.327(e)(3) through (e)(4)). The duration of protection for insect repellents varies according to the active ingredient and strength. Based on information from the EPA product list, many insect repellent-sunscreen products provide protection against mosquitoes and/or ticks for more than 2 hours, and some provide protection for as many as 6 to 10 hours. EPA has stated that it is ‘‘concerned about consumer use of products that contain sunscreens and DEET, since directions to reapply generally and frequently may promote greater use of DEET than needed for pesticidal efficacy and thus pose unnecessary exposure to DEET.51 The Centers for Disease Control and Prevention (CDC) advises consumers 51 DEET 2014 reregistration interim review final decision, supra note 49, v. E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules that ‘‘products that combine sunscreen and repellent are not recommended, because sunscreen may need to be reapplied more often and in larger amounts than needed for the repellent component to provide protection from biting insects.’’ (Ref. 200). Similarly, the American Academy of Pediatrics advises consumers not to use products that combine DEET with sunscreen, in part because ‘‘[t]hese products can overexpose your child to DEET because the sunscreen needs to be reapplied often’’ (Ref. 201). Additionally, DEET is approved for use on children with no age restriction (Ref. 202), whereas FDA labeling states ‘‘[bullet] children under 6 months of age, ask a doctor’’ (see § 201.327(e)(1)(iv)). The recommended manner of application also differs for sunscreens and insect repellents. For example, the directions on the label for all insect repellent products containing DEET say to apply just enough to cover exposed skin, and avoid over-application (Ref. 190), whereas the labeling of nonprescription sunscreens marketed without approved NDAs calls for liberal or generous application (see § 201.327(e)(1)(ii)). The EPA-mandated directions on the labels of DEET products also state, ‘‘Do not apply near eyes and mouth; apply sparingly around ears; do not use under clothing’’ (Ref. 190). Such statements are potentially troublesome from the standpoint of sun protection in light of surveillance data from Australia, which suggest that the incidence of certain skin cancers is more frequent on highly exposed areas of the body such as ears and the backs of hands (Refs. 203 and 204). The CDC advises consumers who need protection from both sun and insects to apply sunscreen product first, followed by an insect repellent (Ref. 200). Additional disparities in the content and format of labeling elements for sunscreens and registered insect repellents include the following: • EPA pesticide labeling includes required elements that generally must appear on the front panel of the label, such as the ingredient statement (40 CFR 156.10(g)(2)), specified signal word such as ‘‘CAUTION’’ (40 CFR 156.64), and child hazard warning (40 CFR 156.66), which could crowd or detract from drug information required to appear on the principal display panel for drugs (see § 201.60 (‘‘The principal display panel shall be large enough to accommodate all the mandatory label information required to be placed thereon by this part.’’)). Other labeling elements that only EPA requires include registration numbers and manufacturing VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 establishment numbers (40 CFR 156.10(a)). • FDA labeling for sunscreens uses the word ‘‘warning’’ (see §§ 201.66(c)(5) and 201.327(d)), while the EPA requirements specify that pesticide products that, like DEET, IR3535, and oil of citronella, meet the criteria of Toxicity Category III or IV as the highest category by any route of exposure bear on the front panel either no signal word or only the signal word ‘‘CAUTION’’ (40 CFR 156.64). In EPA labeling the word ‘‘WARNING’’ is used as a signal word only for toxicity category II, which is a higher toxicity category than that applicable to any insect repellent ingredients used in sunscreen-insect repellent combination products (40 CFR 156.64(a)(2)). • FDA labeling uses the term ‘‘directions’’ (see §§ 201.66(c)(6) and 201.327(e)), while EPA regulations use the term ‘‘directions for use’’ (see 40 CFR 156.10(i)(2)). • FDA calls for ingredients to be listed as ‘‘active’’ and ‘‘inactive’’ (see § 201.66(b) through (c)), while EPA labeling uses the term ‘‘inert’’ or ‘‘other’’ instead of ‘‘inactive’’ for all nonpesticide ingredients (40 CFR 156.10(g)). Given the extent of the disparities discussed above, FDA tentatively concludes that attempting to merge the required labeling for monograph sunscreens and insect repellents in a way that would comply with both Agencies’ requirements and permit adequate consumer understanding and proper use would be impracticable. In this regard, we specifically disagree with comments made in response to the 2007 FDA Call for Data suggesting that acceptable ‘‘merged’’ labeling could be crafted by varying the OTC sunscreen drug facts to include insect-repellentrelated information, and/or by providing EPA-required labeling outside the drug facts box. We are particularly concerned that consumers would be confused by the juxtaposition of two sets of different and, in some cases, contradictory information in the labeling about these products’ dual intended uses. We are also concerned that the sheer amount of required information would result in crowded, difficult-to-read labels lacking in the clarity and prominence of important safety and use information that are both required by FDA regulations and vital to consumer comprehension. We solicit comment and data about how to reconcile the labeling of suncreens and insect repellents such that a combined product could meet FD&C Act requirements for OTC sunscreen drugs. d. FDA’s review of published medical literature. The results of FDA’s literature PO 00000 Frm 00045 Fmt 4701 Sfmt 4702 6247 review raise potential safety concerns about products that combine sunscreen and insect repellent active ingredients. The available data suggest that the dermal penetration and systemic absorption of at least one combination of a sunscreen active ingredient and an insect repellent is increased when both are present. There have been some studies assessing the penetration of DEET and the effects of DEET combined with sunscreen (particularly the active ingredient oxybenzone) on dermal penetration. Ross et al. tested for synergistic effects between DEET and oxybenzone using an in vitro mouse skin diffusion model and showed substantial penetration of a 20 percent DEET standard in ethanol, while penetration of sunscreen active ingredients was not found (Ref. 205). Despite a lower DEET content (10 percent), a commercially marketed sunscreen formulation had a 6-fold more rapid detection and a 3- to 4-fold greater penetration of DEET than the 20 percent standard. Other diffusion tests using pigskin or artificial membranes and various combinations of DEET and oxybenzone in different media suggested an enhancing effect on dermal penetration of both DEET and oxybenzone (Refs. 206 and 207). The same investigators obtained similar results in a later in vitro study using human skin (Ref. 207). Kasichayanula et al. assessed the dermal absorption of DEET and oxybenzone using an in vivo piglet model, in which samples were collected from plasma, urine, and under the skin. Their results indicated that the enhanced dermal penetration evidenced in the in vitro studies translated to increased systemic exposure to both oxybenzone and DEET (Refs. 208 and 209). Finally, a study by Yiin et al. suggests that enhanced systemic absorption would also occur in humans (Ref. 210). Yiin et al. used human urinary metabolites of DEET and oxybenzone to evaluate the mutual enhancing effect on absorption of these ingredients and concluded that their findings confirm that concurrent use of DEET-containing insect repellent and oxybenzone-containing sunscreen results in the enhancement of dermal absorption of DEET when insect repellent (DEET) was applied first and then covered by sunscreen (Ref. 210). The study authors suggested that placing repellent spray on top of sunscreen lotion with no mixing seems to be the best approach to diminish DEET penetration through the skin. Although insect repellents and sunscreens are designed to exert their E:\FR\FM\26FEP2.SGM 26FEP2 6248 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules protective effects on the surface of the skin, the studies described above suggest that combining a sunscreen and insect repellent in a single product may result in unintended systemic exposure to the sunscreen ingredient oxybenzone and the insect repellent ingredient DEET. We acknowledge the study limitations cited by comments to the FDA Call for Data, and that in vitro diffusion studies have their limitations in terms of reflecting clinical use. We also note that many of the studies tested formulated commercial products with multiple sunscreen ingredients and excipients for which details were not given, and it is unclear how this may have influenced the results. Although we, therefore, do not view these data as conclusory, we have determined that they raise a valid safety concern that warrants a tentative conclusion that, even if one could overcome the misbranding and associated safety and effectiveness concerns created by the inconsistent application directions for sunscreens and insect repellants, there would not be sufficient evidence to conclude that combination sunscreen and insect repellent products are GRASE for sunscreen use without further investigation. Regarding future investigations that could assist FDA in determining whether these products have sufficient evidence of safety to be GRASE for use as sunscreen, we are not aware of any data that define the extent of systemic exposure to either DEET or oxybenzone that would occur with maximal exposure to a sunscreen-insect repellent combination product. There also are few data from which to assess whether there would be a similar enhancement of skin penetration for other combinations of sunscreen and insect repellent active ingredients. Moreover, without adequate human absorption studies under maximal use conditions of particular sunscreen-insect repellent combinations (i.e., a MUsT, as discussed in section VII.B.4), it is difficult to evaluate potential risks associated with the use of such combination products. Because of the potential synergistic interaction between the sunscreen active ingredient and the insect repellent active ingredient, human absorption data for the individual components would not provide adequate data to estimate the level of systemic absorption. Likewise, in vitro data would not be able to provide a reliable estimate of the systemic exposure that would occur with such products’ use. In terms of sunscreen active ingredient effectiveness, we have little data from which to determine whether the presence of an insect repellent VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 would affect the determined SPF value of combination sunscreen-insect repellent products. Montemarano et al. reported a reduction in sunscreen efficacy because of concomitant use with insect repellent. However, in that study, the sunscreen and insect repellent ingredients were applied separately and were not part of a combination product (Ref. 211). With respect to efficacy, we recognize that the testing required by § 201.327 (both the current regulation and the regulation if amended as proposed elsewhere in this proposed rule) to support labeled SPF levels and other efficacy claims that may be made for certain OTC sunscreen products could potentially mitigate concerns about the impact of insect repellent active ingredients on sunscreen effectiveness. However, we are not aware of any data evaluating the reliability of SPF testing for sunscreen formulations that contain insect repellent ingredients. There also is the possibility that increasing the amount of the sunscreen active ingredient to compensate for any loss in efficacy because of the presence of the insect repellent could result in unnecessarily high exposure to the sunscreen active ingredient. For these additional reasons, we tentatively conclude that even if other concerns could be overcome, there is not currently sufficient evidence to conclude that combination sunscreeninsect repellent products are GRASE for use as sunscreens. We solicit comment on the data needs identified above and tentative conclusions, including supporting data and analysis. We also solicit data and information to address these data needs. 3. Conclusion FDA tentatively concludes that the inherent disparity in labeling requirements that apply to sunscreens marketed under the OTC monograph and insect repellents prevent the creation of labeling that will sufficiently ensure safe and effective use of the sunscreen component of sunscreeninsect repellent combination products, particularly in connection with duration of action. We also conclude that these conflicting requirements prevent these products from having adequate directions for use as a sunscreen, and thus these products would be misbranded under section 502(f) of the FD&C Act. In addition, even if these issues could be overcome, existing safety concerns about potential enhanced systemic absorption resulting from combining individual sunscreen active ingredients and insect repellent ingredients would also need to be PO 00000 Frm 00046 Fmt 4701 Sfmt 4702 addressed by further studies on both combinations of individual sunscreen and insect repellent ingredients and final formulations. Existing data indicates there is a risk of systemic absorption of insect repellent and/or a sunscreen active ingredient when both are present. Additional data would be needed to identify any interactions between specific sunscreen active ingredients and insect repellents, in particular, to characterize any enhancement of skin penetration and/or systemic absorption if the resulting data presents safety or effectiveness concerns. As stated above, FDA would need adequate human absorption studies, such as a MUsT, as part of the clinical safety assessment (for more discussion on assessment of dermal absorption of sunscreen active ingredients using MUsT, see section VII.B.4). The effectiveness of sunscreeninsect repellent combination products is also a continuing concern. For all of those reasons, we tentatively determine that these products are not GRASE for nonprescription sunscreen use. We solicit comment on this tentative determination. X. Proposed Actions To Effectuate Lifting of Stay and Harmonize Impacted Regulations In the 2011 L&E Final Rule, FDA explained that although we were not yet lifting the stay on the 1999 final monograph, the provisions set forth in the L&E Final Rule reflected the Agency’s position on the appropriate testing and labeling of sunscreen products that were previously identified as falling within the Stayed 1999 Final Monograph (76 FR 35620 at 35621). We explained that § 201.327 would therefore supersede the prior approach to labeling and effectiveness testing described in the never-effective provisions of part 352, subparts C and D. We are now proposing to lift the stay on the 1999 final monograph (21 CFR part 352) while making certain changes in its provisions. To fully effectuate this proposal, we are proposing several harmonizing revisions to part 352 and § 201.327. These changes remove certain provisions from part 352 that were superseded by the 2011 L&E Final Rule and, where applicable, replace them with appropriate cross references to the applicable testing and labeling provisions in § 201.327, as we propose to amend these regulations in this document. We also have made minor revisions in parts 347, 352 and § 201.327 to improve readability and to correct certain typographical errors and erroneous internal cross references. E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules We are also proposing revisions to certain provisions describing requirements for products containing both sunscreen active ingredients and skin protectant active ingredients to avoid duplication between § 201.327 and part 352 and to harmonize the requirements set forth in those provisions. As in the past, the proposed sunscreen monograph would include conditions under which a single product could include certain sunscreen active ingredients as well as certain ingredients determined to be GRASE for use in skin protectants under part 347 (see proposed § 352.20(b), as well as current § 347.20(e) (21 CFR 347.20(e)). Current § 201.327(h) allows for such products to combine certain labeling statements applicable to each ingredient in the product to eliminate duplicative words or phrases. The stayed provisions of part 352 contain similar allowances for products that contain both sunscreen and skin protectant active ingredients, but also outline more detailed requirements for presenting such a product’s statement of identity, indications, warnings, and directions. We propose to relocate the labeling requirements for such products from § 352.60 to § 201.327(h), thereby consolidating labeling conditions for these products in one section of the regulations. We also propose to retain compliance with these labeling provisions as a monograph condition for sunscreen/skin protectant products under both parts 352 (the sunscreen monograph) and 347 (the skin protectant monograph) by incorporating cross references to § 201.327(h) in § 352.20(b)(4), and § 352.60, and incorporating cross references to §§ 352.20 and 352.60 in §§ 347.20(e), and 347.60. Additionally, we propose to consolidate under new § 310.549 (21 CFR 310.549) certain properties that render an OTC drug product offered for use as sunscreen a new drug for which an approved NDA is required prior to marketing. Section 310.545 (21 CFR 310.545) currently contains several such provisions addressing specific ingredients and efficacy claims. We propose to relocate these provisions from § 310.545 to § 310.549. In addition, in the interest of completeness, we are clarifying in § 310.549 that labeling a product with claims that it decreases the risk of skin cancer or early skin aging caused by the sun if that product has an SPF of less than 15 when tested in accordance with § 201.327(i) and/or does not pass the broad spectrum test in § 201.327(j) renders the product a new drug. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 Finally, we propose to add to § 310.549 new characteristics that would render a product a new drug. These characteristics include: (1) Containing the ingredients we propose to classify as categories II and III (see sections VIII.B–C); (2) being labeled, represented, or promoted for use as a combined sunscreen-insect repellant (see section IX.E); (3) failing to comply with provisions relating to maximum SPF values and broad spectrum requirements (see section IX.B); and (4) failing to conform to certain other sunscreen formulation and dosage form conditions (see sections IX.A and D). XI. Comment Period We are providing a comment period of 90 days (see DATES). FDA will also consider requests to defer further rulemaking with respect to a specific sunscreen active ingredient to allow the submission of new safety and/or effectiveness data to the record if such requests are submitted to the docket within the initial 90-day comment period. FDA will review all data and information submitted to the record in conjunction with all timely and complete requests to extend. In assessing whether to extend the comment period to allow for additional time for studies to generate new data and information, FDA will consider the data already in the docket along with any information that is provided in any requests to extend. FDA will determine whether the sum of the data, if timely submitted, is likely to be adequate to provide all the data that are necessary to make a determination of general recognition of safety and effectiveness. XII. Proposed Effective/Compliance Dates The proposed effective date of final regulations resulting from the proposals described in this rulemaking is November 26, 2019 (see FD&C Act section 586E). We recognize that industry will need time after publication of any final regulations to comply with their provisions. To allow for orderly implementation of final regulations and help assure continued product availability to consumers, we would not expect full compliance with such final regulations for units of sunscreen product initially introduced or initially delivered for introduction into interstate commerce, until 1 year after the effective date of the final rule. We also would not expect full compliance, even after that date, for units of product that were initially introduced or initially delivered for introduction into interstate commerce before that date, such as those PO 00000 Frm 00047 Fmt 4701 Sfmt 4702 6249 remaining in retail outlets. Our current thinking on implementation is informed in part by our understanding there are no currently marketed sunscreen products that contain the active ingredients we propose here as Category II. We solicit comment on this proposed approach. XIII. Preliminary Economic Analysis of Impacts A. Introduction We have examined the impacts of the proposed rule under Executive Order 12866, Executive Order 13563, Executive Order 13771, the Regulatory Flexibility Act (5 U.S.C. 601–612), and the Unfunded Mandates Reform Act of 1995 (Pub. L. 104–4). Executive Orders 12866 and 13563 direct us to assess all costs and benefits of available regulatory alternatives and, when regulation is necessary, to select regulatory approaches that maximize net benefits (including potential economic, environmental, public health and safety, and other advantages; distributive impacts; and equity). Executive Order 13771 requires that the costs associated with significant new regulations ‘‘shall, to the extent permitted by law, be offset by the elimination of existing costs associated with at least two prior regulations.’’ We believe that this proposed rule is a significant regulatory action as defined by Executive Order 12866. The Regulatory Flexibility Act requires us to analyze regulatory options that would minimize any significant impact of a rule on small entities. Because many sunscreen manufacturers are small entities and the one-time costs of the proposed rule represent a significant fraction of annual revenue to sunscreen manufacturers, we find that the proposed rule will have a significant economic impact on a substantial number of small entities. The Unfunded Mandates Reform Act of 1995 (section 202(a)) requires us to prepare a written statement, which includes an assessment of anticipated costs and benefits, before proposing ‘‘any rule that includes any Federal mandate that may result in the expenditure by State, local, and tribal governments, in the aggregate, or by the private sector, of $100,000,000 or more (adjusted annually for inflation) in any one year.’’ The current threshold after adjustment for inflation is $150 million, using the most current (2017) Implicit Price Deflator for the Gross Domestic Product. This proposed rule would result in an expenditure in any year that meets or exceeds this amount. E:\FR\FM\26FEP2.SGM 26FEP2 6250 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules We have developed a comprehensive preliminary regulatory impact analysis that assesses the impacts of the proposed rule. We present a summary of this analysis below. B. Summary of Costs and Benefits If finalized, the proposed rule would update and make effective regulations to ensure the safety and effectiveness of sunscreen products marketed under the OTC drug monograph. The rule would update sunscreen product labeling standards, address the safety of sunscreen active ingredients, revise and clarify our expectations for testing and recordkeeping by entities that conduct sunscreen testing, and address other sunscreen safety or efficacy concerns, like combination sunscreen-insect repellents and alternative dosage forms. Consumers would benefit from less exposure to sunscreen products containing active ingredients about which safety questions remain, less exposure to sunscreen products labeled with potentially misleading sun protection information, increased consumption of products with better UVA protection, less exposure to flammable spray sunscreens, and less exposure to spray and powder sunscreen products posing inhalation risks. Consumers would also experience transaction cost savings. The costs of the rule to sunscreen manufacturers include administrative costs, costs to fill data gaps for active ingredients and powder dosage forms, product formulation testing costs, and costs to reformulate and relabel sunscreen products. Finally, testing entities would incur recordkeeping costs if they do not already maintain adequate records of testing equipment, methods, and observations in final formulation testing. Table 7 summarizes the costs and benefits of the proposed rule, if finalized. The annualized benefits of the proposed rule, if finalized, would range from $0.00 million to $3.72 million at a 7 percent discount rate and from $0.00 million to $3.62 million at a 3 percent discount rate. Our primary estimate of annualized benefits would equal $0.91 million at a 7 percent discount rate and $0.88 million at a 3 percent discount rate. The annualized costs of the proposed rule, if finalized, would range from $15.57 million to $75.84 million at a 7 percent discount rate and from $12.40 million to $60.42 million at a 3 percent discount rate. Our primary estimate of annualized costs would be $47.55 million at a 7 percent discount rate and $37.79 million at a 3 percent discount rate.52 TABLE 7—SUMMARY OF BENEFITS, COSTS, AND DISTRIBUTIONAL EFFECTS OF THE PROPOSED RULE Units Primary estimate Category Benefits: Annualized Monetized ($m/ year). Annualized Quantified (mil oz/ year) 1. Annualized Quantified (mil oz/ year) 2. Low estimate High estimate $0.91 0.88 201.79 $0.00 0.00 98.16 $3.72 3.62 286.26 51.42 19.43 83.41 Annualized Quantified (mil oz/ year) 3. 161.04 159.88 162.20 Annualized Quantified (mil oz/ year) 4. 386.44 384.86 388.02 Qualitative .............................. Costs: Annualized Monetized ($m/ year). Annualized Quantified. Qualitative .............................. Transfers: Federal Annualized tized ($m/year). Year dollars 2017 2017 Discount rate (%) Period covered (years) 7 3 Notes 20 20 Increased use of products with improved UVA protection. Less exposure to sunscreens containing active ingredients about which safety questions remain. Less exposure to sunscreens with potentially misleading sun protection information. Less exposure to spray and powder sunscreens posing inhalation risks. Quicker responses to adverse events, improved inspections, and better protection of human subjects. Potential transaction cost savings related to changes in the effort required to choose a sunscreen. 47.55 37.79 15.57 12.40 75.84 60.42 2017 2017 7 3 20 20 Recordkeeping costs to testing entities that do not already maintain adequate records. Mone- 52 The primary estimate of the costs is not the average of the lower bound costs and the upper bound costs. VerDate Sep<11>2014 18:42 Feb 25, 2019 Jkt 247001 PO 00000 Frm 00048 Fmt 4701 Sfmt 4702 E:\FR\FM\26FEP2.SGM 26FEP2 6251 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules TABLE 7—SUMMARY OF BENEFITS, COSTS, AND DISTRIBUTIONAL EFFECTS OF THE PROPOSED RULE—Continued Units Primary estimate Category Low estimate High estimate Year dollars From: To: From: To: Discount rate (%) Period covered (years) Notes Other Annualized Monetized ($m/year). Effects: State, Local, or Tribal Government: None. Small Business: Some small businesses could exit the sunscreen market by discontinuing their products or going out of business. Wages: None. Growth: None. 1 Values represent the 2016 consumption of sunscreens that would provide improved UVA protection under the proposed rule. represent the 2016 consumption of sunscreens that contain active ingredients about which safety questions remain. 3 Values represent the 2016 consumption of sunscreens with potentially misleading sun protection information. 4 Values represent the 2016 consumption of potentially inhalable spray sunscreens and powder sunscreens. 2 Value Table 8 shows the Executive Order 13771 summary over an infinite time horizon. In this analysis we assume that the costs and cost savings of the rule would end after 20 years. We estimate that this rule generates $29.85 million in net annualized costs, discounted at 7 percent, over a perpetual time horizon. Based on these costs, this proposed rule would be considered a regulatory action under E.O. 13771. TABLE 8—E.O. 13771 SUMMARY TABLE [In $ millions 2016 dollars, over an infinite time horizon) 1 Primary estimate (7%) Present Value of Costs ............................ Present Value of Cost Savings ................ Present Value of Net Costs ..................... Annualized Costs ..................................... Annualized Cost Savings ......................... Annualized Net Costs .............................. 1 We $456.33 0.00 456.33 29.85 0.00 29.85 Lower bound (7%) Upper bound (7%) $149.22 0.00 149.22 9.76 0.00 9.76 $730.46 0.00 730.46 47.79 0.00 47.79 Primary estimate (3%) $618.16 0.00 618.16 40.44 0.00 40.44 Lower bound (3%) $201.53 0.00 201.53 13.18 0.00 13.18 Upper bound (3%) $1,002.22 0.00 1,002.22 65.57 0.00 65.57 assume that the benefits and costs of the proposed rule would diminish after 20 years. Negative values denoted in parentheses. We have developed a comprehensive Economic Analysis of Impacts that assesses the impacts of the proposed rule. The full preliminary analysis of economic impacts is available in the docket for this proposed rule (Ref. 63) and at https://www.fda.gov/AboutFDA/ ReportsManualsForms/Reports/ EconomicAnalyses/default.htm. XIV. Analysis of Environmental Impact We have determined under 21 CFR 25.31(c) that this action is of a type that does not individually or cumulatively have a significant effect on the human environment. Therefore, neither an environmental assessment nor an environmental impact statement is required. XV. Paperwork Reduction Act of 1995 This proposed rule contains information collection provisions that are subject to review by OMB under the Paperwork Reduction Act of 1995 (PRA) VerDate Sep<11>2014 18:42 Feb 25, 2019 Jkt 247001 (44 U.S.C. 3501–3520). A description of these provisions is given in the Description section of this document with an estimate of the annual reporting, recordkeeping, and thirdparty disclosure burden. Included in the estimate is the time for reviewing instructions, searching existing data sources, gathering and maintaining the data needed, and completing and reviewing each collection of information. FDA invites comments on these topics: (1) Whether the proposed collection of information is necessary for the proper performance of FDA’s functions, including whether the information will have practical utility; (2) the accuracy of FDA’s estimate of the burden of the proposed collection of information, including the validity of the methodology and assumptions used; (3) ways to enhance the quality, utility, and clarity of the information to be collected; and (4) ways to minimize the PO 00000 Frm 00049 Fmt 4701 Sfmt 4702 burden of the collection of information on respondents, including through the use of automated collection techniques, when appropriate, and other forms of information technology. Title: Sunscreen Drug Products for OTC Human Use. Description: The proposed rule would amend FDA’s current sunscreen labeling regulation (§ 201.327) and sunscreen products monograph (part 352) regarding product labeling, testing, and recordkeeping requirements. We note that existing regulations (e.g., current § 201.327) already require SPF testing and labeling. The information collections associated with current testing, labeling, and recordkeeping requirements have previously been approved in accordance with the PRA under OMB control numbers 0910– 0139, 0910–0717, and 0910–0755. For more information about current regulations and their history, see the Background and Scope sections of the E:\FR\FM\26FEP2.SGM 26FEP2 6252 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules proposed rule (sections III and IV, respectively). The proposed rule would also amend parts 310 and 347. While the proposed provisions are broadly consistent with current best practices for testing conducted in human subjects and are not expected to require significant changes by reputable and experienced testing establishments, the proposed rule clarifies and confirms the application of existing requirements to sunscreens and adds certain new requirements, particularly for labeling and recordkeeping. The purpose of these changes is to help ensure that sunscreen testing is conducted and documented in a way that verifiably provides for protection of human subjects and increases the reliability of the testing data that underlies sunscreen labeling, and to update the labeling requirements. Description of Respondents: Affected entities include: (1) ‘‘responsible persons,’’ as defined in proposed § 201.327(a); (2) entities to which the responsible person transfers its obligations as permitted under proposed § 201.327(a)(1) (e.g., contract manufacturers, contract testing entities, contract research organizations); and (3) clinical investigators conducting the testing (the investigator(s) required to submit investigator statements and other materials to the responsible person). FDA estimates that up to 772 entities could meet the proposed definition of responsible person (equivalent to ‘‘brands’’ in the economic analysis found in section XIII, Preliminary Analysis of Economic Impacts). The estimate of 772 entities also includes nearly all entities to which a responsible person might transfer its obligations (‘‘transferees’’), such as contract manufacturers, contract repackagers, contract distributors. For example, a manufacturer may be a responsible person for one brand and a contract manufacturer for another. However, in addition to the 772 entities and potential transferees already described, we estimate that there are approximately 10 U.S.-based contract testing entities used by multiple responsible persons to conduct sunscreen testing (e.g., contract laboratories and contract research organizations). These 10 potential transferees are not included in the 772 figure. Thus, for certain information collections, the estimated respondent number may be 782. We note that this estimate does not include non-U.S.based contract testing entities. In addition to the 10 contract testing entities, FDA estimates that approximately 10 of the estimated 772 responsible persons conduct their own VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 SPF or broad spectrum testing. Thus, we estimate that there are approximately 20 entities that conduct covered sunscreen testing; we estimate these entities have approximately 20 lead clinical investigators to whom certain information collection obligations (e.g., reporting) may apply. A. Labeling for Sunscreen Products and Associated Clinical Testing The proposed rule includes thirdparty disclosure obligations for responsible persons. The provisions may also apply to entities to which the responsible persons transfer their responsibilities under section 201.327(a)(1) (‘‘transferees’’), depending on the scope of transferred obligations. There are labeling-related information collections (requirements include certain information on product labels) and a related testing burden (requirements for certain clinical testing to determine and support labeling information). 1. Labeling-Related Information Collection and Burden Proposed § 201.327(b) and § 201.327(h)(1) amend certain labeling requirements applicable to the PDP. Among other things, proposed § 201.327(b) sets forth labeling requirements for the statement of identity and SPF value claims discussed in this section. Proposed § 201.327(h)(1) applies to the statement of identity for sunscreen products that also contain skin protectant active ingredients. Proposed § 352.50 requires that the PDP labeling comply with the requirements of § 201.327(b). The SPF value statements set forth in proposed § 201.327(b) and referenced in proposed § 352.50 are based on the results of the testing required in proposed § 201.327(i) and proposed part 352 (§ 352.70). a. Statement of identity. Proposed § 201.327(b)(1) requires that sunscreen drug products bear a statement of identity consisting of the name of each sunscreen active ingredient listed in alphabetical order, followed by ‘‘Sunscreen’’ and ‘‘[Dosage form]’’ (e.g., ‘‘Lotion’’, ‘‘Spray’’). Proposed § 352.52(a) requires the labeling to contain a statement of identity in accordance with § 201.327(b). Proposed § 201.327(h)(1) applies to sunscreen drug products that also contain skin protectant active ingredients; it requires that the product bear a statement of identity consisting of the name of all sunscreen and skin protectant active ingredients in alphabetical order, followed by ‘‘Sunscreen/Skin Protectant’’ and ‘‘[Dosage form],’’ presented in PO 00000 Frm 00050 Fmt 4701 Sfmt 4702 accordance with § 201.327(b)(1)(ii). Proposed § 352.60(a) requires that the product bear a statement of identity as set forth in § 201.327(h)(1). Proposed § 352.20(b)(4) requires that the product must be labeled in accordance with §§ 201.327(h) and 352.60. Proposed § 347.60(a)(3) requires that the labeling of the product bear the statement of identity set forth in proposed § 352.60(a). We note that current regulations already include a requirement that OTC products bear a statement of identity (see § 201.66). This proposed rule would set forth the specific requirements just described for sunscreen drug products and sunscreen drug products that also contain skin protectant active ingredients. We believe this analysis reflects the additional burden beyond current statement of identity requirements. b. SPF value. Proposed § 201.327(b)(2) requires, among other things, that the labeling display certain statements regarding the product’s SPF value; the statements must be supported by the testing required by proposed § 201.327(i) and referenced in proposed § 352.70. As previously noted, certain SPF testing and labeling is already required under current regulations. This analysis reflects the estimated additional burden of the proposed changes to SPF testing and labeling requirements. c. Burden for proposed statement of identity and SPF value information collections. The estimated burden for the statement of identity and SPF value information collections just described is provided in table 11 (Estimated Annual Third-Party Disclosure Burden). For currently marketed OTC sunscreen products, FDA believes that responsible persons need only complete the testing (or reanalyze existing testing data) and relabel the product as required by the rule one time, and may then continue to utilize the resultant labeling going forward without additional burden. We estimate that 772 respondents would need to complete this relabeling and related testing (if not already done) or reanalysis of existing test results one time for up to 4,078 total products. In addition, there may be new products introduced each year. We estimate that as many as 1,500 new OTC sunscreen product stock keeping units (SKUs) may be introduced each year by up to 772 respondents. These new products must be tested and labeled with the SPF value and broad spectrum results determined in the tests. We estimate that the 1,500 new sunscreen SKUs represent 975 new formulations. E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules Table 11, row 1 provides FDA’s estimate that 772 respondents will need to create PDP labeling for currently marketed sunscreen formulations in accordance with the statement of identity and SPF value requirements of proposed § 201.327(b)(1), (b)(2), and (h)(1). This would be a one-time burden, and FDA estimates 5.2824 responses per respondent for a total of 4,078 responses. FDA estimates a burden of 0.5 hours per response. We estimate the total burden of this recordkeeping to be 2,039 hours. Table 11, row 2 provides FDA’s estimate that up to 772 respondents will need to create PDP labeling for new formulations each year in accordance with the statement of identity and SPF value requirements of proposed § 201.327(b)(1), (b)(2), and (h)(1). FDA estimates 1.943 responses per respondent for a total of 1,500 responses. FDA estimates a burden of 0.5 hours per response. We estimate the total burden of this recordkeeping to be 750 hours. Table 11, row 3 provides FDA’s estimate that 20 respondents will conduct SPF testing in accordance with § 201.327(i) (to determine the SPF value required by § 201.327(b)(2)) for currently marketed sunscreen formulations, if this has not already been done. This would be a one-time burden. The estimated number of respondents reflects FDA’s assumption based on its knowledge of the existing market that, of the 772 responsible persons, approximately 10 will conduct their own final formulation testing under § 201.327(i), while most will delegate the responsibility for conducting final formulation testing to the approximately 10 independent testing entities that FDA believes conduct most final formulation testing. FDA estimates 111 responses per respondent for a total of 2,220 responses. FDA estimates a burden of 24 hours per response. We estimate the total burden to be 53,280 hours. Table 11, row 4 provides FDA’s estimate that 20 respondents will conduct SPF testing in accordance with § 201.327(i) (to determine the SPF value required by § 201.327(b)(2)) for new sunscreen formulations. FDA estimates 48.75 responses per respondent for a total of 975 responses. FDA estimates a burden of 24 hours per response. We estimate the total burden to be 23,400 hours. Regarding proposed § 352.70, because that section does not add any additional labeling or testing-related information collections not already addressed elsewhere (it incorporates the proposed SPF testing requirements as a condition VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 of the part 352 monograph), there is no additional burden. 2. Clinical Testing-Related Information Collection and Burden Proposed § 201.327(i) contains requirements for clinical testing of SPF values for inclusion on sunscreen product labeling. As previously noted, current regulations already require SPF testing. While FDA expects that SPF testing and some of the proposed recordkeeping is already being done, the proposed changes are intended to clarify existing requirements applicable to sunscreen drug products and set forth certain new requirements intended to improve the reliability of SPF testing and ensure the protection of human subjects. Proposed § 352.70 references the § 201.327(i) testing requirements and makes the referenced testing requirements part of the monograph conditions of use. Across disciplines, testing involving human subjects is ordinarily conducted under IRB oversight as a means of ensuring that adequate human subject protections are provided and to ensure the integrity of study design and execution. Thus, in this proposed regulation, FDA is proposing to apply certain human subject protection requirements to sunscreens, with the aim of having a framework similar to that used in the IND context, but tailored to sunscreen testing. Information collections related to proposed § 201.327(i) are addressed in detail in the sections that follow. Regarding proposed § 352.70, as in the previous section, because the proposed change does not add any additional labeling or testing-related information collections not already addressed elsewhere (it cross-references the proposed § 201.327(i) testing requirements as a condition of the part 352 monograph), there is no additional burden. a. Investigator statements and notifications. Proposed § 201.327(i), among other things, requires responsible persons to obtain a signed investigator statement and an investigator CV, and to provide certain notifications (e.g., notification of adverse drug experiences). These may result in thirdparty disclosure or reporting requirements for responsible persons (and entities to which they have transferred relevant obligations) as well as for clinical investigators. As noted above, our experience leads us to believe that most responsible persons will transfer their obligations under § 201.327(i) to the approximately 20 entities that currently conduct clinical SPF testing. This assumption is PO 00000 Frm 00051 Fmt 4701 Sfmt 4702 6253 reflected in the estimates regarding the number of respondents below. b. Investigator statements, CVs, and related burden. Proposed § 201.327(i)(1)(i) requires responsible persons to, among other things, obtain a signed investigator statement from each investigator. Proposed § 201.327(i)(1)(iv)(B) requires responsible persons to obtain a signed investigator statement and CV. In FDA’s experience, investigators for SPF testing are most often employed by the testing entities, and we therefore believe this is a recordkeeping requirement rather than a third-party reporting requirement. We request comment on this assumption. As noted above, we estimate that responsible persons will typically delegate this obligation to the approximately 20 entities conducting final formulation testing. We estimate that each testing entity employs one clinical investigator to run the SPF testing they conduct. One investigator may run multiple SPF tests, and so long as the responsible person (or testing entity) has the investigator statement and CV on file for each investigator, there need not be a separate copy for each investigation. Table 10, row 1 provides FDA’s estimate that approximately 20 respondents will need to obtain and keep a signed investigator statement and CV in accordance with § 201.327(i)(1)(i) and (i)(1)(iv)(B). FDA estimates 2 responses per respondent (1 CV and 1 investigator statement) for a total of 40 annual responses. FDA estimates a burden of 0.6 hours per response. We estimate the total burden of this recordkeeping to be 24 hours. c. Notifications and related burden. Proposed § 201.327(i)(1)(i) requires responsible persons to, among other things, ensure that FDA and all participating investigators are promptly informed of significant new adverse effects or risks with respect to the drug. Proposed § 201.327(i)(1)(v) requires responsible persons to keep each participating investigator informed of new observations about the drug, particularly with respect to adverse effects and safe use. As mentioned above, like other obligations associated with testing under proposed § 201.327(i), we anticipate that this obligation will be delegated in most instances to the approximately 20 entities that currently conduct SPF testing on behalf of responsible persons. Table 9, row 1 provides FDA’s estimate that approximately 20 respondents will need to inform FDA and participating investigators of significant new adverse effects or risks in accordance with § 201.327(i)(1)(i) and E:\FR\FM\26FEP2.SGM 26FEP2 6254 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules of new safety and other observations in accordance with § 201.327(i)(1)(v). FDA estimates up to 40 responses per respondent for a total of up to 800 annual responses. FDA estimates a burden of 0.5 hours per response. We estimate the total burden of this recordkeeping to be 400 hours. d. Informed consent, IRB review, and related burden. Proposed § 201.327(i)(1)(ii) requires responsible persons to obtain informed consent, as defined in part 50, before clinical final formulation testing and proposed § 201.327(i)(1)(iii) requires that clinical testing under § 201.327(i) be reviewed and approved by an IRB meeting the requirements of part 56. These two proposed provisions make clear that FDA’s regulations governing informed consent (part 50) and IRB approval of research (part 56) apply to clinical final formulation testing conducted pursuant to § 201.327(i). Regarding proposed § 201.327(i)(1)(ii) and (iii), the information collections associated with FDA’s regulations governing informed consent (part 50) and IRB approval of research (part 56) have previously been approved in accordance with the PRA under OMB control number 0910–0755. FDA does not expect that proposed § 201.327(i)(1)(ii) or (iii) would affect the number of recordkeepers, records, reports, or associated burdens included in the existing approval (0910–0755), but we invite stakeholders to comment if they have a different view. Proposed § 201.327(i)(1)(vii) requires investigators to provide safety reports and a final study report to the responsible person. Although investigators are often employees of testing entities, we are basing our estimate on our assumption the respondents in this case are the investigators themselves because of the framing of the duty proposed by the regulation. Table 9, row 2 provides FDA’s estimate that up to 20 respondents will need to provide safety reports in accordance with § 201.327(i)(1)(vii)(A). FDA estimates 24.4 responses per respondent for a total of 488 annual responses. FDA estimates a burden of 0.5 hours per response. We estimate the total burden of this recordkeeping to be 244 hours. Table 9, row 3 provides FDA’s estimate that up to 20 respondents will need to provide a final report in accordance with § 201.327(i)(1)(vii)(B). This will occur one time per study, with each of the 20 investigators conducting multiple studies per year. FDA estimates 48.75 responses per respondent for a total of 975 annual VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 responses. FDA estimates a burden of 3 hours per response. We estimate the total burden of this recordkeeping to be 2,925 hours. Proposed § 352.40(i)(1) references limitations on particle size for sunscreens in a spray dosage form. Proposed § 352.40(i)(2) and (3) proposes limitations on flammability and drying time for spray sunscreen formulations. These proposed sections (§ 352.40(i)(1) through (3)) make the referenced limitations on flammability and particle size requirements part of the monograph conditions of use. Proposed § 352.40(i)(5) states that applicable requirements for particle size, flammability, and drying time for spray sunscreens must be verified through batch and lot testing as part of CGMP compliance under part 211. Entities conducting testing required by these sections must also comply with associated recordkeeping requirements, including those set forth in parts 210 and 211. The recordkeeping associated with ensuring compliance with § 352.40(i)(5) (batch and lot testing to ensure compliance with particle size, flammability, and drying time limitations) is considered to be part of the manufacturers’ CGMP requirements under parts 210 and 211 (OMB control number 0910–0139). While FDA believes that sunscreen manufacturers are already included among the respondents counted for that collection, and that many of those manufacturers who have spray dosage products may already be conducting flammability and drying time testing (e.g., many are including flammability statements and information about drying time in current product labeling), the proposed inclusion of these requirements in the sunscreen regulations is new. The proposed rule specifies the particle size, flammability, and drying time limitations that would be required for sunscreens in spray dosage forms to be GRASE under the monograph. The proposed rule also specifies that compliance with these limitations must be verified through batch and lot testing. While this greater specificity as to required testing might have a marginal effect on the burden associated with recordkeeping for manufacturing facilities that are not already conducting such testing, FDA believes that the total change would be minimal in light of the total recordkeeping burden under parts 210 and 211, which is estimated across thousands of manufacturers of a wide variety of drugs. We request comment on these assumptions. If FDA determines that the assumptions are incorrect, then, concurrent with PO 00000 Frm 00052 Fmt 4701 Sfmt 4702 publication of the final rule, FDA plans to amend its approved information collection 0910–0139, if necessary, to adjust the respective burden estimate(s) to account for any change. We request comment on the accuracy of our assumptions and the resulting burden estimate. B. Regulatory Status of Testing Entities Proposed § 201.327(k) clarifies the regulatory status of final formulation testing, including that final formulation testing conducted pursuant to § 201.327 constitutes ‘‘manufacture’’ of a drug. As such, this testing must be conducted in an establishment registered in accordance with part 207 and section 510 of the FD&C Act, and entities conducting final formulation testing required by this section must comply with CGMP and associated recordkeeping requirements, including those set forth in § 201.327(l) and in parts 210 and 211. As this provision is intended only to clarify an existing requirement, it does not create a new information collection. Entities covered by this provision are already included in the burden estimates for the information collections associated with registration and listing requirements. Recordkeeping obligations related to registration and listing under part 207 and section 510 of the FD&C Act are part of FDA’s approved information collection for part 207 (OMB control number 0910–0829). CGMP recordkeeping obligations are part of FDA’s approved information collection for part 211 (OMB control number 0910–0139). C. Generating and Maintaining Records of SPF and Broad Spectrum Testing FDA is proposing specific recordkeeping requirements for SPF and broad spectrum testing to enable FDA to better monitor responsible persons’ compliance with the requirements of § 201.327. Recordkeeping is essential for FDA to evaluate whether required testing of final formulations is being conducted properly (both as to human subject protection and as to study design) and to enable the Agency to investigate postmarketing product failures or adverse events. Appropriate recordkeeping also enables FDA to conduct better and more efficient inspections of entities conducting final formulation testing. The proposed recordkeeping requirements are in alignment with the records required for other types of manufacturing under CGMPs as set forth in parts 210 and 211. Failure to maintain adequate records of testing equipment, methods, and observations can raise broad questions E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules about the reliability of final formulation testing. In FDA’s experience, there has been a lack of uniformity in testing entities’ approaches to recordkeeping for final formulation testing, raising concerns about the Agency’s ability to assess the reliability of the results of final formulation testing. The proposed regulation would address these concerns, clarify FDA’s expectations, and align the regulation with current best practices. a. Potential transfer of obligations. Proposed § 201.327(a)(1) permits a responsible person (defined in § 201.327(a)) to transfer some or all of its obligations to another entity (a ‘‘transferee’’), except for obligations with respect to recordkeeping under § 201.327(l). We note that this could create some situations in which both the responsible person and the transferee would be required to comply with applicable recordkeeping requirements. The proposed provision would also require a written record of the transfer of obligations to be maintained by both parties to the transfer. Regarding the record of an obligation transfer, FDA believes that it is usual and customary business practice for a written record of a transfer of obligations to be maintained by both parties to the transfer. FDA does not believe this requirement would incur any additional recordkeeping burden and believes it would meet the exception at 5 CFR 1320.3(b)(2). Regarding the potential for some recordkeeping obligations to fall on both responsible persons and transferees, although proposed § 201.327(a)(1) does not itself impose a specific requirement to generate records, it does create the potential for some recordkeeping obligations to fall on both responsible persons and transferees. In particular, if a responsible person has delegated all other responsibilities under § 201.327(i) and (j), they would nonetheless need to maintain a copy of the records of final formulation testing required by § 201.327(l)(2) and (3). We have included the burden associated with keeping this copy in our assumption that there are 782 respondents for recordkeeping obligations as described below (20 entities that conduct testing, 10 of whom are also responsible persons, plus 762 responsible persons that delegate their responsibility for conducting testing (e.g., to one of the 10 independent testing entities that are not themselves responsible persons)). We invite comment on whether our estimates properly reflect the recordkeeping obligations. b. Maintenance records and related burden. Proposed § 201.327(l)(1) VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 addresses maintenance records. The proposed rule clarifies that, as manufacturing, final formulation testing must comply with CGMPs, and, accordingly, records documenting proper maintenance of equipment used in final formulation testing must be generated and maintained by testing entities, consistent with existing obligations in part 211. Regarding proposed § 201.327(l)(1), the existing maintenance record obligations are part of FDA’s approved information collection for part 211 (OMB control number 0910–0139), and FDA believes that most of the respondents for this collection of information (the approximately 20 entities we believe are conducting final formulation testing) are already included among the recordkeepers counted for that collection. The proposed rule provides greater specificity regarding what information should be included in maintenance records maintained by facilities conducting final formulation testing. While this greater specificity might have a marginal effect on the burden associated with recordkeeping for these facilities, and the number of respondents for this requirement may need to be increased by 10 (to reflect contract testing entities that may not be currently registered as manufacturers), FDA believes that the total change would be minimal in light of the total recordkeeping burden under parts 210 and 211, which is estimated across thousands of manufacturers of a wide variety of drugs. We request comment on these assumptions. If FDA determines that the assumptions are incorrect, then, concurrent with publication of the final rule, FDA plans to amend its approved information collection under OMB control number 0910–0139 as necessary to adjust the respective burden estimate(s) in order to account for any change. c. SPF testing records and related burden. Proposed § 201.327(l)(2) addresses SPF testing records and requires that respondents keep records related to the identification of the entity conducting the testing, the formulation being tested, equipment used, investigators, SPF standards, specific subject and test result data, and records demonstrating compliance with § 201.327(i)(1) governing the establishment of adequate clinical testing procedures and conditions. This is important because failure of testing entities to keep adequate records to support final formulation testing may leave FDA unable to verify the reliability of the results of SPF testing. Because one testing entity may conduct PO 00000 Frm 00053 Fmt 4701 Sfmt 4702 6255 final formulation testing on behalf of multiple responsible persons, an error at one testing entity may affect data across multiple clinical SPF testing studies for multiple different final formulations that are ultimately sold under different labels. In particular, proposed § 201.327(l)(2) requires that, in addition to any records required to be kept pursuant to parts 210 and 211, records of SPF testing must include: (1) Identification of the testing entity; (2) the product identifier and expected SPF; (3) characterization of the SPF standard sunscreen required by proposed § 201.327(i)(3) (lot number, manufacturing date, and results of high performance liquid chromatography (HPLC) SPF standard assay); (4) documentation linking any blinded samples with the product lot number and formulation tested; (5) specific testing records for each human subject (identification of the UV source used for testing and various specific test results and the individual(s) who determined the values); (6) the mean and standard deviation from SPFi values, standard error and determined SPF value derived as set forth in proposed § 201.327(i)(7); (7) records for water resistance testing of pool temperature, air temperature, and relative humidity as required by proposed § 201.327(i)(8); and (8) records demonstrating compliance with proposed § 201.327(i)(1) requirements for adequate clinical testing procedures and conditions (e.g., individual case histories and documentation of IRB review). Table 10, row 2 provides FDA’s estimate that approximately 20 respondents will need to generate SPF testing records in accordance with proposed § 201.327(l)(2) for existing products that will be reformulated. FDA estimates 85.5 records per recordkeeper for a total of 1,710 records. This is a one-time burden. FDA estimates a burden of 24 hours per recordkeeping. We estimate the total burden of this recordkeeping to be 41,040 hours. Table 10, row 3 provides FDA’s estimate that up to 20 respondents will need to generate SPF testing records in accordance with proposed § 201.327(l)(2) for new formulations. FDA estimates 48.75 records per recordkeeper for a total of 975 records. FDA estimates a burden of 24 hours per recordkeeping. We estimate the total burden of this recordkeeping to be 23,400. Table 10, row 4 provides FDA’s estimate that up to 782 respondents will need to keep SPF testing records in accordance with proposed § 201.327(l)(2) for existing products that will be reformulated. This is a one-time E:\FR\FM\26FEP2.SGM 26FEP2 6256 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules burden. FDA estimates 2.1867 records per recordkeeper for a total of 1,710 records. FDA estimates a burden of 0.33 hours per recordkeeping. We estimate the total burden of this recordkeeping to be 564.3 hours. Table 10, row 5 provides FDA’s estimate that up to 782 respondents will need to keep SPF testing records in accordance with proposed § 201.327(l)(2) for new formulations. FDA estimates 1.2468 records per recordkeeper for a total of 975 records. FDA estimates a burden of 0.33 hours per recordkeeping. We estimate the total burden of this recordkeeping to be 321.75 hours. With regard to the testing-related estimates, we note that the requirements for obtaining certain medical history information from test subjects are not considered collections of information because information collected from subjects of clinical testing does not constitute information under 5 CFR 1320.3(h)(5), and that the referenced informed consent and IRB requirements under parts 50 and 56 are covered by existing approvals, as previously discussed. d. Broad spectrum testing records and related burden. Proposed § 201.327(l)(3) addresses broad spectrum testing records. The proposed rule requires records related to the identification of the entity conducting the testing, the formulation being tested, equipment used, investigators, UV standards, sunscreen application, and specific test result data. This is important because failure of testing entities to keep adequate records to support broad spectrum testing may leave FDA unable to verify the reliability of testing results. Failure at one testing entity may affect data across multiple broad spectrum testing studies for multiple different final formulations that are ultimately sold under different labels. In particular, proposed § 201.327(l)(3) requires that records of broad spectrum testing must include: (1) Identification of the testing entity; (2) records of sample information (product identifier and expected SPF, master key for blinded samples, sample number and identifier code, polymethylmethacrylate (PMMA) plate surface topography measurement, and sample holder orientation); (3) identification of each UV source used for sunscreen product pre-irradiation; (4) records of sunscreen product application (sample weights, equipment identification); (5) measurements required by proposed § 201.327(j)(4) to (6)); (6) records of critical wavelength and UVA1/UV ratio values; (7) for each sample: The identity of the individual(s) conducting specific testing steps; and (8) test dates for the broad spectrum test conducted pursuant to § 201.327(j), and sample report forms and supporting data. Table 10, row 6 provides FDA’s estimate that approximately 20 respondents will need to generate broad spectrum testing records in accordance with proposed § 201.327(l)(3) for existing products. As with records of SPF testing, this number of respondents reflects FDA’s assumption that most responsible persons will delegate responsibility for conducting testing under § 201.327(j) to the approximately 20 testing entities. FDA estimates 203.9 records per recordkeeper for a total of 4,078 records. This is a one-time burden. FDA estimates a burden of 1.5 hours per recordkeeping. We estimate the total burden of this recordkeeping to be 6,117 hours. Table 10, row 7 provides FDA’s estimate that up to 20 respondents will need to generate broad spectrum testing records in accordance with proposed § 201.327(l)(3) for new formulations. FDA estimates 48.75 records per recordkeeper for a total of 975 records. FDA estimates a burden of 1.5 hours per recordkeeping. We estimate the total burden of this recordkeeping to be 1,462.5 hours. Table 10, row 8 provides FDA’s estimate that up to 782 respondents will need to keep broad spectrum testing records in accordance with proposed § 201.327(l)(3) for existing products. This is a one-time burden. FDA estimates 5.215 records per recordkeeper for a total of 4,078 records. FDA estimates a burden of 0.17 hours per recordkeeping. We estimate the total burden of this recordkeeping to be 693.3 hours. Table 10, row 9 provides FDA’s estimate that up to 782 respondents will need to keep broad spectrum testing records in accordance with proposed § 201.327(l)(3) for new formulations. FDA estimates 1.2468 records per recordkeeper for a total of 975 records. FDA estimates a burden of 0.17 hours per recordkeeping. We estimate the total burden of this recordkeeping to be 165.75 hours. The recordkeeping burden is estimated as described in the tables at the end of the PRA discussion. With the exceptions noted above, we conclude that the other provisions of this rule are not subject to OMB review under the PRA. The proposed changes to part 310 do not include any collections of information subject to the PRA. The remaining sections of part 347 do not include any collections of information not already addressed in this analysis. Section 201.327 and the remaining sections of part 352 either do not contain an information collection subject to PRA, or contain specific labeling information, including directions and warnings, which are a ‘‘public disclosure of information originally supplied by the Federal Government to the recipient for the purpose of disclosure to the public’’ (5 CFR 1320.3(c)(2)) and, therefore, are not collections of information. FDA estimates the burden of this information collection as follows: TABLE 9—ESTIMATED ANNUAL REPORTING BURDEN 1 Number of respondents Activity and 21 CFR section Number of responses per respondent Total annual responses Average burden per response Total hours Inform FDA and investigators of significant new adverse effects or risks (§ 201.327(i)(1)(i)) and new safety and other observations (§ 201.327(i)(1)(v)). Investigators provide safety reports in accordance with § 201.327(i)(1)(vii)(A). Investigators provide a final report in accordance with § 201.327(i)(1)(vii)(B) (one time per study). 20 40 800 0.5 (30 minutes) ..... 400 20 24.4 488 0.5 (30 minutes) ..... 244 20 48.75 975 3 ............................. 2,925 Total ...................................................................... ........................ ........................ ........................ ................................ 3,569 1 There are no capital costs or operating and maintenance costs associated with this collection of information. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 PO 00000 Frm 00054 Fmt 4701 Sfmt 4702 E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules 6257 TABLE 10—ESTIMATED ANNUAL RECORDKEEPING BURDEN 1 Number of recordkeepers Activity and 21 CFR section Obtain and keep a signed investigator statement and CV in accordance with § 201.327(i)(1)(i) and (iv)(B). Generate SPF testing records for existing products (§ 201.327(l)(2)) (one-time). Generate SPF testing records for new formulations (§ 201.327(l)(2)). Keep SPF testing records for existing products (§ 201.327(l)(2)) (one-time). Keep SPF testing records for new formulations (§ 201.327(l)(2)). Generate Broad Spectrum testing records for existing products (§ 201.327(l)(3)). Generate Broad Spectrum testing records for new formulations (§ 201.327(l)(3). Keep Broad Spectrum testing records for existing products (§ 201.327(l)(3)). Keep Broad Spectrum testing records for new formulations (§ 201.327(l)(3)). Total ...................................................................... 1 There Number of records per recordkeeper Total annual records Average burden per recordkeeping Total hours 20 2 40 0.6 (36 minutes) ..... 24 20 85.5 1,710 24 ........................... 41,040 20 48.75 975 24 ........................... 23,400 782 2.1867 1,710 0.33 (20 minutes) ... 564.3 782 1.2468 975 321.75 20 203.9 4,078 0.33 ........................ (20 minutes) ........... 1.5 .......................... 20 48.75 975 1.5 .......................... 1,462.5 782 5.215 4,078 0.17 (10 minutes) .. 693.3 782 1.2468 975 0.17 (10 minutes) .. 165.75 ........................ ........................ ........................ ................................ 773,788.6 6,117 are no capital costs or operating or maintenance costs associated with this collection of information. TABLE 11—ESTIMATED ANNUAL THIRD-PARTY DISCLOSURE BURDEN 1 Number of respondents Activity and 21 CFR section Number of disclosures per respondent Total annual disclosures Average burden per disclosure Total hours Create PDP labeling in accordance with statement of identity and SPF value requirements (§ 201.327(b)(1), (b)(2) and (h)(1)) for currently marketed sunscreen formulations (one-time burden). Create PDP labeling in accordance with statement of identity and SPF value requirements (§ 201.327(b)(1), (b)(2), and (h)(1)) for new formulations. Conduct SPF testing in accordance with § 201.327(i) to determine SPF value for currently marketed sunscreen formulations (if not already done) (onetime burden). Conduct SPF testing in accordance with § 201.327(i) to determine SPF value for new sunscreen formulations. 772 5.2824 4,078 0.5 (30 minutes) ..... 2,039 772 1.943 1,500 0.5 (30 minutes) ..... 750 20 111 2,220 24 ........................... 53,280 20 48.75 975 24 ........................... 23,400 Total ...................................................................... ........................ ........................ ........................ ................................ 79,469 1 There are no capital costs or operating or maintenance costs associated with this collection of information. In compliance with the PRA (44 U.S.C. 3407(d)), the Agency has submitted the information collection provisions of this proposed rule to OMB for review. These requirements will not be effective until FDA obtains OMB approval. FDA will publish a notice concerning OMB approval of these requirements in the Federal Register. XVI. Federalism We have analyzed this proposed rule in accordance with the principles set forth in Executive Order 13132. Section 4(a) of the Executive order requires Agencies to ‘‘construe . . . a Federal statute to preempt State law only where VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 the statute contains an express preemption provision or there is some other clear evidence that the Congress intended preemption of State law, or where the exercise of State authority conflicts with the exercise of Federal authority under the Federal statute.’’ The sole statutory provision giving preemptive effect to this proposed rule is section 751 of the FD&C Act (21 U.S.C. 379r). We have complied with all of the applicable requirements under the Executive order and have determined that the preemptive effect of this proposed rule, if finalized, would be consistent with Executive Order 13132. Through publication of this PO 00000 Frm 00055 Fmt 4701 Sfmt 4702 proposed rule, we are providing notice and an opportunity for State and local officials to comment on this rulemaking. XVII. Consultation and Coordination With Indian Tribal Governments We have analyzed this proposed rule in accordance with the principles set forth in Executive Order 13175. We have tentatively determined that the rule does not contain policies that would have a substantial direct effect on one or more Indian Tribes, on the relationship between the Federal Government and Indian Tribes, or on the distribution of power and responsibilities between the Federal E:\FR\FM\26FEP2.SGM 26FEP2 6258 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules Government and Indian Tribes. The Agency solicits comments from tribal officials on any potential impact on Indian Tribes from this proposed action. XVIII. References The following references marked with an asterisk (*) are on display at the Dockets Management Staff (see ADDRESSES) and are available for viewing by interested persons between 9 a.m. and 4 p.m., Monday through Friday; they also are available electronically at https:// www.regulations.gov. References without asterisks are not on public display at https://www.regulations.gov because they have copyright restriction. Some may be available at the website address, if listed. References without asterisks are available for viewing only at the Dockets Management Staff. FDA has verified the website addresses, as of the date this document publishes in the Federal Register, but websites are subject to change over time. * 1. FDA, Guidance for Industry, ‘‘Enforcement Policy—OTC Sunscreen Drug Products Marketed Without an Approved Application,’’ May 2018 (available at https://www.fda.gov/Drugs/ GuidanceCompliance RegulatoryInformation/Guidances/ UCM259001), accessed June 7, 2018. 2. 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Degen, et al., ‘‘Prevention of Non-Melanoma Skin Cancer in Organ Transplant Patients by Regular Use of a Sunscreen: a 24 Months, Prospective, Case-Control Study,’’ The British Journal of Dermatology, vol. 161 Suppl 3, pp. 78–84, 2009. 177. Kuhn, A., K. Gensch, M. Haust, et al., ‘‘Photoprotective Effects of a BroadSpectrum Sunscreen in UltravioletInduced Cutaneous Lupus Erythematosus: a Randomized, VehicleControlled, Double-Blind Study,’’ Journal of the American Academy of Dermatology, vol. 64(1), pp. 37–48, 2011. 178. Faurschou, A. and H.C. Wulf, ‘‘Synergistic Effect of Broad-Spectrum Sunscreens and Antihistamines in the Control of Idiopathic Solar Urticaria,’’ Archives of Dermatology, vol. 144(6), pp. 765–769, 2008. 179. Fourtanier, A., D. Moyal, and S. 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Utley, et al., ‘‘Insect Repellant Interactions: Sunscreens Enhance DEET (N,N-DiethylM-Toluamide) Absorption,’’ Drug Metabolism and Disposition, vol. 32, pp.783–785, 2004. PO 00000 Frm 00061 Fmt 4701 Sfmt 4702 6263 206. Gu, X., T. Wang, D.M. Collins, et al., ‘‘In Vitro Evaluation of Concurrent Use of Commercially Available Insect Repellent and Sunscreen Preparations,’’ British Journal of Dermatology, vol. 152(6), pp. 1263–1267, 2005. 207. Wang, T. and X. Gu, ‘‘In Vitro Percutaneous Permeation of the Repellent DEET and the Sunscreen Oxybenzone Across Human Skin,’’ Journal of Pharmacy and Pharmaceutical Sciences, vol. 10(1), pp. 17–25, 2007. 208. Kasichayanula, S., J.D. House, T. Wang, et al., ‘‘Simultaneous Analysis of Insect Repellent DEET, Sunscreen Oxybenzone and Five Relevant Metabolites by Reversed-Phase HPLC with UV Detection: Application to an In Vivo Study in a Piglet Model,’’ Journal of Chromatography B. 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List of Subjects 21 CFR Part 201 Drugs, Incorporation by reference, Labeling, Reporting and recordkeeping requirements. 21 CFR Part 310 Administrative practice and procedure, Drugs, Labeling, Medical devices, Reporting and recordkeeping requirements. 21 CFR Part 347 Labeling, Over-the-counter drugs. 21 CFR Part 352 Labeling, Over-the-counter drugs. Therefore, under the Federal Food, Drug, and Cosmetic Act and under authority delegated to the Commissioner of Food and Drugs, we propose that 21 CFR parts 201, 310, 347, and 352 be amended as follows: PART 201—LABELING 1. The authority citation for part 201 continues to read as follows: ■ E:\FR\FM\26FEP2.SGM 26FEP2 6264 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules Authority: 21 U.S.C. 321, 331, 351, 352, 353, 355, 358, 360, 360b, 360gg–360ss, 371, 374, 379e; 42 U.S.C. 216, 241, 262, 264. ■ 2. Revise § 201.327 to read as follows: § 201.327 Over-the-counter sunscreen drug products; required labeling based on effectiveness testing. The following provisions apply to an over-the-counter (OTC) sunscreen drug product that is intended for application to the skin of humans for purposes of absorbing, reflecting, or scattering radiation in the ultraviolet (UV) range at wavelengths from 290 to 400 nanometers (nm), and that contains one or more of the following as an active ingredient: Avobenzone, cinoxate, dioxybenzone, ensulizole, homosalate, meradimate, octinoxate, octisalate, octocrylene, oxybenzone, padimate O, sulisobenzone, titanium dioxide, or zinc oxide, alone or in combination. The provisions do not apply to OTC sunscreen drug products marketed under approved new drug applications or abbreviated new drug applications. The failure of a product covered by this section to comply with any provision of this section, including the labeling of such a product with any effectiveness claim based on testing that fails to comply with any provision of this section, renders that product misbranded under section 502 of the Federal Food, Drug, and Cosmetic Act. (a) General obligations of responsible persons. As used in this section, a ‘‘responsible person’’ is the manufacturer, packer, or distributor whose name appears on the labeling of a product covered by this section. A responsible person must assure that final formulation testing conducted on its product(s) pursuant to paragraphs (i) and (j) of this section complies with all applicable provisions of this section. (1) Transfer of obligations. (i) A responsible person may transfer responsibility for any or all of its obligations set forth in this section to another entity (e.g., a contract research organization and/or testing laboratory), except as set forth in paragraph (l) (recordkeeping) of this section. Any such transfer must be described in writing. If not all obligations are transferred, the writing is required to describe each of the obligations being assumed by the transferee. If all obligations are transferred, a general statement that all obligations have been transferred is acceptable. Any obligation not covered by the written description will be deemed not to have been transferred. A written record of the transfer of obligations must be maintained by both parties to the VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 transfer for the time period set forth in paragraph (l) of this section. (ii) An entity that assumes any obligation(s) of a responsible person must comply with the provisions of this section applicable to the assumed obligation and will be subject to the same regulatory action as a responsible person for failure to comply with any obligation assumed under this section. Thus, all references to ‘‘responsible person’’ in this section apply to another entity (e.g., a contract research organization or testing laboratory) to the extent that it assumes one or more obligations of a responsible person. (2) Personnel. A responsible person must select only investigators and other personnel qualified by appropriate training and/or experience to conduct final formulation testing pursuant to this section. Personnel engaged in testing under this section must have the education, training, and experience, or any combination thereof, to enable that person to adequately perform their assigned functions. (b) Principal display panel. The following labeling must be prominently placed on the principal display panel: (1) Statement of identity—(i) Placement. The principal display panel of an over-the-counter sunscreen drug product bears a statement of identity as one of its principal features. Except as set forth in paragraph (h) of this section, the statement of identity consists of the name of each sunscreen active ingredient in the product as identified in this section, listed in alphabetical order and followed by ‘‘Sunscreen’’ and ‘‘[Dosage form]’’ (e.g., ‘‘Lotion’’ ‘‘Spray’’). (ii) Prominence. The statement of identity must appear on the principal display panel in boldface type at least one-quarter as large as the size of the most prominent printed matter on the principal display panel, in lines generally parallel to the base on which the package rests as it is designed to be displayed and in direct conjunction with the most prominent display of the proprietary name or designation. The entire text of the statement of identity must appear in the same font style, size, and color with the same background color, and as continuous text with no intervening text or graphic, other than additional text provided in accordance with paragraph (h) of this section. (2) Effectiveness claim. For purposes of this section, the term ‘‘determined SPF value’’ refers to the SPF value that equals the largest whole number less than SPF¥(t*SE), determined for a sunscreen product in accordance with paragraph (i) of this section. PO 00000 Frm 00062 Fmt 4701 Sfmt 4702 (i) SPF Broad Spectrum Statement. For a product that has been shown to pass the broad spectrum test in paragraph (j) of this section, the labeling states ‘‘Broad Spectrum SPF [insert the labeled SPF value associated with the range into which the determined SPF value falls, as set forth in the following table.]’’ TABLE 1 TO PARAGRAPH (b)(2)(i)— SPF LABELING RANGES Range of determined SPF values Associated labeled SPF value 60–80 .................... 50–59 .................... 40–49 .................... 30–39 .................... 25–29 .................... 20–24 .................... 15–19 .................... 2–14 ...................... 60+. 50. 40. 30. 25. 20. 15. Determined SPF Value. (ii) SPF Statement. For a product that has not been shown to pass the broad spectrum test in paragraph (j) of this section, the labeling states ‘‘SPF [insert labeled SPF value associated with the range into which the determined SPF value falls, as set forth in the table in paragraph (b)(2)(i) of this section]’’. (iii) For a product with a determined SPF value of at least 2 but less than 15. The SPF statement is immediately followed by an asterisk (‘‘*’’), and the associated statement ‘‘*See Skin Cancer/ Skin Aging Alert’’ appears in the bottom 30 percent of the principal display panel. (iv) Prominence of required statements. The SPF Broad Spectrum statement, SPF statement, and ‘‘*See Skin Cancer/Skin Aging Alert’’ statement, as applicable, must appear in boldface type at least one-quarter as large as the most prominent printed matter on the principal display panel and in lines generally parallel to the base on which the package rests as it is designed to be displayed. The entire text of the Broad Spectrum SPF or SPF statement, as applicable, must appear in the same font style, size, and color with the same background color and must appear as continuous text with no intervening text or graphic. The entire text of the ‘‘See Skin Cancer/Skin Aging Alert’’ statement, as applicable, must appear in the same font style, size, and color with the same background color and must appear as continuous text with no intervening text or graphic. (3) Water resistance statements—(i) For products that provide 40 minutes of water resistance according to the test in paragraph (i)(8)(i) of this section. The E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules labeling states ‘‘Water Resistant (40 minutes).’’ (ii) For products that provide 80 minutes of water resistance according to the test in paragraph (i)(8)(ii) of this section. The labeling states ‘‘Water Resistant (80 minutes).’’ (iii) Prominence of water resistance statement. For all products bearing a water resistance statement, the statement must appear in boldface type at least one-quarter as large as the most prominent printed matter on the principal display panel and in lines generally parallel to the base on which the package rests as it is designed to be displayed. The entire text of the water resistance statement must appear in the same font style, size, and color with the same background color, and as continuous text with no intervening text or graphic. (c) Indications. The labeling of the product states, under the heading ‘‘Uses,’’ the phrases listed in this paragraph, as appropriate. Other truthful and nonmisleading statements, describing only the uses that have been established and listed in this paragraph, may also be used, as provided in § 330.1(c)(2) of this chapter, subject to the provisions of section 502 of the Federal Food, Drug, and Cosmetic Act relating to misbranding and the prohibition in section 301(d) of the Federal Food, Drug, and Cosmetic Act against the introduction or delivery for introduction into interstate commerce of unapproved new drugs in violation of section 505(a) of the Federal Food, Drug, and Cosmetic Act. (1) For all sunscreen products, the following indication statement must be included under the heading ‘‘Uses’’: ‘‘[bullet] helps prevent sunburn’’. See § 201.66(b)(4) for definition of bullet. (2) For sunscreen products that have been shown to pass the broad spectrum test in paragraph (j) of this section and have a determined SPF value of 15 or higher, the labeling may include the following statement in addition to the indication in paragraph (c)(1) of this section: ‘‘[bullet] if used as directed with other sun protection measures (see Directions [in bold italic font]), decreases the risk of skin cancer and early skin aging caused by the sun’’. (3) Any labeling or promotional materials that suggest or imply that the use, alone, of any sunscreen reduces the risk of or prevents skin cancer or early skin aging will cause the product to be misbranded under section 502 of the Federal Food, Drug, and Cosmetic Act (21 U.S.C. 352). (d) Warnings. The labeling of the product contains the following warnings under the heading ‘‘Warnings’’. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 (1) For all sunscreen products. (i) The labeling states ‘‘Do not use [bullet] on damaged or broken skin.’’ (ii) The labeling states ‘‘When using this product [bullet] keep out of eyes. Rinse with water to remove.’’ (iii) The labeling states ‘‘Stop use and ask a doctor if [bullet] rash occurs.’’ (2) For sunscreen products that are broad spectrum with determined SPF values of at least 2 but less than 15 according to the SPF test in paragraph (i) of this section or that have not been shown to pass the broad spectrum test in paragraph (j) of this section. The first statement under the heading ‘‘Warnings’’ states ‘‘Skin Cancer/Skin Aging Alert [in bold font]: Spending time in the sun increases your risk of skin cancer and early skin aging. This product has been shown only to help prevent sunburn, not [in bold font] skin cancer or early skin aging.’’ (3) For products in a spray dosage form that meet the definition of either the term ‘‘flammable’’ or the term ‘‘combustible’’ as defined in § 352.3(g) or (h) of this chapter, as applicable, when tested in accordance with 16 CFR 1500.43a—(i) Labeling statement. The labeling states [bullet] ‘‘Flammable’’ or ‘‘Combustible’’ (as applicable) followed by a colon and the statement ‘‘Keep away from fire or flame.’’ (ii) For products that have a drying time of less than 5 minutes. The labeling states [bullet] ‘‘Wait 5 minutes after application before approaching a source of heat or flame, or before smoking.’’ (iii) For products that have a drying time of at least 5 minutes but less than 10 minutes. The labeling states [bullet] ‘‘Wait 10 minutes after application before approaching a source of heat or flame, or before smoking.’’ (e) Directions. The labeling of the product contains the following statements, as appropriate, under the heading ‘‘Directions.’’ More detailed directions applicable to a particular product formulation may also be included. (1) For all sunscreen products. (i) As an option, the labeling may state ‘‘For sunscreen use:’’. (ii) The labeling states ‘‘[bullet] apply [select one of the following: ‘liberally’ or ‘generously’] [and, as an option: ‘and evenly’] 15 minutes before sun exposure’’. (iii) As an option, the labeling may state ‘‘[bullet] apply to all skin exposed to the sun’’. (iv) The labeling states ‘‘[bullet] children under 6 months of age: Ask a doctor’’. (2) For sunscreen products that have been shown to pass the broad spectrum test in paragraph (j) of this section and PO 00000 Frm 00063 Fmt 4701 Sfmt 4702 6265 have a determined SPF value of 15 or higher. The labeling states ‘‘[bullet] Sun Protection Measures. [in bold font] Spending time in the sun increases your risk of skin cancer and early skin aging. To decrease this risk, regularly use a sunscreen with a Broad Spectrum SPF value of 15 or higher and other sun protection measures including: [bullet] limit time in the sun, especially from 10 a.m.–2 p.m. [bullet] wear long-sleeved shirts, pants, hats, and sunglasses’’. (3) For products that satisfy the water resistance test in paragraph (i)(8) of this section. The labeling states ‘‘[bullet] reapply: [bullet] after [select one of the following determined by water resistance test: ‘40 minutes of’ or ‘80 minutes of’] swimming or sweating [bullet] immediately after towel drying [bullet] at least every 2 hours’’. (4) For products that do not satisfy the water resistance test in paragraph (i)(8) of this section. The labeling states ‘‘[bullet] reapply at least every 2 hours [bullet] use a water resistant sunscreen if swimming or sweating’’. (5) For sunscreen products in a spray dosage form. The labeling states ‘‘[bullet] Hold container 4 to 6 inches from the skin to apply. [bullet] Do not spray directly into face. Spray on hands then apply to face. [bullet] Do not apply in windy conditions. [bullet] Use in a well-ventilated area and avoid inhalation’’. (f) Other information. The labeling of the product contains the following statement under the heading ‘‘Other information:’’ ‘‘[bullet] protect the product in this container from excessive heat and direct sun’’. (g) False or misleading claims. There are claims that would be false and/or misleading on sunscreen products. These claims include but are not limited to the following: ‘‘Sunblock,’’ ‘‘sweatproof,’’ and ‘‘waterproof.’’ These or similar claims will cause the product to be misbranded under section 502 of the Federal Food, Drug, and Cosmetic Act. (h) Labeling of products containing a combination of sunscreen and skin protectant active ingredients. Statements of identity, indications, warnings, and directions for use, respectively, applicable to each ingredient in the product may be combined to eliminate duplicative words or phrases so that the resulting information is clear and understandable. Labeling provisions in § 347.50(e) of this chapter do not apply to these products. (1) Statement of identity. The statement of identity of a sunscreen product that also contains one or more skin protectant active ingredients, identified in §§ 347.10(a), (d), (e), (g), h), E:\FR\FM\26FEP2.SGM 26FEP2 6266 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules (i), (k), (l), (m), and (r) of this chapter, consists of the names of all sunscreen and skin protectant active ingredients in alphabetical order followed by ‘‘Sunscreen/Skin Protectant’’ and ‘‘[Dosage form].’’ The statement of identity must be prominently placed on the principal display panel and presented in accordance with paragraph (b)(1)(ii) of this section. (2) Indications. The labeling of the product states, under the heading ‘‘Uses,’’ any or all of the applicable indication(s) included in § 347.50(b) of this chapter or in paragraph (c) of this section. Other truthful and nonmisleading statements, describing only the indications for use that have been established in § 347.50(b) of this chapter or listed in paragraph (c) of this section, may also be used, as provided by § 330.1(c)(2) of this chapter, subject to the provisions of section 502 of the Federal Food, Drug, and Cosmetic Act relating to misbranding and the prohibition in section 301(d) of the Federal Food, Drug, and Cosmetic Act against the introduction or delivery for introduction into interstate commerce of unapproved new drugs in violation of section 505(a) of the Federal Food, Drug, and Cosmetic Act. (3) Warnings. The labeling of the product states, under the heading ‘‘Warnings,’’ the applicable warnings for sunscreens in paragraph (d) of this section and for skin protectants in § 347.50(c) of this chapter. (4) Directions. The labeling of the product states, under the heading ‘‘Directions,’’ any or all of the applicable directions for sunscreens, as set forth in paragraph (e) of this section, and for skin protectants, as set forth in §§ 347.50(d) and 347.60(d) of this chapter, unless otherwise stated in this paragraph. When the time intervals or age limitations for administration of the individual ingredients differ, the directions for the product may not contain any dosage that exceeds those established for any individual ingredient in the applicable OTC drug monograph(s), and may not provide for use by any age group lower than the highest minimum age limit established for any individual ingredient. When the directions for administration of the sunscreen and skin protectant differ in any other way, the directions for sunscreens in paragraph (e) of this section should be used. (i) Sun Protection Factor (SPF) testing—(1) Adequate clinical testing procedures and conditions—(i) General obligations of responsible persons for testing under this paragraph. Responsible persons must provide investigators and other personnel VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 engaged in SPF testing with the information they need to conduct an investigation properly; must obtain a signed investigator statement from each investigator; must ensure proper monitoring of the investigation(s); must ensure that the investigation(s) is conducted in accordance with written general investigational plan(s) and protocol(s); must ensure compliance with paragraphs (i)(1)(ii) and (iii) of this section; and must ensure that FDA and all participating investigators are promptly informed of significant new adverse effects or risks with respect to the drug. (ii) Informed consent. Effective informed consent, as defined in part 50 of this chapter, must be obtained from all human subjects before initiating clinical final formulation testing under this paragraph (i). (iii) Institutional review board (IRB) approval. Clinical testing under this paragraph (i), must be reviewed and approved by an IRB meeting the requirements of FDA’s regulations in part 56 of this chapter. (iv) Control of personnel—(A) General obligations. A responsible person is responsible for ensuring that investigators and other personnel conducting any testing under this paragraph (i), conduct all investigations in accordance with the signed investigator statement, the investigational plan, and applicable regulations. Responsible persons must ensure the implementation of adequate safeguards to protect the rights, safety, and welfare of subjects under he investigator’s care. The responsible person must also ensure that investigators or other study personnel will promptly report to the IRB all changes in the clinical final formulation testing and all unanticipated problems involving risk to human subjects or others, and that investigators or other personnel will not make any changes in the clinical final formulation testing without IRB approval, except where necessary to eliminate apparent immediate hazards to human subjects. (B) Obtaining information from the investigator. Before permitting an investigator to begin participating in clinical final formulation testing under this paragraph (i), the responsible person must obtain the following: (1) Investigator statement. A signed investigator statement containing the name and address of the investigator and a commitment by the investigator that he or she— (i) Will conduct the testing in accordance with the relevant, current protocol(s) and will only make changes in a protocol after notifying the PO 00000 Frm 00064 Fmt 4701 Sfmt 4702 responsible person and the IRB, except when necessary to protect the safety, the rights, or welfare of subjects; (ii) Will comply with all requirements regarding the obligations of clinical investigators and all other pertinent requirements in this subpart; (iii) Will personally conduct or supervise the described investigation(s); (iv) Will inform any potential subjects that the drugs are being used for investigational purposes and will comply with the requirements relating to obtaining informed consent (part 50 of this chapter) and institutional review board review and approval (part 56 of this chapter); (v) Will report to the responsible person adverse experiences that occur during the investigation(s); (vi) Will ensure that all personnel assisting in the conduct of the testing are informed about their obligations in meeting the above commitments. (2) Curriculum vitae. A curriculum vitae or other statement of qualifications of the investigator showing the education, training, and experience that qualifies the investigator to conduct the final formulation testing pursuant to this paragraph (i). (v) Informing investigators. The responsible person must, as the overall investigation proceeds, keep each participating investigator informed of new observations discovered by or reported to the responsible person on the drug, particularly with respect to adverse effects and safe use. (vi) Review of ongoing investigations. (A) The responsible person must monitor the progress of all clinical testing being conducted on its final formulation pursuant to this paragraph (i). (B) A responsible person who discovers noncompliance by an investigator or other personnel with the signed agreement, the general investigational plan, or the requirements of this paragraph (i) or other applicable regulations (e.g., parts 50 and 56 of this chapter) must promptly either secure compliance or end the investigator’s or other personnel’s participation in testing conducted under this paragraph (i). (C) The responsible person must review and evaluate the evidence relating to the safety and effectiveness of the final formulation as it is obtained from the investigator. (vii) Investigator reports—(A) Safety reports. An investigator must immediately report to the responsible person any serious adverse event, whether or not considered related to the final formulation, including those listed in the protocol, and must include an E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules TABLE 2 TO PARAGRAPH (I)(2)(I)(A)— SOLAR SIMULATOR EMISSION SPECTRUM Wavelength range (nm) <290 .................................. 290–300 ............................ 290–310 ............................ 290–320 ............................ 290–330 ............................ 290–340 ............................ 290–400 ............................ Percent erythemal contribution 1 <0.1 1.0–8.0 49.0–65.0 85.0–90.0 91.5–95.5 94.0–97.0 99.9–100.0 1 Calculation of erythema action spectrum described in paragraph (i)(2)(ii) of this section. (B) In addition, UVA II (320–340 nm) irradiance must equal or exceed 20 percent of the total UV (290–400 nm) irradiance. UVA I (340–400 nm) irradiance must equal or exceed 60 percent of the total UV irradiance. (ii) Erythema action spectrum. (A) Calculate the erythema action spectrum weighting factor (Vi) at each wavelength l: (1) Vi (l) = 1.0 (250 <l ≤298 nm) (2) Vi (l) = 100.094 * (298 ¥ l) (298 <l ≤328 nm) (3) Vi (l) = 100.015 * (140 ¥ l) (328 <l ≤400 nm) (B) Calculate the erythema-effective UV dose (E) delivered by a solar simulator as follows: Where Vi(l) = erythema action spectrum weighting factor at each wavelength l VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 I(l) = irradiance (Watts per square meter) at each wavelength l t = exposure time (seconds) Erythema-effective dose (E) is expressed as effective Joules per square meter (J/m2eff). (C) The solar simulator radiation intensity must be determined using a handheld radiometer with a response weighted to match the spectrum in ISO 17166 CIE S 007/E entitled ‘‘Erythemal reference action spectrum and standard erythema dose,’’ dated 1999 (First edition, 1999–12–15; corrected and reprinted 2000–11–15), which is incorporated by reference in accordance with 5 U.S.C. 552(a) and 1 CFR part 51. You may obtain a copy from the ISO Copyright Office, Case Postale 56, CH– 1211, Geneva 20, Switzerland, telephone +41–22–749–01–11 or fax +41–22–74–09–47. https://www.iso.org. You may inspect a copy at the Center for Drug Evaluation and Research, 10903 New Hampshire Ave., Bldg. 22, Silver Spring, MD 20993, call 301–796–2090, or at the National Archives and Records Administration (NARA). For information on the availability of this material at NARA, call 202–741–6030, or go to: https://www.archives.gov/ federal-register/cfr/ibr-locations.html. The solar simulator output should be measured before and after each phototest or, at a minimum, at the beginning and end of each test day. This radiometer should be calibrated using side-by-side comparison with the spectroradiometer (using the weighting factors determined according to paragraph (i)(2)(ii)(A) of this section) at the time of the annual spectroradiometric measurement of the solar simulator as described in paragraph (i)(2)(iv) of this section. (iii) Operation. A solar simulator must have no significant time-related fluctuations (within 20 percent) in radiation emissions after an appropriate warm-up time and demonstrate good beam uniformity (within 20 percent) in the exposure plane. The delivered dose to the UV exposure site must be within 10 percent of the expected dose. (iv) Periodic measurement. To ensure that the solar simulator delivers the appropriate spectrum of UV radiation, the emission spectrum of the solar simulator must be measured at least annually with an appropriate and accurately calibrated spectroradiometer system (results should be traceable to the National Institute for Standards and Technology). In addition, the solar simulator must be recalibrated if there is any change in the lamp bulb or the optical filtering components (i.e., filters, mirrors, lenses, collimating devices, or focusing devices). Daily solar simulator PO 00000 Frm 00065 Fmt 4701 Sfmt 4702 radiation intensity should be monitored with a broadband radiometer with a response weighted to match the erythema action spectrum in ISO 17166 CIE S 007/E entitled ‘‘Erythemal reference action spectrum and standard erythema dose,’’ which is incorporated by reference in paragraph (i)(2)(ii)(C) of this section. If a lamp must be replaced due to failure or aging during a phototest, broadband device readings consistent with those obtained for the original calibrated lamp will suffice until measurements can be performed with the spectroradiometer at the earliest possible opportunity. (3) SPF standard—(i) Preparation. The SPF standard must be a formulation containing 7-percent padimate O and 3-percent oxybenzone. TABLE 3 TO PARAGRAPH (i)(3)(i)— COMPOSITION OF THE PADIMATE O/ OXYBENZONE SPF STANDARD Ingredients Part A: Lanolin ........................... Cocoa butter .................. Glyceryl monostearate .. Stearic acid .................... Padimate O ................... Oxybenzone .................. Part B: Purified water USP ........ Sorbitol solution ............. Triethanolamine, 99 percent ............................ Methylparaben ............... Propylparaben ............... Part C: Benzyl alcohol ............... Part D: Purified water USP ........ 1 Quantity Percent by weight 4.50 2.00 3.00 2.00 7.00 3.00 71.60 5.00 1.00 0.30 0.10 0.50 QS 1 sufficient to make 100 grams. (A) Step 1. Add the ingredients of Part A into a suitable stainless steel kettle equipped with a propeller agitator. Mix at 77 to 82 °C until uniform. (B) Step 2. Add the water of Part B into a suitable stainless steel kettle equipped with a propeller agitator and begin mixing at 77 to 82 °C. Add the remaining ingredients of Part B and mix until uniform. (C) Step 3. Add the batch of Step 1 to the batch of Step 2 and mix at 77 to 82 °C until smooth and uniform. Slowly cool the batch to 49 to 54 °C. (D) Step 4. Add the benzyl alcohol of Part C to the batch of Step 3 at 49 to 54 °C. Mix until uniform. Continue to cool batch to 35 to 41 °C. (E) Step 5. Add sufficient water of Part D to the batch of Step 4 at 35 to 41 °C to obtain 100 grams of SPF standard. Mix until uniform. Cool batch to 27 to 32 °C. E:\FR\FM\26FEP2.SGM 26FEP2 EP26FE19.003</GPH> assessment of whether there is a reasonable possibility that the final formulation being tested caused the adverse event. The investigator must record nonserious adverse events and report them to the responsible person according to the timetable specified in the protocol. (B) Final report. An investigator must provide the responsible person with an adequate report shortly after completion of each investigation conducted by that investigator for the responsible person under this paragraph (i). (2) UV source (solar simulator)—(i) Emission spectrum. Filter a single port or multiport solar simulator so that it provides a continuous emission spectrum from 290 to 400 nanometers (nm) with a limit of 1,500 watts per square meter (W/m2) on total irradiance for all wavelengths between 250 and 1,400 nm. (A) The solar simulator must have the following percentage of erythemaeffective radiation in each specified range of wavelengths: 6267 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules verify the concentrations of padimate O and oxybenzone in the SPF standard: (A) Instrumentation—(1) Equilibrate a suitable liquid chromatograph to the following or equivalent conditions: (i) Column ................................................................................................................................................. (ii) Mobile Phase ...................................................................................................................................... (iii) Flow Rate ........................................................................................................................................... (iv) Temperature ....................................................................................................................................... (v) Detector .............................................................................................................................................. (vi) Attenuation ......................................................................................................................................... (2) Use HPLC grade reagents for mobile phase. (B) Preparation of the HPLC reference standard. (1) Weigh 0.5 gram (g) of oxybenzone USP reference standard into a 250-mL volumetric flask. Dissolve and dilute to volume with isopropanol. Mix well. (2) Weigh 0.5 g of padimate O USP reference standard into a 250-mL volumetric flask. Dissolve and dilute to volume with isopropanol. Mix well. (3) Pipet 3 mL of the oxybenzone solution and 7 mL of the padimate O solution into a 100-mL volumetric flask. Dilute to volume with isopropanol and mix well. (C) HPLC system suitability. (1) Make three replicate 10-microliter injections of the HPLC reference standard (described in paragraph (i)(3)(ii)(B) of (ii) The percent of oxybenzone and padimate O in the SPF standard must be between 95 and 105. (4) Test subjects—(i) Number of subjects. A test panel should include enough subjects to produce a minimum of 10 valid test results. A maximum of three subjects may be rejected from this panel based on paragraph (i)(6)(v) of this section. (ii) Medical history. (A) Obtain a medical history from each subject with emphasis on the effects of sunlight on the subject’s skin. Determine that each subject is in good general health with skin type I, II, or III as follows: (1) Always burns easily; never tans (sensitive). (2) Always burns easily; tans minimally (sensitive). (3) Burns moderately; tans gradually (light brown) (normal). (4) Burns minimally; always tans well (moderate brown) (normal). VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 this section). The relative standard deviation in peak areas should not be more than 2 percent for either oxybenzone or padimate O. (2) Calculate the resolution (R) between the oxybenzone and padimate O peaks from one chromatogram as follows: C–18, 250 millimeters (mm) length, 4.6 mm inner diameter (5 microns). 85:15:0.5 methanol: water: acetic acid. 1.5 milliliters (mL) per minute. Ambient. UV spectrophotometer at 308 nanometers. As needed. (D) SPF standard assay. (1) The SPF standard is diluted to the same concentration as the HPLC reference standard according to the following steps: (i) Step 1. Weigh 1 g of the SPF standard (described in paragraph (i)(3)(i) of this section) into a 50-mL volumetric flask. (ii) Step 2. Add approximately 30 mL of isopropanol and heat with swirling until contents are evenly dispersed. (iii) Step 3. Cool to room temperature (15 to 30 °C) and dilute to volume with isopropanol. Mix well. (iv) Step 4. Pipet 5.0 mL of the preparation into a 50-mL volumetric flask and dilute to volume with isopropanol. Mix well. (2)(i) Inject 10-microliter of diluted SPF standard from paragraph (i)(3)(ii)(D)(1) of this section and calculate the amount of oxybenzone and padimate O as follows: (5) Rarely burns; tans profusely (dark brown) (insensitive). (6) Never burns; deeply pigmented (insensitive). (B) Skin type is based on first 30 to 45 minutes of sun exposure after a winter season of no sun exposure. Determine that each subject is not taking topical or systemic medication that is known to alter responses to UV radiation. Determine that each subject has no history of sensitivities to topical products and/or abnormal responses to sunlight, such as a phototoxic or photoallergic response. (iii) Physical examination. Conduct a physical examination to determine the presence of sunburn, suntan, scars, active dermal lesions, and uneven skin tones on the areas of the back to be tested. Adequate time must have passed following any previous UV exposure (e.g., participation in a prior SPF clinical study, tanning, etc.) so that the test subject has no preexisting skin pigmentation at the time of enrollment. A suitable source of low power UVA, such as a Woods lamp, is helpful in this process. If any of these conditions are present, the subject is not qualified to participate in the study. The presence of nevi, blemishes, or moles will be acceptable if, in the physician’s judgment, they will neither compromise the study nor jeopardize a subject’s safety. Subjects with dysplastic nevi should not be enrolled. Excess hair on the back is acceptable if the hair is clipped. Shaving is unacceptable because it may remove a significant portion of the stratum corneum and temporarily alter the skin’s response to UV radiation. (iv) Informed consent. Obtain legally effective written informed consent from all test subjects as required by paragraph (i)(1)(ii) of this section. Where to = retention time for oxybenzone tp = retention time for padimate O Wo = oxybenzone peak width at baseline Wp = padimate O peak width at baseline If the resolution (R) is less than 3, adjust the mobile phase or replace the column. PO 00000 Frm 00066 Fmt 4701 Sfmt 4702 E:\FR\FM\26FEP2.SGM 26FEP2 EP26FE19.005</GPH> (ii) HPLC assay. Use the following high performance liquid chromatography (HPLC) procedure to EP26FE19.004</GPH> 6268 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 PO 00000 Frm 00067 Fmt 4701 Sfmt 4702 doses administered; or the subject was noncompliant (e.g., the subject withdraws from the test due to illness or work conflicts or does not shield the exposed testing sites from further UV radiation until the MED is determined). (7) Determination of SPF. (i) Calculate an SPF value for each test subject (SPFi) as follows: (ii) Calculate the mean In order for the SPF determination of a test product to be considered valid, the SPF value of the SPF standard must fall within the standard deviation range of the expected SPF (i.e., 16.3 ± 3.43). (8) Determination of water resistance. To support labeling claims of water resistance in accordance with paragraph (b) of this section, the following procedure must be performed in an indoor fresh water pool, whirlpool, and/ or hot tub maintained at 23 to 32 °C. Fresh water is clean drinking water that meets the standards in 40 CFR part 141. The pool and air temperature and the relative humidity must be recorded. (i) Water resistance (40 minutes). Determine the SPF value after 40 minutes of water immersion using the following procedure: (A) Step 1: Apply the sunscreen test product as described in paragraph (i)(5) of this section. (B) Step 2: Perform moderate activity in water for 20 minutes. (C) Step 3: Rest out of water for 15 minutes. Do not towel test site(s). (D) Step 4: Perform moderate activity in water for 20 minutes. (E) Step 5: Allow test sites to dry completely without toweling. (F) Step 6: Apply the SPF standard as described in paragraph (i)(5) of this section. (G) Step 7: Expose test sites to UV doses as described in paragraph (i)(6) of this section. (ii) Water resistance (80 minutes). Determine the SPF value after 80 minutes of water immersion using the following procedure: E:\FR\FM\26FEP2.SGM 26FEP2 EP26FE19.008</GPH> and the standard deviation(s) from the SPFi values. Calculate the standard error (SE), which equals s/√n (where n equals the number of subjects who provided valid test results). Obtain the t value from Student’s t distribution table corresponding to the upper 5-percent point with n ¥ 1 degrees of freedom. Determine the SPF value that is equal to the largest whole number less than EP26FE19.007</GPH> using an accurately calibrated solar simulator. Select doses that are a geometric series represented by 1.25n (i.e., each dose is 25 percent greater than the previous dose). (iii) UV exposure for final MEDu, ssMEDp, and tpMEDp. For each subject, determine the final MEDu, ssMEDp, and tpMEDp by administering a series of five UV doses to the appropriate test sites. The middle dose (X) in each of these dose series (i.e., the third dose) should equal the initial MEDu times the expected SPF. Note that the expected SPF equals 1 and 16.3 for the final MEDu and ssMEDp, respectively. The remaining UV doses in the series depend upon the expected SPF value of the sunscreen test product(s). For products with an expected SPF less than 8, administer UV doses that increase by 25 percent with each successive dose (i.e., 0.64X, 0.80X, 1.00X, 1.25X, and 1.56X). For products with an expected SPF from 8 to 15, administer UV doses that increase by 20 percent with each successive dose (i.e., 0.69X, 0.83X, 1.00X, 1.20X, and 1.44X). For products with an expected SPF higher than 15, administer UV doses that increase by 15 percent with each successive dose (i.e., 0.76X, 0.87X, 1.00X, 1.15X, and 1.32X). (iv) Evaluation of test subsites. In order that the study personnel who evaluates the test subsites is not biased, he/she should not be the same study personnel who applied the sunscreen product to the test site or administered the UV doses. After UV doses are administered, record all immediate responses. These may include an immediate darkening or tanning, typically grayish or purplish in color, which fades in 30 to 60 minutes; an immediate reddening at the subsite, due to heating of the skin, which fades rapidly; and an immediate generalized heat response, spreading beyond the subsite, which fades in 30 to 60 minutes. After the immediate responses are noted, each subject should shield the exposed area from further UV radiation until the MED is determined. Determine the final MEDu, ssMEDp, and tpMEDp 16 to 24 hours after UV exposure. Evaluate the erythema responses of each test subsite using either tungsten or warm white fluorescent lighting that provides at least 450 lux of illumination at the test site. For the evaluation, the test subject should be in the same position as when the test site was irradiated. (v) Invalid test data. Reject test data for a test subject if erythema is not present on either the unprotected or protected test sites; or erythema is present at all subsites; or the responses are inconsistent with the series of UV EP26FE19.006</GPH> (5) Sunscreen application—(i) Test site. Test sites are locations on each subject’s back, between the beltline and the shoulder blades (scapulae) and lateral to the midline, where skin responses to UV radiation are determined. Responses on unprotected skin (no test material applied) and protected skin (sunscreen test product(s) or SPF standard applied) are determined at separate unprotected and protected test sites, respectively. Test sites should be randomly located in a blinded manner. Each test site should be a minimum of 30 square centimeters and outlined with indelible ink. (ii) Test subsite. Test subsites are the locations to which UV radiation is administered within a test site. Administer UV doses to at least five test subsites within each test site. Test subsites must be at least 0.5 square centimeters (cm2) in area and must be separated from each other by at least 0.8 cm. Each test subsite must be outlined with indelible ink. (iii) Applying test materials. Apply the sunscreen test product and the SPF standard at 2 milligrams per square centimeter (mg/cm2) to their respective test sites. Use a finger cot compatible with the sunscreen to spread the product as evenly as possible. (iv) Waiting period. Wait at least 15 minutes after applying a sunscreen product before exposing the test sites to UV radiation as described in paragraph (i)(6) of this section. For water resistant sunscreen products, proceed with the water resistance testing procedure described in paragraph (i)(8) of this section after waiting at least 15 minutes. (6) UV exposure and erythema reading—(i) Definition of minimal erythema dose (MED). The minimal erythema dose (MED) is the smallest UV dose (quantity of erythema-effective energy expressed as Joules per square meter) that produces perceptible redness of the skin (erythema) with clearly defined borders at 16 to 24 hours after UV exposure. The MED for unprotected skin (MEDu) is determined on a test site that does not have sunscreen applied. The MED for protected skin (MEDp) is determined on a test site that has sunscreen applied. An MEDp is determined for the SPF standard (ssMEDp). An MEDp is determined for the sunscreen test product (tpMEDp). (ii) UV exposure for initial MEDu. For each test subject, no more than 1 day before testing a product, determine the initial MEDu by administering a series of UV radiation doses expressed as J/m2-eff (as determined according to paragraph (i)(2)(ii)(B) of this section) to the test subsites within an unprotected test site 6269 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 Frm 00068 are converted into mean absorbance values, at each wavelength by taking the negative logarithm of the mean transmittance value as follows: (ii) The calculation yields 111 monochromatic absorbance values in 1 nanometer increments from 290 to 400 nanometers. (6) Number of plates. For each sunscreen product, determine mean absorbance values from at least three individual PMMA plates. Because paragraph (j)(4) of this section requires at least 5 measurements per plate, there must be a total of at least 15 measurements. (7) Calculation of the critical wavelength. The critical wavelength is identified as the wavelength at which the integral of the spectral absorbance curve reaches 90 percent of the integral over the UV spectrum from 290 to 400 nm. The following equation defines the critical wavelength: Fmt 4701 Sfmt 4702 E:\FR\FM\26FEP2.SGM 26FEP2 EP26FE19.013</GPH> Where A(l) = effective absorbance given as -log T(l)mean absorbance at each wavelength, d(l) = wavelength interval between measurements B(l) = any biological action spectrum factor Because no appropriate biological action spectrum for UVA radiation damage has been universally accepted, no action spectrum is specified. The value of B(l) is, therefore, equal to 1.0 for all wavelengths. EP26FE19.012</GPH> (8) Calculation of the UVA I/UV ratio. The ratio of UVA I/UV is calculated as the area (per unit wavelength) under the UVA I portions of a plot of wavelength versus A(l), divided by the area (per unit wavelength) under the total curve, as follows: EP26FE19.014</GPH> Where lc = critical wavelength A(l) = mean absorbance at each wavelength dl = wavelength interval between measurements (9) Determination of broad spectrum protection. A product that has both a mean critical wavelength of 370 nm or Where n ≥5 PO 00000 (5) Calculation of mean absorbance values. (i) Mean transmittance values, EP26FE19.011</GPH> (v) Dynamic range of the spectrometer. The dynamic range of the spectrometer should be sufficient to measure transmittance accurately through a highly absorbing sunscreen product at all terrestrial solar UV wavelengths (290 to 400 nm). (2) Sunscreen product application to PMMA plate. The accuracy of the test depends upon the application of a precisely controlled amount of sunscreen product with a uniform distribution over the PMMA plate. The product is applied at 0.75 mg per square centimeter to the roughened side of the PMMA plate. The sunscreen product should be applied in a series of small amounts over the entire PMMA plate and then spread evenly using a gloved finger. Spreading should be done with a very light spreading action for approximately 30 seconds followed by spreading with greater pressure for approximately 30 seconds. The plate should then be allowed to equilibrate for 15 minutes in the dark before the pre-irradiation described in paragraph (j)(3) of this section. (3) Sunscreen product pre-irradiation. To account for lack of photostability, irradiate the PMMA plate with a solar simulator described paragraph (i)(2) of this section. The irradiation dose must be 4 MEDs which is equivalent to an erythemal effective dose of 800 J/m2 (i.e., 800 J/m2-eff). (4) Calculation of mean transmittance values. (i) After pre-irradiation, determine the mean transmittance values for each wavelength l over the full UV spectrum (290 to 400 nanometers). Measure the transmittance values at 1 nanometer intervals. Measurements of spectral irradiance transmitted for each wavelength l through control PMMA plates coated with 15 microliters of glycerin (no sunscreen product) must be obtained from at least five different locations on the PMMA plate [C1(l), C2(l), C3(l), C4(l), and C5(l)]. In addition, a minimum of five measurements of spectral irradiance transmitted for each wavelength l through the PMMA plate covered with the sunscreen product will be similarly obtained after preirradiation of the sunscreen product [P1(l), P2(l), P3(l), P4(l), and P5(l)]. (ii) The mean transmittance for each wavelength is the ratio of the mean of the C(l) values to the mean of the P(l) values, as follows: EP26FE19.010</GPH> (A) Step 1: Apply the sunscreen test product as described in paragraph (i)(5) of this section. (B) Step 2: Perform moderate activity in water for 20 minutes. (C) Step 3: Rest out of water for 15 minutes. Do not towel test site(s). (D) Step 4: Perform moderate activity in water for 20 minutes. (E) Step 5: Rest out of water for 15 minutes. Do not towel test site(s). (F) Step 6: Perform moderate activity in water for 20 minutes. (G) Step 7: Rest out of water for 15 minutes. Do not towel test site(s). (H) Step 8: Perform moderate activity in water for 20 minutes. (I) Step 9: Allow test sites to dry completely without toweling. (J) Step 10: Apply the SPF standard as described in paragraph (i)(5) of this section. (K) Step 11: Expose test sites to UV doses as described in paragraph (i)(6) of this section. (j) Broad spectrum testing—(1) UV Spectrometry—(i) Plate. Use opticalgrade polymethylmethacrylate (PMMA) plates suitable for UV transmittance measurements. The plate should be roughened on one side to a threedimensional surface topography measure (Sa) between 2 and 7 micrometers and must have a rectangular application area of at least 16 square centimeters (with no side shorter than 4 cm). (ii) Sample holder. The sample holder should hold the PMMA plate in a horizontal position to avoid flowing of the sunscreen product from one edge of the PMMA plate to the other. Mount the PMMA plate as close as possible to the input optics of the spectrometer to maximize capture of forward scattered radiation. The sample holder should be a thin, flat plate with a suitable aperture through which UV radiation can pass. Place the PMMA plate on the upper surface of the sample holder with the roughened side facing up. (iii) Light source. The light source must produce a continuous spectral distribution of UV radiation from 290 to 400 nanometers. (iv) Input optics. Unless the spectrometer is equipped with an integrating sphere, an ultraviolet radiation diffuser should be placed between the sample and the input optics of the spectrometer. The diffuser will be constructed from any UV radiation transparent material (e.g., Teflon or quartz). The diffuser ensures that the radiation received by the spectrometer is not collimated. Set the spectrometer input slits to provide a bandwidth that is less than or equal to 5 nanometers. EP26FE19.009</GPH> 6270 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules greater, calculated in accordance with paragraph (j)(7) of this section, and a mean UVA I/UV ratio of 0.70 or greater, calculated in accordance with paragraph (j)(8) of this section, is determined to pass the broad spectrum test. (k) Regulatory status of final formulation testing and related requirements. Final formulation testing required under this section is considered a part of the manufacture of a sunscreen product. Therefore, final formulation testing required under this section must be performed in an establishment registered in accordance with part 207 of this chapter and section 510 of the Federal Food, Drug, and Cosmetic Act. Entities conducting final formulation testing required by this section must also comply with current good manufacturing practices (CGMPs) and associated recordkeeping requirements including those set forth in paragraph (l) of this section and in parts 210 and 211 of this chapter. Failure to comply with CGMPs or recordkeeping requirements will mean that any product labeled in reliance on that testing will be adulterated. (l) Recordkeeping. Records required to be kept under this section must be maintained for at least 1 year after the expiration date of all products labeled in reliance on that testing or, in the case of certain OTC drug products lacking expiration dating because they meet the criteria for exemption under § 211.137 of this chapter, 3 years after distribution of the last lot of drug product bearing labeling that relies on the testing. Recordkeeping requirements under this section may not be transferred. Maintenance records required to be kept under (l)(1) must be kept by the testing entity. Records of final formulation testing as described in paragraphs (l)(2) and (3) of this section must be kept by the responsible person and any entity that is performing final formulation testing required by this section on behalf of a responsible person pursuant to a transfer of obligations. (1) Maintenance records. Entities performing final formulation testing are expected to maintain equipment in accordance with paragraph (k) of this section and, as applicable, parts 210 and 211 of this chapter. Maintenance records must be kept for all equipment used for final formulation testing under this section and must include: (i) Documentation that equipment has been maintained in accordance with established written specifications as required by paragraph (k) of this section and parts 210 and 211 of this chapter; and (ii) Documentation of characterization of UV sources including: VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 (A) Record of emission spectrum, total irradiance, and percent of erythemaeffective radiation contribution required by paragraph (i)(2)(i) of this section; (B) Record of each periodic measurement required by paragraph (i)(2)(iv) of this section for each solar simulator; (C) Record of each calibration, realignment, or change in components of each solar simulator, or any changes to the broadband radiometer (or UV meter/dose control system), required by paragraph (i)(2)(iv) of this section; and (D) Record of each solar simulator output measurement required by paragraph (i)(2)(ii)(C) of this section. (2) SPF testing records. In addition to any records required to be kept pursuant to parts 210 and 211 of this chapter, records of SPF testing performed pursuant to paragraph (i) of this section must include: (i) Identification of the entity that conducted the final formulation testing, including the name and address of the establishment(s) at which testing was carried out; (ii) The sunscreen test product identifier and characterization of the formulation being tested, including lot number, manufacture date, and expected SPF; (iii) Characterization of the SPF standard sunscreen required by paragraph (i)(3) of this section, including: (A) Lot number; (B) Manufacturing date; and (C) Results of HPLC SPF standard assay that verify compliance with the concentrations of padimate O and oxybenzone in the SPF standard. (iv) Documentation linking any blinded samples with the product identifier. (v) For each human subject, records of: (A) The identification of the UV source used for testing on that subject, including make, model, and serial number; (B) Initial and final individual MED for unprotected skin (MEDu), and the identity of the study personnel who determined that value; (C) Final MED for sunscreen test product protected skin (tpMEDp), and the identity of the study personnel who determined that value; (D) Final MED for SPF standard sunscreen protected skin (ssMEDp), and the identity of the study personnel who determined that value; and (E) Individual SPFi values, including all valid test data and invalid test data for the test product and for the SPF standard sunscreen, and the identity of the study personnel who determined that value. PO 00000 Frm 00069 Fmt 4701 Sfmt 4702 6271 (vi) Records of the mean and standard deviation from SPFi values, standard error, and determined SPF value derived as set forth in paragraph (i)(7) of this section. (vii) Records for water resistance testing of pool temperature, air temperature, and relative humidity as required by paragraph (i)(8) of this section. (viii) Records demonstrating compliance with paragraph (i)(1) of this section governing the establishment of adequate clinical testing procedures and conditions, including, but not limited to: (A) Case histories. Responsible persons are required to prepare and maintain adequate and accurate case histories on each individual participant enrolled in SPF testing performed under paragraph (i) of this section. Case histories must record all observations and other data pertinent to the investigation. Case histories include the case report forms and supporting data (for example, signed and dated consent forms, medical records including progress notes of the physician, the individual’s hospital chart(s), and the nurses’ notes (if applicable)). The case history for each individual participant must document that informed consent was obtained pursuant to part 50 before each individual’s participation in the study. Case histories as required by this section must include: (1) Protocol deviations or injuries, if any; and (2) Identification, by subject, of the study personnel who: Examined the potential study site areas, who weighed and applied the sunscreen, and who provided the UV irradiation. (B) IRB review. Documentation that clinical research conducted pursuant to paragraph (i) of this section was reviewed and approved by a registered IRB as required by paragraph (i)(1)(iii) of this section. (3) Broad spectrum testing records. Records of broad spectrum testing conducted pursuant to paragraph (j) of this section must include: (i) Identification of the entity that conducted the final formulation testing, including the name and address of the establishment(s) at which testing was carried out; (ii) Records of sample information, including: (A) A sunscreen test product identifier and expected SPF. If the samples used in testing under paragraph (j) of this section are blinded, then records must include a master key that enables samples to be re-identified. In all other cases, records must include a E:\FR\FM\26FEP2.SGM 26FEP2 6272 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules master key that links samples used to a sunscreen test product identifier. (B) Sample number; (C) Identifier code; (D) Measurement of PMMA plate surface topography in micrometers; and (E) Sample holder orientation (vertical or horizontal). (iii) Identification of each UV source used for sunscreen product preirradiation, including make, model, and serial number. (iv) Records of sunscreen product application, including: (A) A record of all sample weights, including analytical balance; and (B) For all equipment used; make, model, and serial number; (v) For each sample, all measurements required by paragraphs (j)(4) to (6) of this section. (vi) For each sample, records of critical wavelength and the UVA I/UV ratio values required by paragraphs (j)(7) and (8) of this section. (vii) For each sample: The identity of the study personnel who weighed and applied the sunscreen to the PMMA plates; the identity of the study personnel who provided the preirradiation; and the identity of the study personnel, or, if calculated by software, what software, calculated the mean transmittance, mean absorbance values, critical wavelength, and UVA I/UV. (viii) For each sample, the test dates for the broad spectrum test conducted pursuant to paragraph (j) of this section, and sample report forms and supporting data including, for example, spectral data, Excel files containing transmittance or absorbance values, or any notes from the lab investigator. (4) Food and Drug Administration (FDA) inspection of records—(i) Testing entity. Anentity performing final formulation testing under this section, including a responsible person or an entity that has been transferred any obligations of a responsible person under this section, must, upon request from any properly authorized officer or employee of FDA, at reasonable times, permit such officer or employee to have access to, and copy and verify any records or reports of testing pursuant to this section. The testing entity is not required to divulge subject names unless the records of particular individuals require a more detailed study of the cases, or unless there is reason to believe that the records do not represent actual case studies, or do not represent actual results obtained. (ii) Responsible persons. A responsible person must upon request from any properly authorized officer or employee of FDA, at reasonable times, permit such officer or employee to have VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 access to and copy and verify any records and reports relating to final formulation testing conducted under this section. Upon written request by FDA, the responsible person must submit the records or reports (or copies of them) to FDA. The responsible person must discontinue from further participation in final formulation testing required by this section any investigator who has failed to maintain or make available records or reports of the investigation as required by this paragraph (l). PART 310—NEW DRUGS 3. The authority citation for part 310 continues to read as follows: ■ Authority: 21 U.S.C. 321, 331, 351, 352, 353, 355, 360b–360f, 360j, 360hh–360ss, 361(a), 371, 374, 375, 379e, 379k–l; 42 U.S.C. 216, 241, 242(a), 262. § 310.545 [Amended] 4. Amend § 310.545 by removing and reserving paragraphs (a)(29) and (d)(31),and (40). ■ 5. Add § 310.549 to subpart E to read as follows: ■ § 310.549 Drug products offered over-thecounter (OTC) for use as sunscreen. (a) Any drug product offered OTC for use as sunscreen and identified in any of paragraphs (b) through (i) of this section is not generally recognized as safe and effective and is regarded as a new drug within the meaning of section 201(p) of the Federal Food, Drug, and Cosmetic Act, for which an approved new drug application under section 505 of the Federal Food, Drug, and Cosmetic Act and part 314 of this chapter is required for marketing. In the absence of an approved new drug application, such product is also misbranded under section 502 of the Federal Food, Drug, and Cosmetic Act. Products offered OTC for use as sunscreen include those represented, labeled, or promoted as sunscreen, or for use to help prevent sunburn, skin cancer, and/or skin aging caused by the sun, or with similar claims or representations. Clinical investigations designed to obtain evidence that any sunscreen drug product covered by this section is safe and effective for the purpose intended must comply with the requirements and procedures governing the use of investigational new drugs set forth in part 312 of this chapter. (b) A sunscreen drug product that contains any of the following ingredients: (1) Diethanolamine methoxycinnamate (2) Digalloyl trioleate PO 00000 Frm 00070 Fmt 4701 Sfmt 4702 (3) Ethyl 4-[bis(hydroxypropyl)] aminobenzoate (4) Glyceryl aminobenzoate (5) Lawsone with dihydroxyacetone (6) Red petrolatum (7) Trolamine salicylate (8) Aminobenzoic acid (9) Avobenzone (10) Cinoxate (11) Dioxybenzone (12) Ensulizole (13) Homosalate (14) Meradimate (15) Octinoxate (16) Octisalate (17) Octocrylene (18) Oxybenzone (19) Padimate O (20) Sulisobenzone (c) A sunscreen drug product that has a determined sun protection factor (SPF) value, as defined in § 352.3(d) of this chapter, of at least 15 when tested in accordance with § 201.327(i) of this chapter, but that has not been shown to pass the broad spectrum test in § 201.327(j) of this chapter. (d) A sunscreen drug product that has a determined sun protection factor (SPF) value, as defined in § 352.3(d) of this chapter, of less than 2 or greater than 80 when tested in accordance with § 201.327(i) of this chapter. (e) A sunscreen drug product that has a determined sun protection factor (SPF) value, as defined in § 352.3(d) of this chapter, of less than 15 when tested in accordance with § 201.327(i) of this chapter and/or that does not pass the broad spectrum test in § 201.327(j) of this chapter, and labeled with any of the following or similar claims: (1) Decreases the risk of skin cancer caused by the sun; or (2) Decreases the risk of early skin aging caused by the sun. (f) A sunscreen drug product labeled with any of the following or similar claims: (1) Instant protection or protection immediately upon application; or (2) Claims for ‘‘all-day’’ protection or extended wear claims citing a specific number of hours of protection that is inconsistent with the directions for application in § 201.327 of this chapter. (g) A sunscreen drug product that is labeled, represented, or promoted for use as a combined sunscreen-insect repellant. (h) A sunscreen drug product that is in any dosage form other than the following: Oil, lotion, cream, gel, butter, paste, ointment, stick, or spray. (i) A sunscreen drug product in a spray dosage form that has any of the following properties: (1) The product meets the definition of the term ‘‘extremely flammable’’ as E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules defined at § 352.3(f) of this chapter when tested in accordance with 16 CFR 1500.43a; (2) More than 10 percent of the particles dispensed from the consumer container are smaller than 10 micrometers; (3) Any of the particles dispensed from the consumer container are smaller than 5 micrometers; or (4) The product meets the definition of either the term ‘‘flammable’’ or the term ‘‘combustible’’ as defined at §§ 352.3(g) or (h) of this chapter, as applicable, when tested in accordance with 16 CFR 1500.43a and has a measured drying time of 10 minutes or more. PART 347—SKIN PROTECTANT DRUG PRODUCTS FOR OVER-THECOUNTER HUMAN USE 6. The authority citation for part 347 continues to read as follows: ■ Authority: 21 U.S.C. 321, 351, 352, 353, 355, 360, 371. 7. Amend § 347.20 by lifting the stay on paragraph (e) (previously paragraph (d), redesignated at 74 FR 9765, March 6, 2009) and revising paragraph (e) to read as follows: ■ § 347.20 Permitted combinations of active ingredients. * * * * * (e) Combinations of skin protectant and sunscreen active ingredients. Any one (two when required to be in combination) or more of the skin protectant active ingredients identified in § 347.10(a), (d), (e), (g), (h), (i), (k), (l), (m), and (r) of this chapter may be combined with any single sunscreen active ingredient identified in § 352.10 of this chapter, or any permitted combination of these ingredients identified in § 352.20 of this chapter, provided the product meets the conditions in § 352.20(b) of this chapter and is labeled according to §§ 347.60 and 352.60 of this chapter. ■ 8. Amend § 347.60 by revising paragraphs (a), (b)(3), (c)(1), and (d)(1) to read as follows: § 347.60 Labeling of permitted combinations of active ingredients. * * * * * (a) Statement of identity. (1) Except as set forth in paragraph (a)(3) of this section, for a combination drug product that has an established name, the labeling of the product states the established name of the combination drug product, followed by the statement of identity for each ingredient in the combination, as established in the statement of identity sections of the applicable OTC drug monographs. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 (2) Except as set forth in paragraph (a)(3) of this section, for a combination drug product that does not have an established name, the labeling of the product states the statement of identity for each ingredient in the combination, as established in the statement of identity sections of the applicable OTC drug monographs. (3) For a product containing a combination of skin protectant and sunscreen active ingredients, the labeling of the product bears the statement of identity set forth in § 352.60(a) of this chapter. (b) * * * (3) Combinations of skin protectant and sunscreen active ingredients in § 347.20(e). In addition to any or all of the indications for skin protectant drug products in § 347.50(b)(2)(i) of this chapter, the required indications for sunscreen drug products in § 352.60(b) of this chapter must be used and any or all of the additional indications for sunscreen drug products may be used. (c) * * * (1) For combinations containing a skin protectant and a sunscreen identified in §§ 347.20(e) and 352.20(b). The warnings in § 352.60(c) of this chapter are used. * * * * * (d) * * * (1) For combinations containing a skin protectant and a sunscreen identified in §§ 347.20(e) and 352.20(b). The directions in § 352.60(d) of this chapter are used. * * * * * PART 352—SUNSCREEN DRUG PRODUCTS FOR OVER-THECOUNTER HUMAN USE 9. The authority citation for part 352 continues to read as follows: ■ Authority: 21 U.S.C. 321, 351, 352, 353, 355, 360, 371. ■ 10. Lift the stay of 21 CFR part 352. § 352.1 [Amended] 11. In paragraph (a), remove the words ‘‘in a form suitable for topical administration’’. ■ 12. Revise § 352.3 to read as follows: ■ § 352.3 Definitions. As used in this part: (a) [Reserved] (b) [Reserved] (c) Sunscreen active ingredient. An active ingredient listed in § 352.10 that absorbs, reflects, or scatters radiation in the ultraviolet (UV) range at wavelengths from 290 to 400 nanometers. (d) Determined sun protection factor (SPF) value. The SPF value that equals PO 00000 Frm 00071 Fmt 4701 Sfmt 4702 6273 the largest whole number less than SPF ¥ (t * SE), determined for a sunscreen product in accordance with § 201.327(i) of this chapter. (e) Labeled sun protection factor (SPF) value. The SPF value associated with the range into which the determined SPF value falls, as set forth in the table in § 201.327(b)(2)(i) of this chapter. (f) Extremely flammable. The term ‘‘extremely flammable’’ applies to any product that has a flashpoint at or below 20 °F (¥6.7 °C) as determined by the test method described at 16 CFR 1500.43a, except that any product having one component or more with a flashpoint higher than 20 °F (¥6.7 °C) that comprises at least 99 percent of the total volume of the product is not considered to be extremely flammable. (g) Flammable. The term ‘‘flammable’’ applies to any product that has a flashpoint above 20 °F (¥6.7 °C) and below 100 °F (37.8 °C) as determined by the test method described at 16 CFR 1500.43a, except that: (1) Any product having one component or more with a flashpoint at or above 100 °F (37.8 °C) that comprises at least 99 percent of the total volume of the product is not considered to be flammable; and (2) Any product containing 24 percent or less of water miscible alcohols, by volume, in aqueous solution is not considered to be flammable if the product does not present a significant flammability hazard when used by consumers. (h) Combustible. The term ‘‘combustible’’ applies to any product having a flashpoint at or above 100 °F (37.8 °C) to and including 150 °F (65.6 °C) as determined by the test method described at 16 CFR 1500.43a, except that: (1) Any product having one component or more with a flashpoint higher than 150 °F (65.6 °C) that comprises at least 99 percent of the total volume of the product is not considered to be combustible; and (2) Any product containing 24 percent or less of water miscible alcohols, by volume, in aqueous solution is not considered to be combustible if the product does not present a significant flammability hazard when used by consumers. ■ 13. Add § 352.5 to subpart A to read as follows: § 352.5 Sun protection factor related conditions. (a) The product has a determined SPF value of at least 2 but no greater than 80. (b) If the product has a determined SPF value of at least 15, it also passes E:\FR\FM\26FEP2.SGM 26FEP2 6274 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules the broad spectrum test in § 201.327(j) of this chapter. ■ 14. Revise § 352.10 to read as follows: § 352.10 Sunscreen active ingredients. The active ingredient of the product consists of any of the following, under the conditions specified, including being within the concentration specified for each ingredient: (a) through (o) [Reserved] (p) Titanium dioxide up to 25 percent (q) [Reserved] (r) Zinc oxide up to 25 percent. ■ 15. Revise § 352.20 to read as follows: § 352.20 Permitted combinations of active ingredients. The determined SPF of any product containing a sunscreen active ingredient is measured by the testing procedures established in § 201.327(i) of this chapter. (a) Combinations of sunscreen active ingredients. Two or more sunscreen active ingredients identified in § 352.10 may be combined with each other in a single sunscreen product if all of the following conditions are met: (1) Each sunscreen active ingredient in the product must satisfy the conditions established for its use in § 352.10. (2) The concentration of each sunscreen active ingredient must be sufficient to contribute a minimum determined SPF of not less than 2 to the finished product. (3) The finished product must have a minimum determined SPF of not less than the number of sunscreen active ingredients used in the product multiplied by 2. (b) Combinations of sunscreen and skin protectant active ingredients. Any single sunscreen active ingredient identified in § 352.10 or any combination of sunscreen active ingredients permitted under paragraph (a) of this section may be combined with one or more skin protectant active ingredients identified in §§ 347.10(a), (d), (e), (g), (h), (i), (k), (l), (m), and (r) of this chapter when all of the following conditions are met: (1) Each sunscreen active ingredient in the product must satisfy the conditions established for its use in § 352.10. (2) The concentration of each sunscreen active ingredient must be sufficient to contribute a minimum determined SPF of not less than 2 to the finished product. (3) The finished product must have a minimum determined SPF of not less than the number of sunscreen active ingredients used in the product multiplied by 2. VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 (4) The product must be labeled according to § 201.327(h) of this chapter and § 352.60. (c) [Reserved] ■ 16. Add § 352.30 to subpart B to read as follows: when tested accordance with 16 CFR 1500.43a, drying time for each lot of product must be conducted in accordance with adequate written specifications. ■ 18. Revise § 352.50 to read as follows: § 352.30 § 352.50 Principal display panel of all sunscreen drug products. Route of administration. The product is intended for topical administration. ■ 17. Add § 352.40 to subpart B to read as follows: § 352.40 Dosage forms. The product is in one of the following dosage forms and meets any additional conditions specified: (a) Oil. (b) Lotion. (c) Cream. (d) Gel. (e) Butter. (f) Paste. (g) Ointment. (h) Stick. (i) Spray, provided that all of the following conditions are satisfied: (1) Size of particles as dispensed from the consumer container: (i) No more than 10 percent of the particles dispensed from the consumer container are smaller than 10 micrometers; and (ii) None of the particles dispensed from the consumer container are smaller than 5 micrometers. (2) The product does not meet the definition of the term ‘‘extremely flammable’’ as defined in § 352.3(f). (3) If the product meets the definition of either the term ‘‘flammable’’ or the term ‘‘combustible’’ as defined at §§ 352.3(g) or (h), as applicable, when tested in accordance with 16 CFR 1500.43a, the product also has a measured drying time of less than 10 minutes. (4) The product is labeled as required by §§ 201.327(d) and (e)(5) of this chapter. (5) Testing in accordance with part 211 of this chapter must confirm that the product meets the conditions for particle size, flammability, and drying time as required by this section and reflected in the product labeling. (i) Testing of each lot of product for size of particles dispensed from the consumer container must be conducted in accordance with adequate written specifications. (ii) Flammability testing for each batch of product must be conducted in accordance with the specifications set forth in 16 CFR 1500.43a. (iii) If the product meets the definition of either the term ‘‘flammable’’ or ‘‘combustible’’ as defined at § 352(g) or (h), as applicable, PO 00000 Frm 00072 Fmt 4701 Sfmt 4702 The principal display panel labeling must comply with § 201.327(b) of this chapter. ■ 19. Revise § 352.52 to read as follows: § 352.52 Labeling of products containing one or more sunscreen active ingredients. (a) Statement of identity. The labeling of the product contains the statement of identity, in accordance with § 201.327(b) of this chapter. (b) Indications. The labeling of the product contains the indication statements identified in § 201.327(c) of this chapter, as appropriate, and subject to the conditions stated therein. (c) Warnings. The labeling of the product contains the warnings in § 201.327(d) of this chapter, as applicable, under the heading ‘‘Warnings:’’ (d) Directions. The labeling of the product contains the statements in § 201.327(e) of this chapter, as applicable, under the heading ‘‘Directions.’’ (e) Other information. The labeling of the product contains the statement in § 201.327(f) of this chapter under the heading ‘‘Other information.’’ (f) False or misleading claims. The labeling of the product must not contain any claims that would be false and/or misleading on sunscreen products, as outlined in § 201.327(g) of this chapter. ■ 20. Revise § 352.60 to read as follows: § 352.60 Labeling of products containing a combination of sunscreen and skin protectant active ingredients. Statements of identity, indications, warnings, and directions for use, respectively, applicable to each ingredient in the product may be combined to eliminate duplicative words or phrases so that the resulting information is clear and understandable. Labeling provisions in § 347.50(e) of this chapter shall not apply to these products. (a) Statement of identity. The labeling of the product bears the statement of identity, as set forth in § 201.327(h)(1) of this chapter. (b) Indications. The labeling of the product states, under the heading ‘‘Uses,’’ the applicable indication statements, as set forth in § 201.327(h)(2) of this chapter. (c) Warnings. The labeling of the product states, under the heading E:\FR\FM\26FEP2.SGM 26FEP2 Federal Register / Vol. 84, No. 38 / Tuesday, February 26, 2019 / Proposed Rules ‘‘Warnings,’’ the applicable warning statements, as set forth in § 201.327(h)(3) of this chapter. (d) Directions. The labeling of the product states, under the heading ‘‘Directions,’’ the applicable direction statements, as set forth in § 201.327(h)(4) of this chapter. ■ 21. Revise subpart D to read as follows: VerDate Sep<11>2014 17:34 Feb 25, 2019 Jkt 247001 6275 Subpart D—Final Formulation Testing § 352.80 Sec. 352.70 352.80 If the product’s determined SPF value is at least 15, the product is tested and shown to pass the broad spectrum test in § 201.327(j) of this chapter. SPF testing. Broad spectrum testing. Subpart D—Final Formulation Testing § 352.70 SPF testing. The product is tested in accordance with § 201.327(i) of this chapter. PO 00000 Frm 00073 Fmt 4701 Sfmt 9990 Broad spectrum testing. Dated: February 14, 2019. Scott Gottlieb, Commissioner of Food and Drugs. [FR Doc. 2019–03019 Filed 2–21–19; 8:45 am] BILLING CODE 4164–01–P E:\FR\FM\26FEP2.SGM 26FEP2

Agencies

[Federal Register Volume 84, Number 38 (Tuesday, February 26, 2019)]
[Proposed Rules]
[Pages 6204-6275]
From the Federal Register Online via the Government Publishing Office [www.gpo.gov]
[FR Doc No: 2019-03019]



[[Page 6203]]

Vol. 84

Tuesday,

No. 38

February 26, 2019

Part II





Department of Health and Human Services





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Food and Drug Administration





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21 CFR Parts 201, 310, 347, et al.





Sunscreen Drug Products for Over-the-Counter Human Use; Proposed Rule

Federal Register / Vol. 84 , No. 38 / Tuesday, February 26, 2019 / 
Proposed Rules

[[Page 6204]]


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DEPARTMENT OF HEALTH AND HUMAN SERVICES

Food and Drug Administration

21 CFR Parts 201, 310, 347, and 352

[Docket No. FDA-1978-N-0018] (Formerly Docket No. FDA-1978-N-0038)
RIN 0910-AF43


Sunscreen Drug Products for Over-the-Counter Human Use

AGENCY: Food and Drug Administration, HHS.

ACTION: Proposed rule.

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SUMMARY: The Food and Drug Administration (FDA or Agency) is issuing 
this proposed rule to put into effect a final monograph for 
nonprescription, over-the-counter (OTC) sunscreen drug products. This 
proposed rule describes the conditions under which FDA proposes that 
OTC sunscreen monograph products are generally recognized as safe and 
effective (GRASE) and not misbranded. It is being published as part of 
the ongoing review of OTC drug products conducted by FDA. It is also 
being published to comply with the Federal Food, Drug, and Cosmetic Act 
(FD&C Act), as amended by the Sunscreen Innovation Act (SIA).

DATES: Submit either electronic or written comments. on the proposed 
rule by May 28, 2019. Electronic comments must be submitted on or 
before May 28, 2019. The https://www.regulations.gov electronic filing 
system will accept comments until 11:59 p.m. Eastern Time at the end of 
May 28, 2019. See section XII for proposed effective and compliance 
dates of a final rule based on this document.

ADDRESSES: You may submit comments as follows. Please note that late, 
untimely filed comments will not be considered. Comments received by 
mail/hand delivery/courier (for written/paper submissions) will be 
considered timely if they are postmarked or the delivery service 
acceptance receipt is on or before the closing date.
    Please be advised that safety and effectiveness data that are not 
available to the public cannot be relied on to establish conditions 
under which the OTC drugs described in this document of proposed 
rulemaking are generally recognized as safe and effective. Accordingly, 
you should not submit, and FDA generally does not intend to rely on, 
any evidence of safety and effectiveness that bears a confidential mark 
unless you include a statement that the information may be released to 
the public. Similarly, if your submission includes safety and 
effectiveness data or information marked as confidential by a third 
party (such as a contract research organization or consultant), you 
should either include a statement that you are authorized to make the 
information publicly available or include an authorization from the 
third party permitting the information to be publicly disclosed. If you 
submit data without confidential markings in response to this document 
and such data includes studies or other information that were 
previously submitted confidentially (e.g., as part of a new drug 
application), FDA intends to presume that you intend to make such data 
publicly available.

Electronic Submissions

    Submit electronic comments in the following way:
     Federal eRulemaking Portal: https://www.regulations.gov. 
Follow the instructions for submitting comments. Comments submitted 
electronically, including attachments, to https://www.regulations.gov 
will be posted to the docket unchanged. Because your comment will be 
made public, you are solely responsible for ensuring that your comment 
does not include any confidential information that you or a third party 
may not wish to be posted, such as medical information, your or anyone 
else's Social Security number, or confidential business information, 
such as a manufacturing process. Please note that if you include your 
name, contact information, or other information that identifies you in 
the body of your comments, that information will be posted on https://www.regulations.gov.
     If you want to submit a comment with confidential 
information that you do not wish to be made available to the public, 
submit the comment as a written/paper submission and in the manner 
detailed (see ``Written/Paper Submissions'' and ``Instructions'').

Written/Paper Submissions

    Submit written/paper submissions as follows:
     Mail/Hand Delivery/Courier (for written/paper 
submissions): Dockets Management Staff (HFA-305), Food and Drug 
Administration, 5630 Fishers Lane, Rm. 1061, Rockville, MD 20852.
     For written/paper comments submitted to the Dockets 
Management Staff, FDA will post your comment, as well as any 
attachments, except for information submitted, marked and identified, 
as confidential, if submitted as detailed in ``Instructions.''
    Instructions: All submissions received must include the Docket No. 
FDA-1978-N-0018 (formerly Docket No. FDA-1978-N-0038) for ``Sunscreen 
Drug Products for Over-the-Counter Human Use.'' Received comments, 
those filed in a timely manner (see ADDRESSES), will be placed in the 
docket and, except for those submitted as ``Confidential Submissions,'' 
publicly viewable at https://www.regulations.gov or at the Dockets 
Management Staff between 9 a.m. and 4 p.m., Monday through Friday.
     Confidential Submissions--To submit a comment with 
confidential information that you do not wish to be made publicly 
available, submit your comments only as a written/paper submission. You 
should submit two copies total. One copy will include the information 
you claim to be confidential with a heading or cover note that states 
``THIS DOCUMENT CONTAINS CONFIDENTIAL INFORMATION.'' The Agency will 
review this copy, including the claimed confidential information, in 
its consideration of comments. The second copy, which will have the 
claimed confidential information redacted/blacked out, will be 
available for public viewing and posted on https://www.regulations.gov. 
Submit both copies to the Dockets Management Staff. If you do not wish 
your name and contact information to be made publicly available, you 
can provide this information on the cover sheet and not in the body of 
your comments and you must identify this information as 
``confidential.'' Any information marked as ``confidential'' will not 
be disclosed except in accordance with 21 CFR 10.20 and other 
applicable disclosure law. For more information about FDA's posting of 
comments to public dockets, see 80 FR 56469, September 18, 2015, or 
access the information at: https://www.gpo.gov/fdsys/pkg/FR-2015-09-18/pdf/2015-23389.pdf.
    Docket: For access to the docket to read background documents or 
the electronic and written/paper comments received, go to https://www.regulations.gov and insert the docket number, found in brackets in 
the heading of this document, into the ``Search'' box and follow the 
prompts and/or go to the Dockets Management Staff, 5630 Fishers Lane, 
Rm. 1061, Rockville, MD 20852.
    Submit comments on information collection issues under the 
Paperwork Reduction Act of 1995 to the Office of Management and Budget 
(OMB) in the following ways:
     Fax to the Office of Information and Regulatory Affairs, 
OMB, Attn: FDA Desk Officer, Fax: 202-395-7285, or email to 
oira_submission@omb.eop.gov. All comments should be identified with

[[Page 6205]]

the title, ``Sunscreen Drug Products for Over-the-Counter Human Use.''
    The Agency encourages commenters also to submit their comments on 
these paperwork requirements to the rulemaking docket (Docket No. FDA-
1978-N-0018), along with their comments on other parts of the proposed 
rule.

FOR FURTHER INFORMATION CONTACT: Kristen Hardin, Center for Drug 
Evaluation and Research, Food and Drug Administration, 10903 New 
Hampshire Ave., Bldg. 22, Rm. 5443, Silver Spring, MD 20993, 240-402-
4246.

SUPPLEMENTARY INFORMATION: 

Table of Contents

I. Executive Summary
    A. Purpose and Coverage of the Proposed Rule
    B. Summary of the Major Provisions of the Proposed Rule
    C. Legal Authority
    D. Costs and Benefits
II. Table of Abbreviations/Commonly Used Acronyms in This Document
III. Background
    A. FDA's Current Regulatory Framework
    B. History of This Rulemaking
IV. Scope of This Rulemaking
V. Legal Authority
VI. Need for Additional Safety Information
    A. Increased Consumer Exposure to Sunscreen Active Ingredients
    B. Emerging Safety Concerns
VII. Framework for Evaluation of Safety Data
    A. General
    B. Clinical Safety Testing
    C. Nonclinical Safety Testing
    D. Postmarketing Safety Data
    E. Sunscreens Containing Nanomaterials
VIII. Existing Safety Data for Sunscreen Active Ingredients
    A. Ingredients Proposed as Category I
    B. Ingredients Proposed as Category II
    C. Ingredients Proposed as Category III
    D. Anticipated Final Formulation In Vitro Permeation Testing
IX. Additional Proposed Conditions of Use
    A. Proposed Requirements Related to Dosage Form
    B. Proposed Maximum SPF and Broad Spectrum Requirements
    C. Proposed PDP Labeling Requirements
    D. Proposed Requirements Related to Final Formulation Testing 
and Recordkeeping
    E. Proposed Status of Sunscreen-Insect Repellent Combination 
Products
X. Proposed Actions To Effectuate Lifting of Stay and Harmonize 
Impacted Regulations
XI. Comment Period
XII. Proposed Effective/Compliance Dates
XIII. Preliminary Economic Analysis of Impacts
    A. Introduction
    B. Summary of Costs and Benefits
XIV. Analysis of Environmental Impact
XV. Paperwork Reduction Act of 1995
    A. Labeling for Sunscreen Products and Associated Clinical 
Testing
    B. Regulatory Status of Testing Entities
    C. Generating and Maintaining Records of SPF and Broad Spectrum 
Testing
XVI. Federalism
XVII. Consultation and Coordination With Indian Tribal Governments
XVIII. References

I. Executive Summary

A. Purpose and Coverage of the Proposed Rule

    The Food and Drug Administration (FDA or Agency) is publishing this 
proposed rule as part of the regulatory proceeding to put into effect a 
final monograph \1\ for nonprescription, OTC sunscreen drug products 
under the OTC Drug Review. In 2011, FDA announced that ``we are 
considering certain active ingredient safety issues further . . . In a 
forthcoming rulemaking, we intend to request additional data regarding 
the safety of the individual sunscreen active ingredients.'' (``Revised 
Effectiveness Determination; Sunscreen Drug Products for Over-the-
Counter Human Use'' (Max SPF PR), 76 FR 35672 at 35673, June 17, 2011). 
As described in further detail below, changed conditions in the nearly 
20 years since publication of the final rule ``Sunscreen Drug Products 
for Over the Counter Human Use'' (64 FR 27666, May 21, 1999) (now 
stayed) (Stayed 1999 Final Monograph) have meant that additional safety 
data are now needed to establish that certain of the active ingredients 
listed in the Stayed 1999 Final Monograph are GRASE for use in 
sunscreen products.\2\
---------------------------------------------------------------------------

    \1\ An OTC monograph establishes conditions under which certain 
OTC drugs may be marketed without approved new drug applications 
because they are generally recognized as safe and effective (GRASE) 
and not misbranded. The proposed rule classifies active ingredients 
and other conditions as Category I (proposed to be GRASE and not 
misbranded), Category II (proposed to be not GRASE or to be 
misbranded), or Category III (additional data needed).
    \2\ Unless otherwise noted, references in this proposed rule to 
sunscreen active ingredients and/or sunscreen products are to 
sunscreen active ingredients or products marketed pursuant to the 
OTC monograph system and subject to 21 CFR 201.327. Unless 
specifically noted, references to sunscreen active ingredients and/
or sunscreen products in this notice do not refer to those marketed 
pursuant to a new drug application (NDA) or an abbreviated new drug 
application (ANDA). They also do not refer to sunscreen active 
ingredients being evaluated under the new procedures set out in the 
SIA (21 U.S.C. 360fff et seq).
---------------------------------------------------------------------------

    As detailed below, we emphasize that this proposed rule does not 
represent a conclusion by FDA that the sunscreen active ingredients 
included in the Stayed 1999 Final Monograph but proposed here as 
Category III are unsafe for use in sunscreens. Rather, we are 
requesting additional information on these ingredients so that we can 
evaluate their GRASE status in light of changed conditions, including 
substantially increased sunscreen usage and exposure and evolving 
information about the potential risks associated with these products 
since they were originally evaluated. While these additional data are 
being developed and reviewed, FDA generally intends to follow the 
enforcement approach discussed in section III.B with regard to 
sunscreen products that contain those sunscreen active ingredients 
included in the Stayed 1999 Final Monograph.
    This proposed rule is also being published to comply with section 
586E of the FD&C Act (21 U.S.C. 360fff-5), as amended by the SIA (21 
U.S.C. ch. 9, sub. 5, part I, enacted November 26, 2014). The SIA calls 
for FDA to issue a final OTC sunscreen monograph to be effective within 
5 years of enactment of the SIA, or by November 26, 2019 (section 
586E(a) of the FD&C Act). If the final OTC sunscreen monograph does not 
include provisions related to the effectiveness of various sun 
protection factor (SPF) levels and address all dosage forms known to 
FDA to be used in sunscreens marketed in the United States without 
approved new drug applications (NDAs), the SIA requires FDA, among 
other things, to submit a report to Congress explaining these omissions 
(section 586E(b) of the FD&C Act). As explained in section I.B, in this 
proposed rule, FDA is addressing multiple conditions of use applicable 
to sunscreen monograph products, including both the effectiveness of 
various SPF values and all marketed sunscreen dosage forms (and intends 
to do so in the final rule as well).
    This proposed rule does not address the sunscreen active 
ingredients that were originally submitted under the procedures 
established in FDA's time and extent application (TEA) regulation 
(Sec.  330.14 (21 CFR 330.14)) (67 FR 3074, January 23, 2002), and are 
now being addressed through a process set forth in the SIA.

B. Summary of the Major Provisions of the Proposed Rule

1. Proposed GRASE Status of Active Ingredients Listed in the Stayed 
1999 Final Monograph
    a. Framework for evaluation of safety data. As previously noted, 
changed conditions in the time since issuance of the Stayed 1999 Final 
Monograph have meant that additional safety data are now needed to 
establish that certain of the active ingredients listed in the Stayed 
1999 Final Monograph are GRASE for use in sunscreen products in 
accordance with the standards established in Sec.  330.10(a)(4) (21 CFR

[[Page 6206]]

330.10(a)(4)). FDA's approach to the clinical safety evaluation of OTC 
sunscreen active ingredients is based on our current scientific 
understanding regarding the safety evaluation of topical drug products 
for chronic use, and is therefore generally consistent with the safety 
data needed to meet the requirements for approval of an NDA for a 
chronic-use topical drug product (e.g., topical safety studies 
(irritation, sensitization, and photosafety); bioavailability 
(absorption); and evaluation of adverse events observed in clinical 
studies). Postmarketing safety information is also relevant to our 
safety evaluation.
    Our current approach to the nonclinical safety evaluation of these 
active ingredients takes into account their lengthy marketing history 
in the United States. Unlike the nonclinical data required to meet the 
standard for approval of chronic-use topical NDA products (which 
include comprehensive nonclinical pharmacology and toxicology safety 
testing), the approach to nonclinical safety testing reflected in this 
proposed rule is largely focused on potential long-term adverse effects 
or effects not otherwise readily detected from human use (i.e., 
carcinogenicity and reproductive toxicity).
    b. Existing safety data for ingredients listed in Stayed 1999 Final 
Monograph. In section VIII, we discuss our review of the scientific 
literature, submissions to the sunscreen monograph docket, and adverse 
event reports submitted to FDA's Adverse Event Reporting System (FAERS) 
for the ingredients listed in the Stayed 1999 Final Monograph and 
identify any existing gaps. Because our review of this evidence has 
produced sufficient safety data on both zinc oxide and titanium dioxide 
to support a proposal that sunscreen products containing these 
ingredients (at concentrations of up to 25 percent) would be GRASE, we 
are proposing that these ingredients are Category I. Our evaluation of 
the available safety data for aminobenzoic acid (PABA) and trolamine 
salicylate, however, has caused us to conclude that the risks 
associated with use of these active ingredients in sunscreen products 
outweigh their benefits. In the case of trolamine salicylate, these 
risks include the potential for serious detrimental health effects 
(including bleeding) caused by the anti-coagulation effects of 
salicylic acid and increased risk of salicylate toxicity when this 
ingredient is used in sunscreens. For PABA, the risks include 
significant rates of allergic and photoallergic skin reactions, as well 
as cross-sensitization with structurally similar compounds. 
Accordingly, we are proposing that these two ingredients are Category 
II.
    Because the public record does not currently contain sufficient 
data to support positive GRASE determinations for cinoxate, 
dioxybenzone, ensulizole, homosalate, meradimate, octinoxate, 
octisalate, octocrylene, padimate O, sulisobenzone, oxybenzone, or 
avobenzone, we are proposing that these ingredients are Category III. 
For example, the available literature includes studies indicating that 
oxybenzone is absorbed through the skin to a greater extent than 
previously understood and can lead to significant systemic exposure, as 
well as data showing the presence of oxybenzone in human breast milk, 
amniotic fluid, urine, and blood plasma. The significant systemic 
availability of oxybenzone, coupled with a lack of data evaluating the 
full extent of its absorption potential, is a concern, among other 
reasons, because of questions raised in the published literature 
regarding the potential for endocrine activity in connection with 
systemic oxybenzone exposure. Nearly all of these sunscreen active 
ingredients also have limited or no data characterizing their 
absorption.
2. Proposed Requirements Related to Dosage Forms
    In 2011, FDA published an Advance Notice of Proposed Rulemaking 
(ANPR) that identified sunscreen dosage forms considered either 
eligible or ineligible for inclusion in the sunscreen monograph, and 
specifically requested comments on the safety and efficacy of spray 
sunscreens. After considering comments received in response (and other 
available data), we are proposing the following dosage forms as 
Category I: Oils, lotions, creams, gels, butters, pastes, ointments, 
and sticks. We are also proposing Category I status for spray 
sunscreens, subject to testing necessary to minimize potential risks 
from unintended inhalation (particle size restrictions) and 
flammability (flammability and drying time testing), together with 
related labeling requirements. We are proposing to add sunscreen 
powders to the list of those eligible for inclusion in the monograph 
and proposing that this dosage form is Category III; we expect that 
powders would also be subject to particle size restrictions if found to 
be GRASE in the final monograph. Finally, we are proposing that 
sunscreens in all other dosage forms--including wipes, towelettes, body 
washes, and shampoos--are new drugs because we did not receive data 
showing that they were marketed prior to 1972, as required for 
inclusion in the monograph.
3. Proposed Maximum Sun Protection Factor and Broad Spectrum 
Requirements
    In the Stayed 1999 Final Monograph, FDA established SPF 30+ as the 
maximum labeled SPF value for sunscreen monograph products, and 
subsequently proposed (in 2011) to raise this value to SPF 50+. Because 
of evidence showing additional meaningful clinical benefit associated 
with broad spectrum sunscreen products with an SPF of 60, we are now 
proposing to raise the maximum labeled SPF value to SPF 60+. Given the 
lack of data showing that sunscreens with SPF values above 60 provide 
additional meaningful clinical benefit, we are proposing not to allow 
labeled SPF values higher than 60+.
    While our proposed cap for SPF labeling is SPF 60+, we are 
proposing to permit the marketing of sunscreen products formulated with 
SPF values up to 80. This formulation margin is intended to provide 
manufacturers with formulation flexibility that we hope will: (1) Help 
facilitate the development of products with greater Ultraviolet A (UVA) 
protection and (2) more fully account for the range of variability in 
SPF test results (discussed further in sections IX.B.4.b-c) for 
sunscreen products labeled SPF 60+. We are proposing not to allow the 
marketing (without an approved NDA) of sunscreen products with SPF 
values above SPF 80.
    In addition, since publication of the 2011 ``Labeling and 
Effectiveness Testing; Sunscreen Drug Products for Over-the-Counter 
Human Use'' (L&E Final Rule) (76 FR 35620, June 17, 2011) and Max SPF 
PR, the body of scientific evidence linking UVA exposure to skin 
cancers and other harms has grown significantly. This evidence raises 
concerns about the potential for inadequate UVA protection in marketed 
sunscreen products--particularly in high SPF sunscreen products that 
either do not pass the current broad spectrum test or (though they pass 
our current broad spectrum test) have inadequate uniformity in their 
UVA protection. Consumers using these products may, while successfully 
preventing sunburn, accumulate excessively large doses of UVA 
radiation--thereby exposing themselves to additional risks related to 
skin cancer and early skin aging.
    To address these concerns, we are making a number of proposals 
designed to couple a greater magnitude of UVA protection to increases 
in SPF values. We are proposing to require that all sunscreen products 
with SPF values of 15 and above satisfy broad spectrum

[[Page 6207]]

requirements. Among other things, this proposal eliminates the 
potential confusion permitted by the current labeling regime, in which 
a higher numbered product (for example, one labeled SPF 30) may provide 
inferior protection against UVA radiation than a lower numbered product 
(for example, one labeled broad spectrum SPF 15). We are also proposing 
to add to the current broad spectrum test a requirement that broad 
spectrum products meet a UVA I/UV ratio of 0.7 or higher. Given how 
much of the UVA portion of the ultraviolet (UV) spectrum is composed of 
UVA I radiation, and given what we now know about the skin cancer risks 
associated with UVA exposure, ensuring that sunscreen products provide 
adequate protection in the UVA I portion of the spectrum is 
critical.\3\ Because sunscreens with SPF 2 to 14 have not been 
demonstrated to help reduce the risk of skin cancer and early skin 
aging caused by the sun, whether or not they provide protection against 
UVA radiation as well as ultraviolet B (UVB) radiation, we are not 
proposing to require that they pass the revised broad spectrum test. 
However, we seek comment on whether these low SPF products should 
remain in the market.
---------------------------------------------------------------------------

    \3\ We note that because our proposal to raise the maximum 
labeled SPF value to 60+ is based on studies that all used broad 
spectrum sunscreens, the additional clinical benefit we are 
proposing to recognize in sunscreen products with SPF values greater 
than 50 cannot be decoupled from the broad spectrum protection 
provided by those products. As a result, our proposal to raise the 
maximum labeled SPF value to SPF 60+ is both consistent with and 
dependent upon our proposal to require that all sunscreen monograph 
products with SPF values of 15 and above satisfy our broad spectrum 
requirements.
---------------------------------------------------------------------------

    Finally, we are proposing to require that sunscreen products with 
SPF values of 15 or above be labeled with an SPF number corresponding 
to the lowest number in a range of tested SPF results. For example, 
sunscreens testing at SPF 15-19 would be labeled ``SPF 15''; those 
testing at 40-49 would be labeled ``SPF 40.'' We are making this 
proposal because new evidence has caused us to reexamine the 
variability inherent in the SPF test (which relies on visual 
assessments of erythema in human subjects). The data we reviewed 
suggests that the clinical evaluation undertaken during SPF testing 
creates variability that justifies the use of SPF ranges. As explained 
further in sections IX.B.4.b-c, because this variability is exacerbated 
at high SPFs, we are proposing that sunscreens testing at SPF 30 or 
more be labeled in increments of 10 (i.e., SPF 30, SPF 40, SPF 50, with 
a proposed maximum of SPF 60+), that sunscreens testing at SPF 15 to 29 
be labeled in increments of 5 (i.e., SPF 15, SPF 20, SPF 25), and that 
the requirement that labeled SPF values correspond to ranges (rather 
than precise numerical values) is not necessary below SPF 15.
4. Proposed PDP Labeling Requirements
    We are also proposing to partially revise the current requirements 
for information that must appear on the principal display panel (PDP) 
of sunscreen products. The PDP is the part of a product label that is 
most likely to be viewed or examined when the product is displayed for 
retail sale. A major feature of the PDP is the statement of identity 
(SOI). We are proposing that the SOI consist of an alphabetical listing 
of the sunscreen active ingredients in the product, followed by 
``Sunscreen'' and the product's dosage form (such as lotion or spray). 
This information would supplement other important elements of the PDP 
(e.g., SPF, broad spectrum, and water resistance information) to 
provide a succinct summary of the product's key characteristics on the 
front of the package or container, permitting consumers to more readily 
compare products and either select or avoid a given product 
accordingly. For sunscreen products that have not been shown to help 
prevent skin cancer or early skin aging caused by the sun, the SPF 
statement would be followed by an asterisk (*) directing consumers to 
see the ``Skin Cancer/Skin Aging alert'' elsewhere on the label. 
Finally, to prevent required information from being obscured or 
overwhelmed by other labeling features, we are revising the format 
requirements for the SPF, broad spectrum, and water resistance 
statements on the PDP.
5. Proposed Requirements Related to Final Formulation Testing Processes 
and Recordkeeping
    To ensure that FDA can assess compliance with our regulations, we 
are proposing to require records of required final formulation testing 
of sunscreen products to be maintained for 1 year after the product 
expiration date, or, if the product is exempt from expiration dating 
(as most sunscreens are), for 3 years after distribution of the last 
lot labeled in reliance on that testing. In addition, we are proposing 
to require responsible persons (defined in section IX.D.2.b) to keep 
records of sunscreen formulation testing, and clarifying that required 
records would be subject to FDA inspection. We are also proposing a 
number of revisions to our labeling and testing regulations designed to 
clarify FDA expectations about clinical final formulation testing 
processes and to ensure that the testing of marketed sunscreen products 
is conducted in a manner that both protects human subjects and produces 
reliable results.
6. Proposed Status of Sunscreen-Insect Repellent Combination Products
    The proposed rule also addresses sunscreen-insect repellent 
products, which are jointly regulated by FDA as sunscreen drugs and by 
the Environmental Protection Agency (EPA) as pesticides under the 
Federal Insecticide, Fungicide and Rodenticide Act (FIFRA). In 2007, 
FDA and EPA both issued ANPRs requesting comment on the appropriate 
regulatory status of these products. We are proposing to classify these 
products as Category II because incompatibilities between FDA and EPA 
labeling requirements prevent these products from being labeled in a 
manner that sufficiently ensures safe and effective use of the 
sunscreen component and provides adequate directions for use. In 
addition, there are data suggesting that combining some sunscreen 
active ingredients with the insecticide DEET may increase absorption of 
either or both components.
7. Proposed Actions To Effectuate Lifting of Stay and Harmonize 
Impacted Regulations
    Finally, we are proposing to lift the stay on the 1999 Final 
Monograph (subject to the revisions to parts 201, 310, 347, and 352 (21 
CFR parts 201,\4\ 310, 347, and 352) described in this document), and 
have proposed revisions to these regulations necessary to effectuate 
the lifting of the stay and to harmonize any impacted regulations.
---------------------------------------------------------------------------

    \4\ We note that, for ease of comprehension, we have included in 
this document the current provisions of 21 CFR 201.327 that we are 
not proposing to revise along with the provisions of that regulation 
that we are proposing to revise.
---------------------------------------------------------------------------

C. Legal Authority

    We are issuing this proposed rule under sections 201, 301, 501, 
502, 503, 505, 510, 586E, 701, 702, 703, 704, and 721 of the FD&C Act 
(21 U.S.C. 321, 331, 351, 352, 353, 355, 360, 360fff-5, 371, 372, 373, 
374, and 379e) and under section 351 of the Public Health Service Act 
(42 U.S.C. 262).

D. Costs and Benefits

    If finalized, the proposed rule would update and make effective 
regulations to ensure the safety and effectiveness of sunscreen 
products marketed under the OTC drug monograph. The rule would update 
sunscreen product labeling standards, address the safety of sunscreen 
active ingredients, revise and

[[Page 6208]]

clarify our expectations for testing and recordkeeping by entities that 
conduct sunscreen testing, and address other sunscreen safety or 
efficacy concerns, like combination sunscreen-insect repellents and 
alternative dosage forms.
    Consumers would benefit from less exposure to sunscreen products 
containing active ingredients about which safety questions remain, less 
exposure to sunscreen products labeled with potentially misleading sun 
protection information, increased consumption of products with better 
UVA protection, less exposure to flammable spray sunscreens, and less 
exposure to spray and powder sunscreen products posing inhalation 
risks. Consumers would also experience transaction cost savings. The 
costs of the rule to sunscreen manufacturers include administrative 
costs, costs to fill data gaps for active ingredients and powder dosage 
forms, product formulation testing costs, and costs to reformulate and 
relabel sunscreen products. Finally, testing entities would incur 
recordkeeping costs if they do not already maintain adequate records of 
testing equipment, methods, and observations in final formulation 
testing.

II. Table of Abbreviations/Commonly Used Acronyms in This Document

------------------------------------------------------------------------
        Abbreviation/ acronym                    What it means
------------------------------------------------------------------------
ANDA.................................  Abbreviated new drug application.
ANPR.................................  Advance notice of proposed
                                        rulemaking.
CFR..................................  Code of Federal Regulations.
DART.................................  Developmental and reproductive
                                        toxicity.
DEET.................................  N,N-Diethyl-meta-toluamide.
EPA..................................  Environmental Protection Agency.
FAERS................................  FDA's Adverse Event Reporting
                                        System.
FDA or Agency........................  Food and Drug Administration.
FD&C Act.............................  Federal Food, Drug, and Cosmetic
                                        Act.
FIFRA................................  Federal Insecticide, Fungicide,
                                        and Rodenticide Act.
FR...................................  Federal Register.
GRASE................................  Generally recognized as safe and
                                        effective (or general
                                        recognition of safety and
                                        effectiveness).
ICH..................................  International Council for
                                        Harmonisation of Technical
                                        Requirements for Pharmaceuticals
                                        for Human Use.
IND..................................  Investigational new drug
                                        application.
IRB..................................  Institutional Review Board.
mL...................................  Milliliter.
MUsT.................................  Maximal usage trial.
NDA..................................  New drug application.
NDAC.................................  Nonprescription Drugs Advisory
                                        Committee.
Ng...................................  Nanogram.
Nm...................................  Nanometer.
NOAEL................................  No observed adverse effect level.
NPIC.................................  National Pesticide Information
                                        Center.
NTP..................................  National Toxicology Program of
                                        the National Institutes of
                                        Health.
OMB..................................  Office of Management and Budget.
OTC..................................  Over-the-counter.
PABA.................................  Aminobenzoic acid.
ROS..................................  Reactive oxygen species.
SIA..................................  Sunscreen Innovation Act.
SPF..................................  Sun protection factor.
TEA..................................  Time and extent application.
TFM..................................  Tentative final monograph.
U.S.C................................  United States Code.
USP..................................  United States Pharmacopeia.
UVA..................................  Ultraviolet A.
UVB..................................  Ultraviolet B.
------------------------------------------------------------------------

III. Background

A. FDA's Current Regulatory Framework

    In the following sections, we provide a brief description of 
terminology used in the OTC Drug Review regulations as well as an 
overview of OTC sunscreen products, their intended uses, and FDA's 
regulation of them.
1. Terminology
    a. OTC drug review. The OTC Drug Review is the process established 
by FDA to evaluate the safety and effectiveness of OTC drug products 
marketed in the United States before May 11, 1972, and to establish the 
conditions under which they are considered to be GRASE and not 
misbranded. As described further below, the OTC Drug Review is 
generally conducted via a multiphase public rulemaking process (each 
phase requiring a Federal Register publication), resulting in the 
establishment of a monograph for an OTC therapeutic drug category.
    b. Generally recognized as safe and effective (GRASE). An OTC drug 
is ``generally recognized as safe and effective'' if it meets each of 
the conditions contained in an applicable OTC final monograph, the 
conditions contained in part 330 (21 CFR part 330), and any other 
applicable regulatory and statutory requirements for OTC drugs, 
including the labeling requirements in part 201.
    c. Proposed, tentative final, and final monographs. The proposed 
monograph, which is typically published in the form of an ANPR, is the 
end product of the first phase of the rulemaking process described 
above. After reviewing the report and recommendations of an expert 
advisory review panel responsible for initially reviewing the safety, 
effectiveness, and labeling of products in a given therapeutic 
category, FDA publishes a proposed monograph (together with the report 
and recommendations of the expert review panel) (see Sec.  
330.10(a)(6)). After a period of public comment, FDA publishes a 
tentative final monograph (TFM) (in the form of a proposed rule, 
proposing conditions under which OTC drugs in the therapeutic class 
being considered are GRASE and not misbranded (see Sec.  330.10(a)(7)). 
Following public comment on the TFM, FDA publishes a final monograph in 
FDA's regulations (see 21 CFR chapter I, subchapter D) codifying the 
conditions under which products in the OTC therapeutic drug category 
are GRASE and not misbranded (see Sec.  330.10(a)(9)). An OTC drug may 
be legally marketed without an approved NDA or abbreviated new drug 
application (ANDA) if it meets each of the conditions contained in an 
applicable final monograph, the conditions contained in part 330, and 
any other applicable regulatory and statutory requirements for OTC 
drugs, including the labeling requirements in part 201.
    d. Category I, II, and III classifications. In the course of 
establishing an OTC monograph, active ingredients and other OTC drug 
conditions are classified in one of three categories: Category I 
(conditions under which a nonprescription drug in the therapeutic 
category would be GRASE and not misbranded), Category II (conditions 
that would result in the drug being classified as not GRASE and/or 
misbranded) and Category III (conditions proposed to be excluded from 
the final monograph because available data are insufficient to classify 
them as either Category I or Category II) (see Sec.  330.10(a)(6)).
2. OTC Sunscreen Products Regulated Under the OTC Drug Review and Their 
Intended Uses
    OTC sunscreen drugs regulated under the OTC Drug Review are 
topically applied products indicated to help prevent sunburn; some are 
also indicated to decrease the risk of skin cancer and early skin aging 
caused by exposure to the sun's UV radiation (when used as directed 
with other sun protection measures) (see Sec.  201.327(c)). The active 
ingredients in sunscreen products achieve these protective effects by 
absorbing, reflecting, and/or scattering radiation in the UV range 
(from 290 to 400 nanometers (nm)) (see section 586(10) of the FD&C Act 
(21 U.S.C. 360fff(10)); see also Sec.  352.3(c) (21 CFR 352.3(c)), 
stayed).
    Sunscreen products must be labeled with an SPF value calculated 
using a standardized SPF testing procedure set forth in FDA regulations 
(in Sec.  201.327(i)). As discussed in further detail in section 
IX.B.1, the SPF test

[[Page 6209]]

measures the amount of UV radiation exposure it takes to cause sunburn 
when a person is using a sunscreen when compared with how much UV 
exposure it takes to cause sunburn when the person is not using a 
sunscreen. Because SPF values represent a sunscreen's level of sunburn 
protection, they are primarily (though not exclusively) an indicator of 
expected protection from UVB radiation (see section IX.B.1 for a 
discussion of both UVB and UVA radiation).
    To pass FDA's current test for the inclusion of the term ``broad 
spectrum'' in labeling (which was established in the 2011 L&E Final 
Rule), sunscreen products must demonstrate that, in addition to UVB 
protection, they also provide UVA protection. Further, only products 
that have been demonstrated both to provide broad spectrum protection 
and to have a minimum SPF value of 15 have been shown to reduce the 
risk of skin cancer and early skin aging caused by the sun (when used 
as directed with other sun protection measures). By contrast, 
sunscreens that have not been demonstrated to provide both broad 
spectrum protection and an SPF value of at least 15 have only been 
demonstrated to help prevent sunburn.\5\ Thus, under the 2011 L&E Final 
Rule, passing the broad spectrum test in Sec.  201.327(j) (21 CFR 
201.327(j)) is necessary, but not itself sufficient, to support 
inclusion of a skin cancer indication in labeling, although any product 
that passes the broad spectrum test may be labeled with the term 
``Broad Spectrum'' in conjunction with its SPF value.
---------------------------------------------------------------------------

    \5\ As described in further detail in section IXB.2, in the time 
since the L&E Final Rule was issued in 2011, the body of evidence 
about the role of UVA radiation in the development of skin cancer 
has grown. As a result, FDA is making a number of proposals designed 
(among other things) to couple a greater magnitude of UVA protection 
to increases in SPF values.
---------------------------------------------------------------------------

B. History of This Rulemaking

1. The OTC Sunscreen Drug Review and FDA's Regulation of OTC Sunscreen 
Drug Products
    Our initial call for safety and efficacy data for sunscreen 
products was issued in 1972 (37 FR 26456, December 12, 1972). The 
resulting data submissions were reviewed by the Advisory Review Panel 
on OTC Topical Analgesic, Antirheumatic, Otic, Burn, and Sunburn 
Prevention and Treatment Products, whose panel report and recommended 
monograph were published as an ANPR in 1978 (43 FR 38206, August 25, 
1978). The ANPR contained a list of the 21 sunscreen active ingredients 
\6\ that the panel recommended for classification as GRASE when used 
under the conditions described in the panel's report (43 FR 38206 at 
38219). In 1993, having reviewed the panel's report and related public 
comments, FDA published a TFM (58 FR 28194, May 12, 1993) which (with 
one exception--padimate A) proposed as GRASE all of the active 
ingredients that had been included in the ANPR. The TFM also included 
specified maximum concentrations at which the proposed ingredients 
would be considered GRASE for use in sunscreens.
---------------------------------------------------------------------------

    \6\ The ingredients were: Aminobenzoic acid, digalloyl 
trioleate, 2-ethylhexyl 2-cyano-3,3-diphenylacrylate, glyceryl 
aminobenzoate, menthyl anthranilate, padimate O, sulisobenzone, 
cinoxate, dioxybenzone, ethylhexyl p-methoxycinnamate, homosalate, 
oxybenzone, 2-phenylbenzimidazole-5-sulfonic acid, titanium dioxide, 
diethanoloamine p-methoxycinnamate, ethyl 4-[bis (hydroxylpropyl)] 
aminobenzoate, 2-ethylhexyl salicylate, lawsone with 
dihydroxyacetone, padimate A, red petrolatum, and triethanolamine 
salicylate.
---------------------------------------------------------------------------

    In the years following the publication of the 1993 TFM, FDA removed 
several additional ingredients from the TFM (see 59 FR 29706, June 8, 
1994), as described at 64 FR 27666 at 27681, and proposed the inclusion 
of two more.\7\ In 1999, FDA published a final sunscreen monograph, 
which included the following 16 sunscreen active ingredients along with 
the conditions (including maximum concentrations) under which these 
ingredients would be considered GRASE for use in sunscreens: \8\
---------------------------------------------------------------------------

    \7\ In 61 FR 48645 (September 16, 1996) (proposing that 
avobenzone is GRASE up to 3 percent alone and 2 to 3 percent when in 
combination with cinoxate, diethanolamine methoxycinnamate, 
dioxybenzone, homosolate, octocrylene, octyl methoxycinnamate, octyl 
salicylate, oxybenzone, sulisobenzone, and/or trolamine salicylate) 
and 63 FR 56584 (October 22, 1998) (proposing that zinc oxide is 
GRASE alone or in combination with any previously proposed GRASE 
active ingredient except avobenzone). The list of active ingredients 
was (and would continue to be) modified because of, among other 
things, a lack of interest in developing United States Pharmacopeia 
(USP) compendial monographs for certain of the active ingredients 
originally proposed (see 64 FR 27666 at 27681).
    \8\ See Sec.  352.10, now stayed; 64 FR 27666. The active 
ingredient names used in that regulation, as originally published, 
differ from those used in table 1, which are the current established 
names for these active ingredients. We note that subsequent to the 
publication of the Stayed 1999 Final Monograph, we issued another 
final rule in 2002 amending the names used for four of those 
ingredients to make them consistent with the renaming of those 
ingredients in the corresponding USP monographs (67 FR 41821 at 
41823, June 20, 2002). Under section 502(e) of the FD&C Act, drug 
labels are required to bear the established name of each active 
ingredient, and if FDA has not designated an official name under 
section 508 of the FD&C Act (21 U.S.C. 358), the compendial name is 
the established name. To comply with section 502(e) of the FD&C Act, 
sunscreen drug products must therefore bear the current compendial 
names for their active ingredients, and the current compendial names 
are used throughout this document. Because the 2002 final rule that 
changed those names was published after part 352 was stayed, 
however, those amendments have not yet been incorporated into the 
published monograph regulation.

 Table 1--Sunscreen Active Ingredients Included in the Stayed 1999 Final
                                Monograph
------------------------------------------------------------------------
                                                              Maximum
                    Active ingredient                      concentration
                                                                (%)
------------------------------------------------------------------------
Aminobenzoic acid (PABA)................................              15
Avobenzone..............................................               3
Cinoxate................................................               3
Dioxybenzone............................................               3
Ensulizole..............................................               4
Homosalate..............................................              15
Meradimate..............................................               5
Octinoxate..............................................             7.5
Octisalate..............................................               5
Octocrylene.............................................              10
Oxybenzone..............................................               6
Padimate O..............................................               8
Sulisobenzone...........................................              10
Titanium dioxide........................................              25
Trolamine salicylate....................................              12
Zinc oxide..............................................              25
------------------------------------------------------------------------

Among other things, the Stayed 1999 Final Monograph established a 
minimum SPF value of 2, and an SPF of 30+ as the maximum labeled SPF 
value (64 FR 27666). FDA concluded that the above-listed ingredients 
(at the listed concentrations) could also be used in combination, with 
limited exceptions, provided that each active ingredient contributed a 
minimum SPF of 2 to the finished product (64 FR 27666).\9\
---------------------------------------------------------------------------

    \9\ An exception to this rule involving avobenzone was retained 
from the TFM: The Stayed 1999 Final Monograph stated that avobenzone 
may not be combined with PABA, phenylbenzimidazole sulfonic acid, 
menthyl anthranilate, padimate O, titanium dioxide, or zinc oxide. 
In 2007, we proposed to include in the monograph a condition 
permitting the marketing of sunscreens containing avobenzone in 
combination with either zinc oxide or ensulizole based on safety and 
effectiveness data about these combinations provided to the docket 
(``Sunscreen Drug Products for Over-the-Counter Human Use: Proposed 
Amendment of Final Monograph'', 72 FR 49070 at 49074, August 27, 
2007). As described in section VII.A, we now anticipate finalizing a 
monograph that would permit all listed active ingredients to be 
combined without limitation. This approach is consistent with the 
approach to sunscreen combinations generally taken throughout the 
OTC Drug Review for sunscreens.
---------------------------------------------------------------------------

    The effective date for complying with the Stayed 1999 Final 
Monograph was May 21, 2001. This deadline was extended (65 FR 36319, 
June 8, 2000) and then stayed until further notice (66 FR 67485, 
December 31, 2001) to provide additional time to resolve various 
outstanding issues, such as the labeling and testing of finished OTC 
sunscreen products. As a result, the

[[Page 6210]]

Stayed 1999 Final Monograph has never been in effect.
    In 2011, FDA published a draft guidance for industry, ``Enforcement 
Policy--OTC Sunscreen Drug Products Marketed Without an Approved 
Application,'' addressing the circumstances under which FDA intended to 
exercise its enforcement discretion with respect to certain marketed 
OTC sunscreen products in the period until a final OTC sunscreen 
monograph becomes effective. This guidance was finalized in May 2018 
(2018 Final Guidance) (Ref. 1). Unless the failure to pursue regulatory 
action poses a potential health hazard to the consumer, FDA generally 
does not intend to object to the marketing of OTC sunscreen products 
that do not have an approved NDA or ANDA provided that they: (1) 
Contain as sunscreen active ingredients only the active ingredients or 
combinations of active ingredients listed in 21 CFR 352.10 and 352.20 
(both currently stayed); (2) do not make claims addressed in Sec. Sec.  
201.327(c)(3) and (g) and 310.545(a)(29)(ii); (3) comply with the 
requirements for OTC drugs set forth in part 201 and Sec.  330.1 (21 
CFR 330.1), the requirements for adverse event reporting for OTC drugs 
set forth in the FD&C Act (see section 760 (21 U.S.C. 379aa)), and the 
provisions of the FD&C Act addressing adulteration; and (4) follow 
applicable labeling and testing requirements for OTC sunscreens set 
forth in Sec.  201.327.
2. Recent Significant Rulemakings Relevant to This Proposed Rule
    Since publishing the Stayed 1999 Final Monograph, FDA has issued a 
number of Federal Register notices relating to OTC sunscreens. Major 
notices pertinent to today's proposed rule are summarized briefly in 
table 2 below:

 Table 2--Recent Significant Federal Register Notices Pertinent to This
                                  Rule
------------------------------------------------------------------------
      Federal Register notice               Information in notice
------------------------------------------------------------------------
Insect Repellent-Sunscreen Drug     We issued a notice stating that we
 Products for Over-the-Counter       were considering amending the
 Human Use: Request for              Stayed 1999 Final Monograph to
 Information and Comments; 72 FR     include conditions for marketing
 7941, February 22, 2007.            insect repellent-sunscreen drug
                                     products and requested information
                                     to form a regulatory position on
                                     these products. The Environmental
                                     Protection Agency, which regulates
                                     the insect repellent component of
                                     insect repellent-sunscreen
                                     combinations, published a similar
                                     notice concurrently with ours, also
                                     seeking information and comment on
                                     these products.
Sunscreen Drug Products for Over-   We proposed to amend the Stayed 1999
 the-Counter Human Use: Proposed     Final Monograph to address, among
 Amendment of Final Monograph; 72    other things, formulation,
 FR 49070, August 27, 2007.          labeling, and testing requirements
                                     for both UVA and UVB radiation
                                     protection.
Labeling and Effectiveness          We issued a final rule establishing
 Testing: Sunscreen Drug Products    labeling and testing requirements
 for Over-the-Counter Human Use      for sunscreen products. Among other
 (L&E Final Rule); 76 FR 35620,      things, the L&E Final Rule
 June 17, 2011.                      established optional broad spectrum
                                     labeling, created an optional
                                     indication relating to decreasing
                                     the risk of skin cancer and early
                                     skin aging for broad spectrum
                                     products with an SPF of 15 or
                                     higher, and required a labeling
                                     warning for sunscreens that did not
                                     both satisfy the broad spectrum
                                     test and provide an SPF of at least
                                     15.
2011 Proposed Rule: Revised         We proposed to raise the limit on
 Effectiveness Determination (Max    the maximum permissible labeled SPF
 SPF PR); 76 FR 35672, June 17,      value for sunscreen products to
 2011.                               ``50+.'' Among other things, we
                                     sought comment on the
                                     appropriateness of a formulation
                                     cap for sunscreen products.
2011 ANPR and Request for Data and  We issued an ANPR describing the
 Information on Certain Dosage       sunscreen dosage forms that we
 Forms; 76 FR 35669, June 17, 2011.  considered to be part of the OTC
                                     Drug Review and thus eligible for
                                     potential inclusion in a sunscreen
                                     monograph, as well as those dosage
                                     forms that we did not consider
                                     eligible. We requested data to
                                     enable us to ensure that the
                                     administrative record would be
                                     adequate to support GRASE
                                     determinations for the eligible
                                     sunscreen dosage forms. In
                                     particular, we emphasized that
                                     additional safety and efficacy data
                                     would be needed to support final
                                     monograph status for spray dosage
                                     forms. We also announced that we
                                     were issuing a draft guidance
                                     document (discussed above)
                                     explaining the Agency's intended
                                     enforcement policy for sunscreens
                                     marketed pursuant to the monograph
                                     system, including with respect to
                                     dosage forms. The Agency's approach
                                     to enforcement of spray sunscreens
                                     is now described in the 2018 Final
                                     Guidance.
------------------------------------------------------------------------

IV. Scope of This Rulemaking

    Eligibility for inclusion in an OTC monograph was originally 
limited to active ingredients and other conditions that had been used 
in drugs marketed in the United States prior to the inception of the 
OTC Drug Review in 1972. After publication of the final sunscreen 
monograph in 1999, FDA published its TEA regulation (Sec.  330.14), (67 
FR 3060 at 3074, January 23, 2002), which sets forth criteria and 
procedures by which OTC drugs initially marketed in the United States 
after the OTC Drug Review began and OTC drugs without any U.S. 
marketing experience can be considered for inclusion in the OTC drug 
monograph system. Congress later passed the SIA, which, among other 
things, supplements FDA's TEA regulations for OTC sunscreen drug 
products (21 U.S.C. 360fff through 360fff-7) (2014).
    This proposed rule addresses the GRASE status (and conditions of 
use applicable to) sunscreen drug products containing active 
ingredients listed in the Stayed 1999 Final Monograph. It does not 
address the pending sunscreen active ingredients that were originally 
submitted under the procedures established in the TEA regulation and 
are now being addressed through the SIA process.\10\ As discussed 
further in section VII, however, the safety data we described as 
necessary to evaluate the safety and effectiveness of sunscreen 
products containing those active ingredients are the same as what we 
are now describing as needed to establish that the active ingredients 
listed in the Stayed 1999 Final Monograph are GRASE for use in 
sunscreen products. We are not revisiting the contribution that the 
active ingredients listed in the Stayed 1999 Final Monograph make to 
the effectiveness of sunscreens. The Agency has not received 
information suggesting that it is necessary to revisit its prior 
decision about the effectiveness of the active ingredients at this 
time.
---------------------------------------------------------------------------

    \10\ FDA's proposed sunscreen orders on each of these 
ingredients can be found at https://www.fda.gov/drugs/guidancecomplianceregulatoryinformation/ucm434843.htm.
---------------------------------------------------------------------------

V. Legal Authority

    We are issuing this proposed rule under sections 201, 301, 501, 
502, 503, 505, 510, 586E, 701, 702, 703, 704, and 721 of the FD&C Act 
and under section 351 of the Public Health Service Act (42 U.S.C. 262).

VI. Need for Additional Safety Information

A. Increased Consumer Exposure to Sunscreen Active Ingredients

    Consumer exposure to sunscreen active ingredients has increased 
dramatically since FDA began its initial safety evaluations of the 
sunscreen active ingredients at issue in this proposed rule. Many 
factors have influenced this increase, including the following:


[[Page 6211]]


 Significant increases in the number and types of consumers 
using sunscreen products (Refs. 2 and 3)
 Sunscreen products containing a greater number of active 
ingredients at greater concentrations (Ref. 4)
 Increased awareness of the risks of sun exposure and 
encouragement of routine sunscreen use by medical and public health 
authorities (see, e.g., Ref. 5)
 Evolving directions for use on sunscreen products instructing 
consumers to use greater amounts of sunscreen per application and to 
reapply sunscreen products more frequently (76 FR 35672 at 35678), 
codified as Sec.  201.327)
 Expanding availability and use of many different types of 
sunscreen products, including daily-use products such as facial makeup, 
moisturizing creams, and lipstick

    Relatively few sunscreen products were in use when the U.S. Army 
initially funded research into the development of effective sunscreen 
products for use by military personnel on aircraft carriers (and others 
routinely exposed to long periods of intense sunlight) during World War 
II (Ref. 2). The reach of sunscreen products began to broaden when they 
were later marketed for use specifically by consumers who sunburned 
readily (i.e., fair-skinned individuals) in situations of intentional 
sun exposure, such as sunbathing on a beach (Ref. 6). Sunscreen 
products are now routinely used by a much broader range of consumers 
for protection against many types of sun-induced skin damage, not just 
sunburn. Accumulating data demonstrate that increased sun exposure 
increases the risk of developing skin cancers and premature skin aging 
(Ref. 2). To help reduce the risk of these types of sun-induced skin 
damage, public health organizations (including FDA) have for years 
urged consumers to use sunscreen products along with other sun-
protective behaviors like limiting time in the sun and wearing 
protective clothing (Refs. 7, 8, and 9).
    Another factor driving increased consumer exposure to sunscreen 
active ingredients has been the introduction and widespread adoption of 
sunscreen products with higher labeled SPF values. The maximum SPF 
value proposed for sunscreen labeling has progressively increased from 
SPF 15 in the 1978 panel report, to SPF 30+ in the Stayed 1999 Final 
Monograph, to SPF 50+ in the 2011 Max SPF PR. To achieve these higher 
SPFs, many currently marketed products are formulated with more active 
ingredients combined together in higher concentrations than were 
generally combined in products when FDA's review of OTC sunscreens 
began. Increased knowledge about the role of UVA radiation in causing 
skin damage has also encouraged the formulation of broad spectrum 
products with combinations of active ingredients designed to achieve 
protection against both UVA and UVB radiation. In addition, other 
widely used products, such as facial makeup, moisturizing creams, and 
lipsticks, have had sunscreen active ingredients added to their 
formulations. These trends are reflected in the evolution of the 
current labeling provisions for sunscreen products regulated under the 
OTC monograph system.
    Changes in the instructions for using these sunscreen products have 
also contributed to increased use of, and exposure to, sunscreen active 
ingredients. The labeling recommended by the advisory panel in 1978 
simply instructed consumers to apply sunscreen products liberally and 
to reapply after swimming or excess perspiration (43 FR 38206 at 
38215). The labeling currently required, by contrast, encourages 
consumers to always use a broad spectrum SPF 15 or higher product, to 
use sunscreen products regularly, and to apply them generously/
liberally 15 minutes before sun exposure and at least every 2 hours or 
more frequently when swimming or sweating (Sec.  201.327(e)).

B. Emerging Safety Concerns

    In recent years, a growing body of data has suggested that the 
transdermal absorption of some sunscreen active ingredients is greater 
than previously thought, and thus may raise previously unevaluated 
safety concerns, including the potential for reproductive, 
developmental, or carcinogenic effects. As discussed in further detail 
in section VIII.C.1.a, newly available information suggests, for 
example, that there is the potential for toxicity associated with the 
transdermal absorption and systemic availability of oxybenzone. This 
new information about absorption and potential safety risks is 
inadequate, by itself, to support an affirmative conclusion that 
products containing the active ingredients at issue are not safe. 
Coupled with the lack of clinical pharmacology and nonclinical safety 
data for certain sunscreen active ingredients, however, it leads us to 
conclude that, for some sunscreen active ingredients, the current 
record does not include adequate evidence of safety to satisfy the 
applicable legal standards for general recognition of safety and 
effectiveness as set forth in Sec.  330.10.

VII. Framework for Evaluation of Safety Data

    In light of these safety concerns, FDA held a meeting of its 
Nonprescription Drugs Advisory Committee (NDAC) on September 4 and 5, 
2014, to discuss the scope of safety testing that should be conducted 
to support general recognition of safety and effectiveness for active 
ingredients for use in nonprescription sunscreen products. FDA proposed 
the following safety testing paradigm:

Clinical data:
     Dermal irritation and sensitization testing
     Phototoxicity and photoallergenicity testing
     Human maximal use bioavailability studies
     Postmarketing adverse event reports
Nonclinical (toxicology) data:
     Dermal carcinogenicity
     Systemic carcinogenicity
     Developmental and reproductive toxicity (DART)
     Toxicokinetics
     Additional testing when data suggest a concern about other 
long-term effects, such as endocrine effects

There was consensus among the committee members that FDA's proposed 
framework was a good starting point (Ref. 10). In November 2015, FDA 
published a draft guidance for industry, ``Over-the-Counter Sunscreens: 
Safety and Effectiveness Data'' (Draft Safety and Effectiveness Data 
Guidance) (see 80 FR 72975, November 23, 2015), which described and 
requested comment on the safety and effectiveness data necessary to 
determine whether an OTC sunscreen active ingredient or combination of 
active ingredients evaluated under the SIA was GRASE when used under 
specified conditions. FDA finalized this guidance in November 2016, 
after considering public comment on its draft recommendations (Ref. 
11).\11\ The recommendations in this guidance reflect FDA's scientific 
expertise, existing technical guidance, experience from reviewing 
safety and efficacy data submitted for GRASE review of sunscreen active 
ingredients under the OTC Drug Review, and input from and

[[Page 6212]]

concurrence by outside scientific experts.
---------------------------------------------------------------------------

    \11\ FDA's recommendations regarding the safety and 
effectiveness data necessary to determine whether an OTC sunscreen 
active ingredient (or combination of ingredients) evaluated under 
the SIA was GRASE when used under specified conditions generally 
remained unchanged in the final guidance.
---------------------------------------------------------------------------

    All sunscreens marketed without an NDA are subject to the same 
standard: General recognition of safety and effectiveness. Accordingly, 
as noted previously, the data that we expect to be necessary to 
evaluate the safety and effectiveness of the sunscreen monograph active 
ingredients are the same as those we recommended as necessary to 
evaluate the safety and effectiveness of sunscreen active ingredients 
previously considered under the procedures established in the TEA 
regulation and now being considered pursuant to the framework 
established by the SIA (see Safety and Effectiveness Data Guidance 
(Ref. 11)).
    The studies described in this section are generally needed for FDA 
to determine that a sunscreen active ingredient is GRASE for use in 
nonprescription sunscreens. Specific data gaps for individual active 
ingredients depend on the quality and quantity of available safety 
data, and are identified in section VIII. As described in that section, 
those active ingredients for which the existing public record contains 
sufficient data to support a positive GRASE finding are proposed as 
Category I. Those for which additional data are necessary are proposed 
as Category III. In addition, in evaluating the existing safety data 
for the active ingredients listed in the Stayed 1999 Final Monograph, 
FDA determined that the risks associated with two of these ingredients 
outweigh their benefits. As discussed in further detail in section 
VIII.B, FDA is therefore proposing that these two ingredients are 
Category II because sunscreens containing these ingredients would not 
be GRASE.

A. General

    FDA's OTC drug regulations identify the general types of safety 
information that should be submitted as evidence that an OTC drug is 
GRASE for use as labeled (Sec.  330.10(a)(2)) and the standard by which 
safety is to be judged (Sec.  330.10(a)(4)(i)). When applying these 
regulations to each drug, FDA uses its scientific expertise to 
determine what constitutes ``adequate tests by methods reasonably 
applicable to show the drug is safe under the prescribed, recommended, 
or suggested conditions of use'' (Sec.  330.10(a)(4)(i)).
    FDA recognizes the contribution that broad spectrum sunscreens with 
an SPF value of 15 or higher can make to decreasing the risk of skin 
cancer and early skin aging caused by the sun if used as directed with 
other sun protection measures. To protect the public health, however, 
it is also important for FDA to balance the potential benefits of these 
sunscreen products to consumers against their potential risks. 
Providing an adequate safety margin for OTC sunscreen active 
ingredients and finished sunscreen products is a key element of FDA's 
risk assessment. A safety margin calculation takes the highest animal 
NOAEL and estimates a maximum safe level of exposure for humans. 
Because animal studies do not always predict effects in humans, the 
actual threshold for an effect in humans may be different (i.e., higher 
or lower) than in the species tested. The human sensitivity to a drug 
is often unknown. To account for this, the predicted safe exposure 
level in humans that is reflected in the safety margin is well below 
where toxicities were seen in animals.
    In determining the specific testing and other data needed to 
adequately demonstrate that an OTC sunscreen active ingredient is safe, 
FDA considers both the circumstances under which OTC sunscreen products 
are intended to be used by consumers (i.e., the conditions of use) and 
current scientific knowledge and assessment technology. FDA's approach 
to the clinical safety evaluation of OTC sunscreen active ingredients 
is based on our current scientific understanding regarding safety 
evaluation of topical drug products for chronic use, and thus is 
generally consistent with the safety data requirements that would apply 
to an NDA for a chronic-use topical drug product (i.e., topical safety 
studies (irritation, sensitization, and photosafety); bioavailability 
(absorption); and evaluation of adverse events observed in clinical 
studies).\12\ In addition, the evaluation of adverse events reported 
during the commercial marketing of sunscreen products containing the 
ingredient and other postmarketing safety information is also relevant 
to safety.
---------------------------------------------------------------------------

    \12\ Chronic use is defined as continuous or intermittent use 
for at least 6 months during the course of a lifetime.
---------------------------------------------------------------------------

    FDA's approach to the nonclinical safety evaluation of these active 
ingredients takes into account their lengthy marketing history in the 
United States. In contrast to nonclinical data requirements for a 
chronic-use topical drug product NDA, which include results from 
comprehensive nonclinical pharmacology and toxicology safety testing, 
the approach to nonclinical safety testing in this proposed rule is 
largely focused on potential long-term adverse effects or effects not 
otherwise readily detected from human use (i.e., carcinogenicity and 
reproductive toxicity). Additional testing beyond what is described 
below may be recommended for active ingredients for which data suggest 
a concern about other long-term effects, such as hormonal disruption.
    In addition, although sunscreen products are typically formulated 
with two or more active ingredients, the framework described below 
contemplates that testing will be performed using formulations that 
include one active ingredient. Generally, unless data suggest that 
there may be a safety or efficacy concern with a particular combination 
of active ingredients, we anticipate that an active ingredient that is 
found to be GRASE for use in sunscreens could be combined with other 
active ingredients that are also GRASE for use in sunscreens. If data 
suggest that there may be a safety or efficacy concern with a 
particular combination of active ingredients (or active and inactive 
ingredients), additional data may be necessary to support a positive 
GRASE determination for sunscreens containing that combination.
    The following sections describe the specific safety data that FDA 
expects the Agency will need to determine whether an active ingredient 
is GRASE for use in sunscreens.

B. Clinical Safety Testing

1. Human Dermal Safety Studies
    Human dermal safety studies for topical products in which exposure 
to light after application is anticipated generally consist of two sets 
of studies--those conducted without specific exposure to light and 
those conducted to assess reactions after UV exposure (photosafety 
studies) (Ref. 12). The studies usually consist of dermal irritation 
patch testing, dermal sensitization patch testing, dermal phototoxicity 
testing, and dermal photoallergenicity testing.
    Because marketed sunscreen products typically contain a combination 
of active ingredients, and product formulations frequently change, it 
is difficult to determine causal links between individual active 
ingredients and reported irritation and hypersensitivity adverse events 
associated with a particular product. Therefore, FDA generally expects 
to use data from human dermal irritation studies, human dermal 
sensitization studies, and human dermal photosafety studies, in 
conjunction with postmarketing adverse event data, to inform GRASE 
determinations and labeling. Nonetheless, in some cases, it may be 
reasonable to omit human

[[Page 6213]]

dermal irritation studies, human dermal sensitization studies, and/or 
human dermal photosafety studies, depending on the rigor of available 
postmarketing safety information. For example, if FDA concludes that 
there is a positive risk-benefit profile for a sunscreen active 
ingredient, but that it is known to be a sensitizer, it may be possible 
to develop safety labeling to address this risk without data generated 
in the human dermal safety studies described below (see, e.g., section 
VIII.C.1.a).
    a. Human dermal irritation and sensitization studies. Studies of 
dermal irritation and sensitization, using the repeat insult patch test 
or other relevant tests, are elements in the safety evaluation of 
topical drug products that, like sunscreens, are applied to the skin 
repeatedly over long periods of time. Designed to detect the potential 
for local dermatologic events with fewer subjects than might be 
observed in larger clinical trials, these tests often employ product 
application that is more frequent and/or for longer duration than 
proposed clinical dosing. In dermal irritation studies, a test 
substance is applied to a small pad (patch) and affixed to the test 
subject's skin, usually on the back, to determine whether the 
ingredient causes direct skin toxicity. Dermal sensitization studies 
are conducted similarly but are designed to detect immunologically 
mediated reactions, which require prior exposure to the allergen.
    Nonprescription sunscreens regulated under the OTC monograph system 
may be used in many product formulations, including those yet unknown. 
Therefore, cumulative irritation studies that evaluate the sunscreen 
active ingredient at the highest concentration for which a GRASE 
determination is sought should be conducted using the ingredient in an 
appropriate vehicle, using the vehicle alone, and using both negative 
and positive controls. The evaluation should include scoring of 
erythema, edema, and a papular response or skin erosion.
    Dermal sensitization studies, conducted to detect immunologically 
mediated reactions, should be conducted in three phases: (1) The 
induction phase (3 weekly applications for 3 weeks); (2) the rest phase 
(no product application for 10 to 14 days); and (3) the challenge phase 
(patch applications to new sites for 48 hours with a confirmatory 
rechallenge to exclude false positives).
    Although FDA recommends separate dermal irritation and 
sensitization studies, it may be appropriate to combine irritation and 
sensitization studies in the same study as long as a sufficient number 
of subjects are included for sensitization evaluation.
    b. Human photosafety studies. Topically applied dermatologic drug 
products should be tested for photosafety if they absorb light in the 
UVA, UVB, or visible spectra. Photosafety evaluations of sunscreen 
active ingredients that absorb light should consist of skin 
photoallergenicity and skin phototoxicity testing. Photoallergy is an 
immunologically mediated reaction to a chemical, initiated by the 
formation of photoproducts (e.g., protein adducts) following a 
photochemical reaction. Similar to dermal sensitivity testing described 
above, photoallergy tests use an induction/rest/challenge/rechallenge 
multiphase design to assess erythema, edema, and vesiculation. 
Phototoxicity (or photoirritation) is an acute light-induced tissue 
response to a photoreactive chemical. Phototoxicity testing typically 
includes a test patch, a vehicle patch, and a sham patch application 
for 24 hours, followed by UV light exposure of the test area. A second 
set of patch application areas not irradiated with light serves as a 
control. FDA expects that, to support a GRASE finding, photosafety 
studies of sunscreen active ingredients that absorb light will need to 
be conducted using the active ingredient at the highest concentration 
for which a GRASE determination is sought in an appropriate vehicle, 
using the vehicle alone, and with a negative control.
2. Human Absorption Studies/Maximal Usage Trial
    Because nonprescription sunscreens are topically applied, a 
critical safety consideration is whether dermal application results in 
skin penetration and systemic exposure to their active ingredients and, 
if so, to what extent. This information helps identify potential safety 
concerns and helps determine whether an adequate safety margin exists 
within which an active ingredient is GRASE for use in sunscreens.
    The principal barrier to topical drug product penetration is the 
multilayered, lipid-rich stratum corneum. The passage of any drug 
product through this layer is influenced by many factors, including the 
drug product's physicochemical features, molecular weight, and vehicle/
formulation properties. Vehicle/formulation properties are particularly 
important because the choice of vehicle can markedly affect the 
permeation potential of a drug product. Effects can range from simple 
hydration of the stratum corneum by occlusive vehicles/formulations to 
direct permeation enhancement by solvent effects on the lipids in the 
stratum corneum. Products absorbed through the skin have the potential 
to cause systemic adverse effects, affecting the safety assessment. 
Because sunscreens are intended to work at the skin's surface, systemic 
absorption may also lower efficacy, affecting the efficacy assessment. 
Such considerations ultimately weigh into the risk-benefit calculus FDA 
uses to determine whether an OTC sunscreen containing a given active 
ingredient is GRASE.
    Since the mid-1990s, topical product NDAs have included a Maximal 
Usage Trial (MUsT) as part of the clinical pharmacology/bioavailability 
assessment. A MUsT is designed to capture the effect of maximal use on 
absorption into the blood with standard pharmacokinetic assessments 
(e.g., Cmax, Tmax,\13\ area under the curve, 
half-life, clearance, and volume of distribution) (for further 
information about conduct of a MUsT, see Ref. 13). For a topical 
product NDA, the MUsT is usually conducted in subjects with the disease 
of interest, where disrupted skin is a feature. In situations where 
disrupted skin is not a feature of the condition being treated or the 
topical product is intended for prevention of disease (e.g., 
sunscreens), the MUsT for a topical product NDA should be conducted in 
subjects with healthy, intact skin. The MUsT for a topical product NDA 
is conducted with the specific product formulation for which approval 
is sought applied at the upper limit of surface area involvement that 
is studied in the phase 3 clinical trials and is proposed for labeling. 
For example, if the proposed labeling of an acne product permits the 
product to be used on up to 30 percent of body surface area, that would 
be the coverage evaluated in the MUsT.
---------------------------------------------------------------------------

    \13\ Cmax is the peak plasma concentration and 
Tmax is the time to peak plasma concentration.
---------------------------------------------------------------------------

    We expect that data from a MUsT will be needed to support an 
adequate assessment of safety for most sunscreen active ingredients 
(Ref. 10). Because sunscreen products regulated pursuant to the OTC 
monograph system may include active ingredients in a variety of 
formulations, FDA recommends that a MUsT be conducted under maximal use 
conditions employing a minimum of four formulations, containing the 
sunscreen active ingredient as the only active ingredient.\14\ These 
formulations

[[Page 6214]]

should be prepared using vehicle/formulation systems that are 
appropriate for sunscreen topical products (e.g., they are deployable 
and spreadable) that represent real-world marketed formulations, and 
that are expected to produce the highest in vivo absorption. 
Justification for the formulations chosen, including results of in 
vitro testing using a human cadaver skin permeation system (e.g., 
static cell, also known as vertical diffusion cell) (Refs. 14 and 15), 
should be included in the study protocol. The protocol should contain 
sufficient detail for others to reproduce the formulations and 
manufacturing process.\15\
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    \14\ We note, however, as described in section VIII.C.1.b, that 
because of avobenzone's potential for photodegradation, we recommend 
that a MUsT for avobenzone evaluate avobenzone in combination with a 
photostabilizer. In some cases, sunscreen active ingredients (e.g., 
octocrylene) can serve as photostabilizers. In such cases, we expect 
that the MUsT could include such ingredients.
    \15\ FDA has issued draft guidance with recommendations for the 
conduct of MUsT studies to support the safety of active ingredients 
that are candidates for inclusion in a topical drug product under an 
OTC Drug monograph (Ref. 16). When finalized, this guidance will 
represent FDA's current thinking on this topic. FDA also encourages 
persons who are interested in conducting a MUsT to support the 
safety of an active ingredient to discuss proposed protocols with 
the Agency.
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    FDA anticipates that the use of multiple formulations will help 
identify the overall absorption potential of the sunscreen active 
ingredient of interest. The MUsT should be conducted in subjects with 
healthy, intact skin \16\ at the highest concentration of the 
ingredient for which a GRASE determination is sought. Based on 
recommended sunscreen use on all exposed skin, the exposed area should 
include at least 75 percent of the body surface area. Data from the 
formulation that produces the highest in vivo absorption would then be 
used to determine the safety margin.
---------------------------------------------------------------------------

    \16\ As discussed infra, the MUsT should be conducted on 
healthy, intact skin because sunscreens are intended for prevention 
rather than treatment.
---------------------------------------------------------------------------

    The assay used in the MUsT should be properly validated according 
to current good laboratory practices (21 CFR part 58). Additionally, 
the Agency's most current guidance on bioanalytical method validation 
may be found by searching at https://www.fda.gov/RegulatoryInformation/Guidances/default.htm. The assay's limit of quantitation-limit of 
detection should be sufficiently low to allow a signal-to-noise ratio 
that ensures confidence in detection of a concentration of 0.5 nanogram 
(ng)/milliliter (mL) for the compound of interest in the receptor 
fluid.
    An important consideration for designing a MUsT is that it should 
include testing for a duration that allows for the attainment of steady 
state levels to ensure that maximum penetration of the ingredient has 
taken place and to optimize the chances of the ingredient being 
detected. Thus, for sunscreen active ingredients, FDA expects that 
single application studies would be inadequate. Because the subjects in 
a MUsT represent an enriched dataset in the upper range of exposures, 
safety-related data (such as vital signs, adverse events) from the 
study's regularly scheduled physical examinations should also be 
collected. We strongly encourage consultation with FDA about MUsT 
protocols before beginning the trial.
    Finally, as discussed further in section VIII.D, if the sunscreen 
active ingredient is determined to be GRASE for use in sunscreens, the 
sunscreen monograph, when finalized, must set out the conditions under 
which any future sunscreen containing that active ingredient will be 
GRASE and not misbranded. As such a condition, FDA is considering 
certain final formulation testing to address the potential for 
transdermal absorption and its impact on safety. FDA anticipates that 
the formulation that produces the highest in vivo absorption in the 
MUsT would be appropriate to designate as a standard control 
formulation for future in vitro human cadaver skin permeation system 
testing (e.g., a static or vertical diffusion cell) of each final 
sunscreen formulation that includes that active ingredient. If such 
testing were included as a condition in a final sunscreen monograph, 
and if in vitro permeation of the sunscreen active ingredient in the 
final product formulation were equal to or less than the value from in 
vitro testing of the standard control formulation (that was shown by 
the MUsT to have the highest degree of systemic absorption), FDA 
anticipates that the safety margin previously calculated would be 
considered adequate to support the safety of the finished formulation.
3. Pediatric Considerations
    Young children have a larger ratio of skin surface to body volume 
than adults, which can increase a child's systemic exposure to 
topically applied drug products. In addition, growing children have 
greater potential to experience deleterious developmental effects from 
drug exposure. If the calculated safety margin for an active ingredient 
(based on nonclinical results and human MUsT) is relatively small, FDA 
will exercise its scientific judgment to determine whether a sunscreen 
active ingredient MUsT in young children or other studies are warranted 
to ensure that the safety margin for marketed products containing the 
ingredient is within an acceptable range for this population.

C. Nonclinical Safety Testing

1. Carcinogenicity Studies: Dermal and Systemic
    FDA generally recommends carcinogenicity studies for any 
pharmaceutical with an expected clinical use (either intermittent or 
continuous) of at least 6 months (Ref. 17). The animal carcinogenicity 
studies help characterize the potential tumor risks associated with use 
of a sunscreen active ingredient in human beings by identifying any 
observed tumors by type, the level of exposure at which tumors occur, 
and the highest level of exposure at which no adverse effects occur, 
referred to as the NOAEL. As noted earlier, FDA intends to use the 
NOAEL in determining the safety margin for human exposure to sunscreens 
containing the active ingredient. In addition to detecting carcinogenic 
potential, carcinogenicity studies in animals can also help to identify 
other systemic or organ toxicities that may be associated with the 
sunscreen active ingredient.
    FDA expects that a dermal carcinogenicity study involving 
application of the test article to the skin of mice or rats for 2 years 
will thus need to be conducted to support a GRASE finding for the 
active ingredient unless the ingredient has been demonstrated not to 
reach the viable layers of the skin where it could impact skin tumor 
development. FDA also considers it important to study the effects of 
systemic exposure if human bioavailability data show that dermal 
application of a particular formulation results in skin penetration and 
systemic exposure to the active ingredient. Therefore, we expect that a 
second carcinogenicity study by a route that produces systemic exposure 
will also be needed to support the safety of a sunscreen active 
ingredient, if systemic exposure is observed in the bioavailability 
data. This can be a 2-year study or a shorter (usually 6 months) 
alternative carcinogenicity model, and it should be conducted in a 
species different from that used in the dermal carcinogenicity study. 
FDA notes that the absence of a carcinogenicity signal from an 
alternative transgenic carcinogenicity study (e.g., TgRasH2 mouse) 
would likely support the safety of a sunscreen active ingredient. If a 
carcinogenicity signal were observed in such a study, however, the 
study could not be used to support the safety of a sunscreen active 
ingredient because there would be no basis for calculating

[[Page 6215]]

a safety margin with this study (Ref. 18). All carcinogenicity studies, 
regardless of route, should assess a full panel of tissues.\17\
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    \17\ FDA recommends submitting the carcinogenicity study 
protocol(s) for review by FDA's Center for Drug Evaluation and 
Research's (CDER's) Executive Carcinogenicity Assessment Committee 
before initiating the studies. For further guidance regarding 
carcinogenicity studies, see the FDA guidance for industry 
``Carcinogenicity Study Protocol Submissions,'' May 2002 (available 
at https://www.fda.gov/ucm/groups/fdagov-public/@fdagov-drugs-gen/documents/document/ucm078924.pdf).
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    FDA expects that a systemic carcinogenicity study would not be 
needed to support a GRASE determination for a sunscreen active 
ingredient if an adequately conducted human pharmacokinetic MUsT 
resulted in a steady state blood level less than 0.5 ng/mL, and an 
adequately conducted toxicology program did not reveal any other safety 
signals for the ingredient or any known structurally similar compound 
indicating the potential for adverse effects at lower levels. The 
threshold value of 0.5 ng/mL is based on the assessment that the level 
would approximate the highest plasma level below which the carcinogenic 
risk of any unknown compound would be less than 1 in 100,000 after a 
single dose. This threshold value is consistent with the Threshold of 
Toxicological Concern concept, which was applied to impurities in the 
ICH guidance for industry ``M7 Assessment and Control of DNA Reactive 
(Mutagenic) Impurities in Pharmaceuticals to Limit Potential 
Carcinogenic Risk'' (Ref. 19). FDA expects that the 0.5 ng/mL 
concentration will be sufficiently above the assay's limit of 
quantitation--limit of detection to allow a signal-to-noise ratio that 
ensures confidence in either the derived concentrations (in the case of 
``exaggerated'' values) or lack of concentrations.
2. Developmental and Reproductive Toxicity Studies
    FDA expects that DART studies will need to be conducted to evaluate 
the potential effects that exposure to the sunscreen active ingredient 
may have on developing offspring throughout gestation and postnatally 
until sexual maturation, as well as on the reproductive competence of 
sexually mature male and female animals (Ref. 20). As with systemic 
carcinogenicity studies, we expect that studies to assess fertility and 
early embryonic development, and pre- or postnatal toxicity in rats 
will not be needed if an adequately conducted human MUsT shows a steady 
state blood level less than 0.5 ng/mL, and an adequately conducted 
toxicology program produces no signals indicating that the ingredient 
(including its clinically relevant metabolites) or any known 
structurally similar compound interacts with related pathways.\18\ We 
expect that effects on embryofetal development will need to be assessed 
in rats and rabbits in all cases.
---------------------------------------------------------------------------

    \18\ Examples of such pathways could include endocrine function 
and signaling pathways related to growth and development.
---------------------------------------------------------------------------

    Gestational and neonatal stages of development may be particularly 
sensitive to active ingredients with hormonal activity (endocrine 
disruption). For this reason, these studies should include assessments 
of endpoints such as vaginal patency, preputial separation, anogenital 
distance, and nipple retention, which can be incorporated into 
traditional DART study designs to assess potential hormonal effects on 
the developing offspring. Behavioral assessments (e.g., mating 
behavior) of offspring, which may detect neuroendocrine effects, should 
also be performed (Ref. 21).
3. Toxicokinetics (Ref. 22)
    Animal toxicokinetic data should also be collected for sunscreen 
active ingredients, as these data provide an important bridge between 
toxic levels seen in animal studies and any potential human adverse 
events associated with systemic exposure to the sunscreen's active 
ingredient. Toxicokinetic measurements are usually obtained during the 
course of ongoing nonclinical toxicity studies, such as carcinogenicity 
or DART studies, rather than through separate studies.

D. Postmarketing Safety Data

    In addition to the active ingredient safety data already described, 
FDA's GRASE evaluation also takes into consideration publicly available 
information about serious adverse drug experiences and known or 
expected adverse effects associated with commercially marketed products 
that contain the active ingredient(s) under consideration.

E. Sunscreens Containing Nanomaterials

    We note that FDA is not proposing to categorically classify 
sunscreen products manufactured using nanotechnology (or containing 
nanomaterials) as GRASE or not GRASE solely based on this 
characteristic. Nanotechnology is used to create, explore, or 
manipulate materials measured in nanometers (nm) (billionths of a 
meter), and has applications in a wide range of products, including OTC 
sunscreens. Such materials generally have dimensions between 
approximately 1 and 100 nm (Ref. 23). Materials at such small sizes can 
have different chemical or physical properties or biological effects 
compared to larger-scale counterparts, making possible a variety of 
functional effects, and also potentially affecting the safety, 
effectiveness, or regulatory status of FDA-regulated products.
    FDA has not established regulatory definitions of nanotechnology, 
nanomaterial, nanoscale, or other related terms. As described in FDA's 
guidance for industry ``Considering Whether an FDA-Regulated Product 
Involves the Application of Nanotechnology'' (Nanotechnology 
Considerations Guidance) (Ref. 24), at this time, when considering 
whether an FDA-regulated product involves the application of 
nanotechnology, FDA asks
    (1) Whether a material or end product is engineered to have at 
least one external dimension, or an internal or surface structure, in 
the nanoscale range (approximately 1 nm to 100 nm).
    In addition, because materials or end products can also exhibit 
related properties or phenomena attributable to a dimension(s) outside 
the nanoscale range of approximately 1 nm to 100 nm that are relevant 
to evaluations of safety, effectiveness, performance, quality, public 
health impact, or regulatory status of products, we will also ask:
    (2) Whether a material or end-product is engineered to exhibit 
properties or phenomena, including physical or chemical properties or 
biological effects, that are attributable to its dimension(s), even if 
these dimensions fall outside the nanoscale range, up to 1 micrometer 
([micro]m) (1,000 nm).
    We will apply these considerations broadly to all FDA-regulated 
products, including sunscreen products. For the purpose of this 
proposed rule, we use the term ``nanomaterial'' generally to refer to 
materials falling within either point 1 or 2 above. The use of this 
term in this manner is consistent with its use in FDA's nanotechnology-
related guidances, including FDA's Nanotechnology Considerations 
Guidance.
    Nanomaterial forms of the active ingredients zinc oxide and 
titanium dioxide have been used in marketed OTC sunscreens. In addition 
to nanomaterial forms of zinc oxide and titanium dioxide, other 
nanomaterials are also reported to have been used, or promoted or 
studied for possible use, in sunscreen products (Ref. 25).

[[Page 6216]]

    As discussed in further detail in section VIII.A, having examined 
the scientific information in the record, including for nanomaterial 
forms of zinc oxide and titanium dioxide, FDA is not now proposing 
conditions of use for these two active ingredients under the sunscreen 
monograph that distinguish nanomaterials from other forms of these 
ingredients. As indicated above, FDA also does not propose to 
categorically classify sunscreen products that are manufactured using 
nanotechnology or contain nanomaterials as GRASE or not, solely on that 
basis. Manufacturers of products containing nanomaterials marketed 
under the OTC sunscreen monograph remain responsible for ensuring that 
the product satisfies all applicable legal requirements. FDA encourages 
manufacturers of such products to consult with FDA to facilitate a 
mutual understanding of specific scientific or regulatory issues 
relevant to their product.
    FDA invites comment on the following topics:

 Specific nanomaterials or types of nanomaterials that have 
been used or proposed for use in OTC sunscreen products
 Concerns about sunscreen product safety, effectiveness, or 
quality associated with the use of nanomaterials in OTC sunscreen 
products, with supporting data
 Need for, and proposals of, specifications or limitations for 
particular nanomaterials for use in OTC sunscreen products
 Any particular nanomaterials that you believe should not be 
permitted for use in OTC sunscreen products, along with supporting 
scientific information
 FDA's proposed regulatory approach and/or alternative 
regulatory approaches to the use of nanomaterials in OTC sunscreen 
products

VIII. Existing Safety Data for Sunscreen Active Ingredients

    In the remainder of this section, we discuss the existing data and 
data gaps for each of the sunscreen monograph active ingredients and 
explain why we propose that these active ingredients are GRASE or not 
GRASE for use in sunscreens. Those ingredients for which the existing 
data are sufficient to support a positive GRASE determination are 
proposed as Category I. Those ingredients for which additional data are 
necessary before a GRASE determination can be made are proposed as 
Category III. In cases where FDA's evaluation of the existing safety 
data caused us to determine that the risks associated with the 
ingredients outweigh their benefits, the ingredients are proposed as 
Category II.

A. Ingredients Proposed as Category I

    Based on our review of the publicly available data for these 
ingredients, both zinc oxide and titanium dioxide are proposed as 
Category I.
1. Zinc Oxide
    Our review of the scientific literature, submissions to the 
sunscreen monograph docket, and adverse event reports submitted to 
FAERS has produced sufficient safety data on zinc oxide to support a 
proposal that a sunscreen containing up to 25 percent zinc oxide would 
be GRASE under the conditions proposed in this rulemaking and the 
general conditions required in part 330. This proposal is based in 
significant part on the existing, substantial evidence that zinc oxide 
(including particles on the nanoscale, i.e., approximately 1 to 100 nm) 
does not penetrate into or through human skin to any great extent and, 
to the extent any de minimis penetration occurs, does not result in 
adverse health effects, given the high levels of endogenous zinc in the 
human system.
    a. Background. Zinc oxide is an inorganic, mineral compound. 
Because of its ability to reflect UVA wavelengths, zinc oxide is 
frequently used in sunscreens to help establish broad spectrum 
protection (Ref. 26). While larger particles of zinc oxide used in 
sunscreens (greater than approximately 100 nm) may impart an opaque, 
white color to the product, zinc oxide is also manufactured in smaller 
particle sizes (less than approximately 100 nm) to reduce this white/
opaque appearance (Refs. 27 and 28). In addition to its use in 
sunscreens, zinc oxide is also used in non-sunscreen ointments, pastes, 
and lotions for various skin disorders because of its protective, 
astringent, and antiseptic properties (Ref. 29).
    b. Discussion. Zinc oxide is insoluble in water and largely 
insoluble in biological fluids.\19\ This insolubility precludes the 
possibility of its systemic absorption from topical application of 
sunscreen products beyond a de minimis amount, even if zinc oxide is 
included at its maximum eligible concentration of 25 percent and 
regardless of the formulation of the product. The available studies on 
the dermal penetration of zinc oxide, further discussed below, confirm 
that its penetration--regardless of particle size--is primarily limited 
to the upper layers of the non-living stratum corneum, with most 
penetration occurring only into skin folds and furrows or hair 
follicles. These studies show that zinc oxide particles do not 
penetrate down into the viable dermis to any significant extent. Any de 
minimis transdermal penetration that may occur does not result in 
adverse health effects, because the tiny amount of zinc oxide particles 
that achieve transdermal absorption, if any, would dissociate into zinc 
and oxygen ions, both of which are naturally occurring elements in the 
human body (Ref. 30). Zinc is the 14th most common element in the human 
body and is essential for all living things; the average human body 
contains about 2.0 to 2.5 grams of zinc, and normal dietary intake of 
zinc is about 15 milligram (mg) per day (Refs. 30 and 31). Homeostatic 
mechanisms in the body regulate zinc's absorption, distribution, 
cellular uptake, and excretion (Ref. 31). Similarly, any oxygen 
absorbed through the skin is nonharmful, as oxygen is plentiful in the 
human body and essential for life.
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    \19\ We note that nanoscale zinc oxide can be solubilized to a 
small extent in the presence of phosphate and lecithin at pH's that 
are achievable on the skin. Even under these conditions, however, 
the amount potentially absorbed is de minimis and far lower than 
daily nutritional intake of zinc.
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    Our search of the literature on zinc oxide revealed four recent 
studies about zinc oxide's penetration into human skin, which confirm 
our expectations based on the physical properties of this compound. The 
first two studies (conducted by Leite-Silva et al. and Darvin et al.) 
examined the penetration of zinc oxide into the skin using multiphoton 
tomography (Refs. 32 and 33). Both studies showed a lack of overall 
permeation of zinc oxide beyond a few cell layers, except in the case 
of furrows and wrinkles (Refs. 32 and 33). The second two studies--a 
pilot and subsequent full trial conducted by Gulson et al.--evaluated 
the penetration of nanoscale zinc oxide into the skin and the 
bloodstream using a stable isotope tracing method (Refs. 34 and 35). 
Although the Gulson studies found that a minimal amount of topically 
applied zinc was absorbed, the absorption observed was at levels that 
are orders of magnitude less than daily nutritional intake and well 
below what would be of concern for a naturally occurring element in the 
body subject to homeostatic mechanisms (Ref. 36). An additional porcine 
study found (as discussed in our 2012 response to a citizen petition 
submitted by the International Center for Technology Assessment and 
others (Docket No. FDA-2006-P-0213-0003) (ICTA Petition Response)), 
that although sunburn caused by UVB rays increased the penetration of 
zinc oxide into the

[[Page 6217]]

non-living stratum corneum, there remained minimal penetration of zinc 
oxide into the epidermal and dermal layers of the skin (Ref. 37). 
Because topically applied zinc oxide particles do not enter systemic 
circulation to any meaningful extent, we do not consider a MUsT to be 
necessary to support the safety of this ingredient.
    In addition to the studies described above, we also located two 
studies evaluating the clinical safety of topically applied zinc oxide 
in which zinc oxide (25 percent) was used as a medicated occlusive 
dressing on the lower arms of healthy volunteers (Refs. 38 and 39). In 
these studies (which were designed to maximize potential absorption and 
identify any resulting adverse events), even with the increased dermal 
or epidermal zinc levels resulting from occlusion, there still were no 
adverse skin events. Our review of the available human dermal safety 
studies on zinc oxide \20\ also identified data showing that test 
material containing up to 25 percent zinc oxide did not induce human 
irritant, photoirritant, allergic, or photoallergic reactions. No human 
pathological phototoxicity or significant human photosensitization 
reaction indicative of skin irritation were noted either. The 
literature supporting the safety of skin protectant drug products 
containing zinc oxide \21\ reinforce these clinical safety findings. 
Our review in this area is also consistent with the conclusion of the 
European Commission's Scientific Committee on Consumer Safety that the 
use of nanoscale zinc oxide in sunscreens at a concentration of up to 
25 percent does not pose a risk of adverse effects in humans after 
topical application (Ref. 40).
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    \20\ This literature included three clinical safety studies 
conducted by Hill Top Research, Inc. for Procter & Gamble regarding 
(a) human sensitization (Study Reports 96-6635-76a and 96-6635-76b); 
(b) human photoirritation/phototoxicity (Study Report 96-6634-76); 
and (c) human photoallergenicity (Study Report 96-6633-76). See 
Citizen Petition submitted by Proctor & Gamble, June 24, 1997 (FDA-
1978-N-0018-0639) and the ``Opinion concerning Zinc Oxide'' drafted 
by the European Commission, Scientific Committee on Cosmetic 
Products and Non-Food Products Intended for Consumers (SCCNFP), 
which included five summaries of human clinical safety studies, all 
evaluating zinc oxide 25 percent (Ref. 40).
    \21\ See, e.g., Beeckman et al. (Ref. 41); 43 FR 34628 at 
34641(August 4, 1978) (discussing use of zinc oxide 1 percent to 25 
percent as a skin protectant active ingredient: ``Zinc oxide is 
widely recognized as a skin protectant'' and ``No reports of topical 
toxicity were found in the literature'' on zinc oxide).
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    A very small number of rash and hypersensitivity reports for 
sunscreens containing zinc oxide were located in FAERS. With a single 
exception, the sunscreens involved contained two or more active 
ingredients, making it difficult to attribute causation to a specific 
active ingredient. Unlike other sunscreen ingredients with a known 
hypersensitivity risk, we did not identify any reports in FAERS or in 
the literature with features suggestive of a causative link, such as 
skin test results positive for zinc oxide. In addition, there is an 
extremely large safety database of zinc oxide use in other topical 
products, including for the treatment of diaper rash in infants. This 
corroborates the negative results in human studies for irritation, 
photoirritation, allergy, and photoallergy that support our proposed 
finding regarding the safety of sunscreens containing this ingredient 
under the conditions proposed. Reports of non-hypersensitivity-related 
clinical safety issues with zinc oxide were infrequent and not serious. 
For these reasons, we do not consider additional clinical studies 
(including photosafety, irritation, or sensitization studies) to be 
necessary for this ingredient.
    Dermal carcinogenicity studies have not been conducted for zinc 
oxide. In general, as discussed in section VII.C.1, adequate tests for 
safety of an active ingredient for use in topical products for chronic 
use (such as a sunscreen) would need to include dermal carcinogenicity 
studies if the active ingredient reaches the viable layers of skin 
where it could have a biological effect. Given the minimal penetration 
of zinc oxide below the non-living stratum corneum, there is no 
plausible mechanism by which zinc oxide could have an effect on skin 
tumor development. We are therefore proposing to find that zinc oxide 
is GRASE for use in sunscreens despite the lack of dermal 
carcinogenicity studies studying this ingredient.
    Based on the minimal systemic exposure resulting from dermally 
applied zinc oxide, in particular when compared to endogenous zinc 
levels, we see no need for further nonclinical studies to support the 
safety of sunscreens containing zinc oxide, including systemic 
carcinogenicity studies, developmental and reproductive toxicity 
studies, or toxicokinetic studies.\22\
---------------------------------------------------------------------------

    \22\ Our review of the available nonclinical safety literature 
on zinc oxide included references for a 90-day dermal toxicity 
study, genotoxicity, and limited developmental and reproductive 
toxicity information. The review of this literature suggests that 
genotoxicity, findings for zinc oxide are mixed, and that there is 
minimal dermal toxicity in rodents after 90 days. (See Refs. 42 and 
43.) Oral rat embryofetal toxicity studies showed some adverse 
maternal and fetal effects, but only at very high doses (>200 mg/kg/
day) significantly higher than what is at issue here (Refs. 44 and 
45).
---------------------------------------------------------------------------

    c. Conclusion. Our review of the available data from both animal 
and human studies and data on physical properties such as solubility 
leads us to conclude that the transdermal absorption of zinc oxide--
regardless of particle size--from any topically applied sunscreen 
formulation is extremely unlikely, and that any de minimis absorption 
that may occur would not result in adverse health effects, given the 
high levels of endogenous zinc. The very low likelihood of any systemic 
absorption of zinc oxide in turn indicates that the safety margin for 
zinc oxide is large; accordingly, consistent with our approach to 
pediatric studies discussed in section VII.B.5, we do not consider 
pediatric studies to be needed for this ingredient. We propose to find 
that the currently available safety data provide sufficient evidence to 
demonstrate the minimal absorption, low dermal irritation, low 
allergenic sensitization and photoallergenicity, and low phototoxic 
potential of zinc oxide--regardless of particle size--up to 25 percent, 
and that these data support a finding that zinc oxide up to 25 percent 
is GRASE for use in sunscreens under the proposed conditions. 
Accordingly, we propose that zinc oxide is a Category I active 
ingredient.
2. Titanium Dioxide
    For similar reasons, we propose that titanium dioxide is also a 
Category I active ingredient. Our review of information publicly 
available in the scientific literature, submissions to the sunscreen 
monograph docket, and FAERS has produced sufficient information to 
support a proposal that a sunscreen product containing up to 25 percent 
titanium dioxide would be GRASE under the conditions proposed in this 
rulemaking and the general conditions required in part 330.
    a. Background. Titanium dioxide is an inorganic mineral compound 
consisting of small, crystalline-structured or amorphous particles. It 
is widely used as an excipient and is currently listed as an inactive 
ingredient in more than 60 approved drug products (including topical, 
oral, and inhalation products, among others) (Ref. 46). Titanium 
dioxide particles can be manufactured to have a variety of different 
dimensions, shapes (such as spheres or rods), and crystal polymorphs 
(such as anatase or rutile). Titanium dioxide (typically with particle 
dimensions ranging from 200 to 300 nm) is manufactured as a white 
powder for use as a white color pigment in pharmaceuticals. 
Manufacturers have also introduced processes that produce

[[Page 6218]]

titanium dioxide with particle dimensions ranging from 15 to 50 nm to 
reduce its white/opaque appearance. Titanium dioxide particles used in 
sunscreens are also now often treated with chemical coatings (such as 
silicones, metal oxides, or organic acids) that are bonded to the 
exterior surface of the particles to, among other things, improve the 
aesthetic characteristics of the final formulation.
    b. Discussion. Titanium dioxide is essentially insoluble in water 
and in biologic fluids (Ref. 47). As with zinc oxide, this lack of 
solubility prevents the transdermal absorption of more than a de 
minimis amount of titanium dioxide, regardless of either the 
concentration of titanium dioxide or the formulation of the product 
(Refs. 48 and 49). Further, unlike zinc oxide, which, if dissolved, 
would dissociate into zinc and oxygen (Ref. 50), the chemical stability 
of titanium dioxide is such that it does not dissociate under the 
conditions that exist in (or on) the human body (Ref. 51). Even if 
titanium dioxide were to dissociate into titanium and oxygen, titanium 
is unreactive in physiologic conditions, and (for this, among other, 
reasons) is frequently used in medical devices and structures implanted 
in the human body (Refs. 51 and 52).
    The available studies on the transdermal absorption of titanium 
dioxide confirm that the skin is an effective barrier to the 
penetration of titanium dioxide, regardless of particle size--including 
those on the nanoscale (Refs. 53, 54, and 55). In our 2012 response to 
the ICTA Petition mentioned earlier, we described the then available 
information about the absorption of titanium dioxide nanomaterials and 
concluded that the ``currently available literature indicates that 
insoluble nanomaterials of titanium dioxide used in sunscreens do not 
penetrate into or through human skin to produce adverse health effects 
when applied topically'' (ICTA Petition Response at 26). Since that 
time, our search of the available literature has not revealed anything 
that would change this conclusion. Because topically applied titanium 
dioxide particles do not enter systemic circulation to any meaningful 
extent, we do not consider a MUsT to be necessary for this ingredient.
    Given the lack of transdermal absorption of titanium dioxide beyond 
a de minims amount and, as a result, the very low likelihood of any 
systemic effects, we also do not consider additional nonclinical 
studies (including systemic carcinogenicity, developmental and 
reproductive toxicity, or toxicokinetic) to be necessary to support the 
safety of this ingredient.\23\ Because titanium dioxide penetration 
beyond the non-living stratum corneum and into the viable layers of the 
skin is also minimal, as with zinc oxide, we do not consider dermal 
carcinogenicity studies to be needed for titanium dioxide either.
---------------------------------------------------------------------------

    \23\ We note that the available literature also includes data 
showing that oral administration of relatively high doses of 
titanium dioxide did not produce adverse fetal effects in rats. (See 
Ref. 56.)
---------------------------------------------------------------------------

    The inability of more than an extremely minimal amount of titanium 
dioxide to reach viable tissues that could have an immunologic reaction 
also prevents dermal irritation, sensitization reactions, and 
photosafety issues for this ingredient. Our search of the available 
literature on titanium dioxide identified nonclinical data reinforcing 
this, showing that dermal toxicity after dermal application of titanium 
dioxide in rodents is minimal (Refs. 57 to 60). Accordingly, we do not 
consider additional clinical photosafety, irritation, or sensitization 
studies to be necessary to support the safety of this ingredient. We 
note that the available studies on titanium dioxide evaluate products 
with titanium dioxide concentrations up to 10 percent. Given that the 
physical properties of titanium dioxide both preclude its penetration 
into or through the human skin regardless of concentration and make it 
unlikely that there would be dermal photosafety, irritation, or 
sensitization associated with titanium dioxide exposure (and that there 
is no data to suggest such photosafety, irritation, or sensitization 
would exist at higher concentrations), we propose that titanium 
dioxide--regardless of particle size--is GRASE for use in sunscreens at 
concentrations up to 25 percent, consistent with the level set in the 
Stayed 1999 Final Monograph.
    In evaluating whether titanium dioxide is GRASE for use in 
sunscreen products, we have considered published literature indicating 
that nanoscale titanium dioxide can exhibit photocatalytic properties 
(Ref. 61). The literature indicates that the crystalline structure of 
titanium dioxide particles plays a role in this photocatalytic 
activity, and that the anatase crystalline polymorph is associated with 
greater photocatalytic activity than the rutile polymorph (Ref. 61). 
The European Commission has established limitations on the percentage 
of anatase crystalline polymorph in titanium dioxide to minimize 
photocatalytic activity.\24\ Coating titanium dioxide particles has 
also been shown to minimize photocatalytic activity (and to limit 
particle clumping, which can have an impact on how products blend).\25\
---------------------------------------------------------------------------

    \24\ In a July 2013 opinion addressing the safe use of titanium 
dioxide in sunscreen products, the European Commission's Scientific 
Committee on Consumer Safety gave its opinion that titanium dioxide 
particles consisting, among other things, of up to 5 percent anatase 
crystal ``can be considered to not pose any risk of adverse effects 
in humans after application on healthy, intact or sunburnt skin'' 
(Ref. 62). In 2016, this physicochemical parameter was incorporated 
by the European Commission into its Regulation on Cosmetic Products 
(Regulation (EC) No. 1223/2009 11/30/2009) permitting the use of 
titanium dioxide as a UV filter or as a colorant in cosmetics. See 
Regulation (EC) No 1143/2016 July 13, 2016.
    \25\ Id.
---------------------------------------------------------------------------

    In theory, if photocatalytic activity occurred when sunscreen 
products containing nanoscale titanium dioxide were exposed to light, 
it could result in the breakdown of other sunscreen active ingredients 
in these products. We have no evidence, however, that this in fact 
occurs in sunscreen products containing titanium dioxide or that there 
are any other negative impacts resulting from such photocatalytic 
activity. Accordingly, its potential for photocatalytic activity does 
not undermine our conclusion that titanium dioxide is GRASE for use in 
sunscreen products. Nonetheless, we invite comment (including 
supporting data) on whether sunscreens containing titanium dioxide are 
negatively impacted by the potential photocatalytic effects of that 
ingredient and, if so, to what extent; and on additional regulatory 
conditions, if any, that are necessary to address this potential issue.
    We note, as well, that it is the responsibility of manufacturers to 
ensure that any inactive ingredients used in a drug product marketed 
pursuant to the OTC Drug Review, including coatings used to address 
photocatalytic activity or for other purposes, are safe and suitable 
for their intended use (see Sec.  330.1(e)). FDA encourages 
manufacturers to contact the Agency regarding any specific coatings 
that they are considering for use in a topical sunscreen.
    c. Conclusion. Given the chemical properties of titanium dioxide as 
insoluble and unreactive under physiologic conditions and the available 
studies showing that titanium dioxide does not penetrate into the skin 
or enter into systemic circulation to any meaningful extent, we 
consider the available safety data adequate to support a proposal that 
titanium dioxide is GRASE for use in sunscreens. As with zinc oxide, 
our proposal rests in significant part on the data showing that 
absorption of titanium dioxide into or through the skin is very 
unlikely and

[[Page 6219]]

that any de minimis absorption that could theoretically occur would not 
result in adverse health effects. As a result, the safety margin here 
is large, and consistent with our approach to pediatric studies 
discussed in section VII.B.5, we therefore consider pediatric studies 
to be unnecessary for this ingredient.

B. Ingredients Proposed as Category II

    FDA's review of the available safety data for PABA and trolamine 
salicylate have caused us to conclude that the risks associated with 
use of these ingredients in sunscreen products outweigh their benefits. 
Accordingly, we are proposing that these two ingredients are Category 
II.
1. Para-Aminobenzoic Acid
    PABA use has decreased significantly in recent years because of, 
among other things, its adverse effects on skin and its discoloring and 
staining effect on clothing. Our review of more than 700 sunscreen 
brands sold in the United States (Ref. 63) indicates that PABA is in 
fact no longer being marketed in the United States.
    A search of the scientific literature, submissions to the sunscreen 
monograph docket, drug approval documents from FDA and the European 
Medicines Agency, adverse event reports submitted to FAERS, and FDA 
Advisory Committee meeting reports (among other sources) has produced 
clinical safety data on PABA that supports a conclusion that a 
sunscreen containing PABA would not be GRASE. The available clinical 
information includes significant numbers of reports of allergic and 
photoallergic skin reactions to PABA, with rates of PABA-induced skin 
reactions potentially 8 percent or higher (Refs. 64 to 67). An 8 
percent incidence is a serious concern: By comparison, only 34 
hypersensitivity reactions associated with sunscreen products have been 
identified in FAERS since 1969.\26\
---------------------------------------------------------------------------

    \26\ Total sunscreen sales since 1969 are not readily available. 
However, in 2016 a total of 161,882,779 sunscreen units were sold in 
the United States (Ref. 68).
---------------------------------------------------------------------------

    Further, PABA has the ability to cause cross-sensitization to 
structurally similar aromatic amines and nitro compounds (i.e., it can 
cause individuals exposed to it to develop sensitivity reactions to 
similar compounds) (Ref. 69). The list of compounds at issue includes a 
variety of widely used products, such as sulfonamide antibiotics 
(commonly used to treat a variety of infections, from urinary tract 
infections to certain types of pneumonia), thiazide diuretics (the 
number one recommended treatment for hypertension for certain 
communities), certain local anesthetics (such as benzocaine and 
procaine), and dyes (including para-phenylenediamine (a hair dye) and 
aniline dyes (used in medical products)) (Refs. 70, 71, and 72). Cross-
sensitization to these products is a serious concern, as widespread 
PABA use could result in a significant increase in cross-reactivity 
with these agents and the incidence of allergic and photoallergic 
dermatitis, some of which are likely to be severe.
    These safety issues alone are reason enough to find PABA not GRASE 
for use in sunscreens. In addition, however, data obtained from the 
urine samples of human subjects receiving topical PABA application 
shows that PABA also penetrates the skin and enters systemic 
circulation (Ref. 73). Because full MUsT studies for PABA have not been 
done, it is unclear to what degree such transdermal absorption takes 
place. However, one article in the published literature suggests that 
there is an association between autoimmune disorder and PABA use (Ref. 
71), and we found one report each of hepatotoxicity (Ref. 74) and 
chronic interstitial nephritis (Ref. 75) after oral PABA 
administration. Although it is difficult to determine causality on the 
basis of such single reports, if a MUsT were to show absorption of 
PABA, these reports could represent an additional safety concern.
    In addition, genotoxicity findings with PABA use have been largely 
negative in the absence of UV irradiation. Adequate assessments of the 
dermal carcinogenicity potential of PABA are unavailable, as are DART 
studies. If a MUsT were to show absorption of PABA, therefore, 
necessary studies would include dermal and systemic carcinogenicity 
studies, DART studies, and toxicokinetic studies. However, given that 
the above-described safety concerns associated with PABA are 
significant enough to place PABA in Category II, conducting such 
testing is neither appropriate nor ethical. We propose that PABA is not 
GRASE for use in sunscreens.
2. Trolamine Salicylate
    We also propose that trolamine salicylate is not GRASE for use in 
sunscreens, and is, like PABA, a Category II active ingredient. As 
described in further detail below, there are significant safety 
concerns associated with the use of trolamine salicylate in sunscreen 
products. We propose that these concerns are sufficient to support a 
conclusion that a sunscreen containing trolamine salicylate would not 
be GRASE. We note that, as with PABA, our review of more than 700 
sunscreen brands sold in the United States suggests that trolamine 
salicylate is no longer being marketed in sunscreens sold in the United 
States (Ref. 63).
    a. Background. Trolamine salicylate is comprised of trolamine and 
salicylic acid. Salicylic acid is a non-steroidal anti-inflammatory 
drug (NSAID); it is the active moiety in aspirin, and has been widely 
used as an analgesic (i.e., pain relieving), anti-pyretic (i.e., fever 
reducing), and anti-inflammatory agent. In addition to these 
properties, salicylic acid inhibits platelet aggregation, which in turn 
inhibits blood coagulation. For this reason, some salicylic acid-
containing products (such as aspirin) are used by consumers to help 
reduce cardiovascular adverse events, including myocardial infarction, 
stent thrombosis, and transient ischemic attacks.
    Trolamine salicylate was included in the Stayed 1999 Final 
Monograph for sunscreens at a concentration of up to 12 percent. It was 
also proposed as a Category III active ingredient in the tentative 
final monograph for OTC external analgesic drug products (External 
Analgesic TFM) (``External Analgesic Drug Products for Over-the-Counter 
Human Use; Tentative Final Monograph,'' 48 FR 5852 at 5855 (February 8, 
1983)). The mechanisms of action for trolamine salicylate for these two 
drug categories are very different; to be effective as an external 
analgesic, trolamine salicylate must penetrate the skin and reach the 
relevant sites of action. The available evidence clearly establishes 
that trolamine salicylate is transdermally absorbed (Refs. 76 and 77). 
To be effective as a sunscreen, however, trolamine salicylate must be 
present on the surface of the skin so that it can reflect, scatter, or 
absorb UV radiation.
    The directions for use for the two product categories differ 
significantly as well. The current requirements for sunscreen labeling 
include directions that the product should be applied to all skin 
exposed to the sun, that it should be used ``regularly'' to decrease 
the risk of skin cancer and early skin aging,\27\ and that it should be 
reapplied at least every 2 hours (21 CFR 201.327). In contrast, 
currently marketed external analgesic products containing trolamine 
salicylate include directions for use stating that they should be 
applied to ``affected areas,'' that they should be reapplied no more 
than three to four

[[Page 6220]]

times a day, and that use should be discontinued after 7 days.\28\
---------------------------------------------------------------------------

    \27\ This direction applies to sunscreens with an SPF of 15 or 
greater that are also broad spectrum.
    \28\ Based on an evaluation of product labeling available at 
https://labels.fda.gov (accessed April 4, 2018). See also External 
Analgesic TFM.
---------------------------------------------------------------------------

    b. Significant safety concerns associated with use of trolamine 
salicylate as a sunscreen. FDA is concerned that use of trolamine 
salicylate as an active ingredient in sunscreens could cause serious 
detrimental health effects due to the anti-coagulation effects of 
salicylic acid. FDA located two case reports of serious coagulation-
related adverse events associated with liberal dermal application of 
trolamine salicylate. The first case involved a surgical patient who 
experienced coagulopathy (impairment of the blood's ability to 
coagulate) at surgical sites in connection with use of topical 
trolamine salicylate (Ref. 76). Although the patient discontinued 
aspirin use 2 weeks before surgery per her doctor's instructions, she 
was unaware that use of a topical cream containing trolamine salicylate 
should have been stopped as well, and continued liberal application of 
the product to her knees for arthritis pain in the period leading up to 
her surgery. Four hours after surgery, the patient returned to the 
operating room bleeding profusely from all surfaces that had been 
operated on and experiencing massive bilateral hematomas. She lost more 
than 900 mL of blood.
    In the second case, a patient taking warfarin (an anticoagulant) 
for atrial fibrillation and stroke prevention experienced a 
considerable increase in prothrombin time (i.e., the time it takes for 
blood to coagulate) after liberal application of trolamine salicylate 
to his neck and shoulders for pain relief (Ref. 78). The patient's 
prothrombin time had previously been in the therapeutic range of 1.3 to 
1.5 times the control, but increased to 2.5 times the control during 
trolamine salicylate use. When trolamine salicylate use was 
discontinued, the patient's prothrombin time returned to 1.3 times the 
control.
    FDA is also concerned that sunscreens containing trolamine 
salicylate could lead to other adverse effects associated with 
salicylic acid exposure. These include gastrointestinal distress and 
hemorrhage, ototoxic effects (i.e., impacts on hearing), 
hypersensitivity reactions, asthma exacerbations, acid-base imbalance, 
salt and water retention, liver injury, and Reye's Syndrome (in 
children). At high doses, acute salicylate toxicity (salicylism) may 
occur. Early symptoms of salicylism include tinnitus, vertigo, nausea, 
vomiting, and diarrhea; subsequent symptoms suggesting a more severe 
intoxication include altered mental status (ranging from agitation to 
lethargy), hyperpyrexia, noncardiac pulmonary edema, and coma.\29\
---------------------------------------------------------------------------

    \29\ The symptoms associated with both acute and chronic 
salicylate toxicity are well established. Descriptions are available 
from many sources, including: National Library of Medicine's 
Toxicology Data Network (ToxNet), ``Salicylic Acid,'' September 
2008, available at https://toxnet.nlm.nih.gov/cgi-bin/sis/search/a?dbs+hsdb:@term+@DOCNO+672 (accessed March 27, 2018). FDA also 
included a comprehensive summary of salicylism in 21 CFR 343.80.
---------------------------------------------------------------------------

    If trolamine salicylate were to be applied to all skin exposed to 
the sun and reapplied every 2 hours as directed in sunscreen labeling, 
the potential for transdermal absorption and systemic availability of 
substantial amounts of salicylic acid raises significant concerns about 
the potential for increased occurrence of the above-described adverse 
events. This is a particular concern given the widespread use of other 
OTC NSAID products with anti-inflammatory, analgesic, or anti-pyretic 
effects, which, combined with the use of sunscreens containing 
trolamine salicylate, may raise the anti-platelet effects experienced 
by consumers to problematic levels. Concerns relating to transdermal 
absorption may be especially acute for children, who have a higher 
surface-area-to-body-weight ratio than adults. FDA proposes that the 
above-described safety concerns are enough, by themselves, to support a 
finding that trolamine salicylate is not GRASE for use in sunscreens, 
and therefore, is a Category II active ingredient.
    c. Data gaps. In addition, there are several categories of data 
about trolamine salicylate that FDA expects would be necessary to 
support a positive GRASE determination for its use in sunscreen 
products that are currently missing from the public record. For 
example, there is insufficient clinical dermal sensitization, 
irritation, and photosafety data for trolamine salicylate. Although the 
transdermal absorption of trolamine salicylate is well established, the 
record currently lacks a MUsT that would allow us to evaluate the 
extent of exposure to this ingredient when it is used as a sunscreen. 
Such data is important because it would allow FDA to interpret systemic 
toxicity findings in animal toxicology studies in the context of the 
amount likely to be absorbed from sunscreen use. Given the FDA 
recommendation that a MUsT for sunscreen use include application to a 
majority (75 percent at a minimum) of the body surface of each test 
subject, the above described safety concerns (including the potential 
for salicylism associated with exposure to high doses of trolamine 
salicylate) would raise significant ethical concerns about the conduct 
of a MUsT in these circumstances. Were it possible to ethically conduct 
a MUsT for this ingredient, and if such a MUsT showed significant 
transdermal absorption of trolamine salicylate, this would raise 
questions about whether enough of this ingredient remains present on 
the surface of the skin for it to function effectively as a sunscreen. 
As we noted in section VII.B.4, such considerations ultimately weigh 
into the risk-benefit calculus FDA uses to determine whether an active 
ingredient would be GRASE for use in sunscreens.
    Although we have data addressing the toxicology profile of 
salicylate, adequately detailed nonclinical DART studies for trolamine 
and toxicokinetic data to interpret DART studies were also not found in 
the public record. Adequate DART information, if it were available, 
might reveal additional data needs (for example, to address any 
potential hormonal effects that may be identified). Dermal 
carcinogenicity data are available from the National Toxicology Program 
for trolamine in acetone and trolamine alone (applied neat).\30\ In the 
absence of toxicokinetic data to interpret existing carcinogenicity 
studies, we cannot determine how the exposure in the animal studies 
relates to human exposure to trolamine from the use of trolamine 
salicylate as a sunscreen active ingredient.
---------------------------------------------------------------------------

    \30\ In mice, liver tumors were identified, providing evidence 
of systemic absorption of trolamine, but the suspected mechanism of 
action is likely not relevant to humans (Refs. 79 and 80). A causal 
link between the proposed mechanism and tumor formation in mice is 
lacking.
---------------------------------------------------------------------------

    d. Conclusion. For the reasons described above, FDA proposes that 
trolamine salicylate is not GRASE for use in sunscreens. The safety 
concerns associated with the use of trolamine salicylate as an active 
ingredient in sunscreens are significant enough to support 
classification of trolamine salicylate as a Category II ingredient. In 
particular, the potential for transdermal absorption and systemic 
availability of substantial amounts of salicylic acid in connection 
with the exposure resulting from the use of trolamine salicylate in 
sunscreens raises concerns about increased occurrence of the above-
described serious adverse events (including salicylism and serious 
coagulation-related issues). The record also contains several 
significant data gaps that would need to be addressed to support a 
positive GRASE determination for trolamine salicylate.

[[Page 6221]]

Given the safety concerns described above, however, conducting the 
clinical absorption testing recommended to address these gaps for use 
as a sunscreen raises ethical concerns.

C. Ingredients Proposed as Category III

    The public record does not contain sufficient data to support a 
positive GRASE determination for cinoxate, dioxybenzone, ensulizole, 
homosalate, meradimate, octinoxate, octisalate, octocrylene, padimate 
O, sulisobenzone, oxybenzone or avobenzone at this time. Accordingly, 
these ingredients are being proposed as Category III. In the sections 
that follow, we discuss our review of the available safety evidence for 
these ingredients and identify the existing data gaps.
1. Ingredients for Which the Record Contains Significant Data Gaps: 
Cinoxate, Dioxybenzone, Ensulizole, Homosalate, Meradimate, Octinoxate, 
Octisalate, Octocrylene, Padimate O, and Sulisobenzone
    The most significant gaps in the administrative record exist for 
the following active ingredients: Cinoxate, dioxybenzone, ensulizole, 
homosalate, meradimate, octinoxate, octisalate, octocrylene, padimate 
O, and sulisobenzone. We expect that data from all the types of studies 
described in section VII will need to be submitted to support general 
recognition of safety and effectiveness for each of these ingredients.
    Only three of these active ingredients (homosalate (Ref. 81)), 
octinoxate (Refs. 81 to 84), and octisalate (Ref. 81), for example, 
appear to have been evaluated in human absorption studies, and most of 
the available absorption studies for these three ingredients had 
significant limitations. For example, the studies use a limited number 
of subjects or are based on only a single application of the sunscreen 
active ingredient to a limited area of the body. Even with this limited 
sunscreen exposure, some of these studies showed systemic availability 
of the active ingredient (octinoxate (Refs. 83 and 84)). None of these 
10 ingredients has been studied in an adequate and well-controlled MUsT 
that would determine the amount of systemic exposure to the active 
ingredients under conditions of maximal use.
    We note that a recent publication examining the relationship 
between melting point, molecular weight, and the transdermal delivery 
rates of the active ingredients in approved drug products shows that 
products containing active ingredients with melting points and 
molecular weights similar to many of these 10 sunscreen active 
ingredients are among those successfully delivered transdermally--and 
therefore available systemically (Ref. 85). This reinforces the 
potential for transdermal absorption of and systemic exposure to these 
sunscreen ingredients. The potential for such systemic exposure is a 
concern because the available data are inadequate to determine either 
the level of systemic exposure to these active ingredients or the 
potential unintended consequences of such exposure. Given the lack of 
chronic exposure toxicology data for these 10 ingredients--which makes 
an evaluation of the dermal and systemic effects of chronic use 
impossible--this is especially concerning. A number of these active 
ingredients have also shown hormonal effects in mammalian assays 
(homosalate (Refs. 86 to 92)) and padimate O (64 FR 27666 at 27671) and 
in in vitro and in vivo assays (homosalate (Refs. 86 to 92), octinoxate 
(Refs. 93 and 94),and octocrylene (Ref. 95). Although these findings 
are only preliminary, we do not have adequate DART studies to enable us 
to assess the impact of these potential hormonal effects on development 
and reproduction.
    In addition, several of these 10 ingredients (homosalate (Refs. 81 
and 84), octinoxate (Refs. 81 and 96 to 101), octisalate (Refs. 81, 84, 
and 101 to 105),octocrylene (Refs. 95 and 106), padimate O (Ref. 100), 
and sulisobenzone (Refs. 107 and 108)) have been studied in dermal 
penetration studies, which show (in general, with the exception of 
homosalate) that these ingredients permeate into the epidermis and/or 
dermis. The studies show that there are several factors (including 
vehicle composition and the presence of other active ingredients) that 
can influence, and potentially increase, the permeation and/or 
penetration of these ingredients.
    Because the record does not currently contain sufficient data to 
support their safety, we are proposing that cinoxate, dioxybenzone, 
ensulizole, homosalate, meradimate, octinoxate, octisalate, 
octocrylene, padimate O, and sulisobenzone are Category III 
ingredients. As previously noted, we expect that data from all the 
types of studies described in section VII will be needed to support 
general recognition of safety and effectiveness for these ingredients.
2. Ingredients for Which the Record Contains Fewer Data Gaps: 
Oxybenzone and Avobenzone
    While the record does not currently contain sufficient data to 
support positive GRASE findings for oxybenzone and avobenzone, we have 
significantly more data for these two ingredients than for the 
ingredients discussed in the preceding section. To help facilitate 
submission of the remaining data, we describe the data gaps for these 
two ingredients in greater detail below.
    a. Oxybenzone data. Although we located substantially more data on 
oxybenzone than on the ingredients discussed in section VIII.C.1, our 
review of the scientific literature, submissions to the sunscreen 
monograph docket, and postmarket safety data publicly available through 
FAERS revealed significant gaps in the data we expect to be necessary 
to support a positive GRASE finding for use of oxybenzone at a 
concentration of up to 6 percent in sunscreen products. The available 
literature includes studies indicating that oxybenzone is absorbed 
through the skin and can lead to significant systemic exposure, as well 
as data showing the presence of oxybenzone in human breast milk, 
amniotic fluid, urine, and blood plasma. The significant systemic 
availability of oxybenzone (and, as discussed further below, the lack 
of data evaluating the full extent of its absorption potential) is a 
concern, among other reasons, because of questions raised in the 
published literature regarding the potential for endocrine activity 
with systemic oxybenzone exposure. Accordingly, we expect that a 
positive GRASE finding for oxybenzone-containing sunscreens would 
require, among other things, both a MUsT showing the degree of 
oxybenzone absorption under maximal usage conditions and DART studies 
that fully investigate its potential endocrine-disrupting effects. We 
found neither in the existing record.
    The record also lacks systemic and dermal carcinogenicity studies 
for oxybenzone; these (and toxicokinetic data) should also be provided 
to support a positive GRASE finding for this ingredient. Finally, the 
available literature also raises questions about the safety of use of 
oxybenzone-containing sunscreens in young children because of the 
potential for higher absorption and bioaccumulation of oxybenzone in 
this population. As discussed in further detail in the sections that 
follow, we invite input and comment on appropriate studies and/or age 
restrictions to address these pediatric issues.
    b. Background of oxybenzone. Unlike zinc oxide and titanium 
dioxide, both of which are inorganic (or physical) UV filters 
consisting of metal oxides that primarily reflect or scatter UV 
radiation,

[[Page 6222]]

oxybenzone is an organic (or chemical) filter, which absorbs UV 
radiation. It belongs to a class of aromatic ketones known as 
benzophenones and has a UV absorption profile covering both UVA and UVB 
wavelengths (Ref. 109). Because of its superior UVA coverage, 
oxybenzone was increasingly used through the early 1990s and ultimately 
replaced PABA in sunscreen products (Ref. 110). Use of oxybenzone in 
sunscreens increased when ``PABA-free'' sunscreens were introduced into 
the market because of recognition that PABA and its esters induced 
contact and photocontact allergic reactions (Ref. 110). As discussed 
below, however, evidence shows that oxybenzone also has contact 
allergenic and photoallergenic potential (Ref. 111). In addition to its 
use as a sunscreen active ingredient, oxybenzone is used in, among 
other things, perfumes, lipsticks, hair sprays, and conditioners as a 
photostabilizer and/or fragrance enhancer (Refs. 112 to 114).
    c. Data showing transdermal absorption and significant systemic 
availability of oxybenzone. Data that have become available since 
publication of the Stayed 1999 Final Monograph suggest that the 
transdermal absorption of oxybenzone is high (Refs. 82, 115, and 116). 
One study involving sampling of plasma and urine following topical 
application of an oxybenzone-containing formulation showed absorption 
and significant systemic availability of oxybenzone (Ref. 82). In this 
study, 15 men and 17 women were dosed once daily, applying a 10 percent 
oxybenzone cream formulation to approximately 90 percent of the body's 
surface area for 4 days. The figures below illustrate the plasma and 
urine levels observed.
BILLING CODE 4164-01-P
[GRAPHIC] [TIFF OMITTED] TP26FE19.000

BILLING CODE 4164-01-C

[[Page 6223]]

[GRAPHIC] [TIFF OMITTED] TP26FE19.001

BILLING CODE 4164-01-C
    Although this study provides important information about the 
significant absorption potential of oxybenzone, it does not obviate the 
need for a MUsT. Among other things, once-daily application may result 
in substantially lower systemic exposure than application at least 
every 2 hours (as sunscreen labeling directs). This difference in 
application frequency is a particular concern given that the data show 
oxybenzone levels would still be increasing at the time of 
reapplication if a 2-hour application window were observed. 
Additionally, the cream formulation used in the study was not 
formulated as a sunscreen product and may have contained ingredients 
not typically used in sunscreen formulations, and/or lacked other 
ingredients typically present. Because the formulation can have an 
impact on absorption, the absorption results produced by the study may 
not reflect absorption levels that would result from actual use of 
oxybenzone-containing sunscreen products.
    Another study, which evaluated the transdermal absorption of a 
marketed sunscreen containing 4 percent oxybenzone in 16 women and 9 
men, showed prolonged systemic availability of oxybenzone following 
topical exposure (Ref. 116). In this study, which was designed to 
evaluate the effects of UV radiation on oxybenzone absorption, the 
sunscreen was applied to study subjects twice daily for 5 days. 
Although the study concluded that UV exposure did not significantly 
affect the urinary excretion of oxybenzone, it provided further 
evidence of the systemic availability of oxybenzone following topical 
application and showed that renal excretion of oxybenzone continued for 
5 days after the last application of the sunscreen. Although the use of 
a commercial sunscreen formulation, and twice- rather than once-daily 
sunscreen application are improvements over the formulation and 
application frequency used in the previous study, twice-daily 
application remains insufficient to approximate the recommended 
application frequency of sunscreen products in real-world use. 
Furthermore, because the study used a sunscreen with 4 percent rather 
than the full 6 percent concentration of oxybenzone eligible for the 
sunscreen monograph, its results may not fully reflect the absorption 
that would result from use of a 6 percent oxybenzone-containing 
product. To properly characterize the potential for absorption of 
oxybenzone in sunscreen products and to determine a margin of safety 
for use of oxybenzone at up to 6 percent in sunscreen products, we 
expect that a MUsT will be needed.
    d. Inadequate data on oxybenzone's developmental and reproductive 
toxicity. The significant systemic availability of oxybenzone following 
topical application and the lack of data fully characterizing its 
absorption levels are concerns, among other reasons, because of 
literature suggesting that oxybenzone may have endocrine activity (see, 
e.g., Refs. 88, 92, and 117). Dermal exposure to oxybenzone (in 
acetone) in rats and mice and oral feeding of oxybenzone to rats and 
mice resulted in reduced sperm density in males in 13-week general 
toxicity studies conducted by the National Toxicology Program (NTP) 
(Ref. 118). In female rats and mice, increased estrous cycle length was 
observed in 13-week oral feeding studies.\31\ Importantly, the actual 
effects of oxybenzone on female fertility were not evaluated. In a 
preliminary dose range-finding pre- and postnatal development study in 
rats, findings in male offspring indicated that cells in the testes 
undergoing programmed cell death were increased in all oxybenzone-
exposed animals and that numbers of spermatocytes in the testes were 
markedly reduced after oral feeding at oxybenzone (Ref. 119). Although 
these findings are notable, they are all derived from dermal studies

[[Page 6224]]

with oxybenzone in acetone and oral feeding studies of oxybenzone; 
these methods of exposure could potentially lead to higher levels of 
systemic exposure to oxybenzone than with sunscreen use. Accordingly, a 
MUsT and toxicokinetic data are needed to determine the relevance of 
these findings to human use of oxybenzone as a sunscreen active 
ingredient.
---------------------------------------------------------------------------

    \31\ These changes could potentially be addressed with 
historical control data (Ref. 88).
---------------------------------------------------------------------------

    In humans, the endocrine effects of oxybenzone have been studied 
with inconclusive results (see, e.g., Refs. 83, 120, and 121). In 
biomonitoring studies of pregnant and lactating women, oxybenzone has 
been detected in breast milk, amniotic fluid, and urine samples (Ref. 
83, 120, and 121). High levels of oxybenzone in the urine of mothers 
have been associated with: (1) Decreased birth weight in girls and (2) 
increased birth weight and head circumference in boys, both of which 
can be indications of endocrine effects (Ref. 83). This association is 
particularly concerning given the widespread exposure of the U.S. 
population to oxybenzone. Estimates suggest that oxybenzone (from all 
sources) is present in the urine of 97 percent of the U.S. population, 
and that oxybenzone concentrations are higher in women than in men 
(possibly because women are more likely to use sunscreen and other 
personal care products containing oxybenzone, leading to greater 
cumulative exposure) (Ref. 83 and 115).
    Because current data suggest that oxybenzone may affect the human 
endocrine system, FDA believes that a positive GRASE determination for 
oxybenzone would require that its potential toxicities have been fully 
explored, including through DART studies (fertility and early embryonic 
studies in rodents, embryofetal development studies in rodent and 
nonrodent species, and pre- and postnatal development studies in 
rodents). In addition, as noted below, toxicokinetic data are needed to 
interpret these studies. We note that, if the results of DART studies 
do not resolve the concerns raised in the literature relating to 
potential endocrine disruption, it may still be possible to resolve 
these concerns through additional testing.\32\ In addition, because of 
the potential risk posed by metabolites of oxybenzone (existing reports 
suggest that some oxybenzone metabolites are more hormonally active 
than the parent drug (Ref. 109)), we recommend that the analytical 
method used in the MUsT be validated for both the parent and the 
metabolites of interest (Ref. 115) to support a positive GRASE finding 
for this ingredient. The results from the metabolite study will inform 
whether additional nonclinical studies assessing oxybenzone's 
metabolites should be conducted to support its safety. We note that the 
NTP is currently conducting additional DART studies on oxybenzone 
(although their embryofetal studies do not appear to include an 
assessment in a nonrodent species) (Ref. 122).\33\
---------------------------------------------------------------------------

    \32\ For examples of the type of studies that could be explored 
at that juncture see Ref. 21.
    \33\ As a reminder, such data must be generally available to be 
considered as part of this rulemaking process. Once available, FDA 
intends to review such data to determine whether it resolves 
particular data concerns we have in this area.
---------------------------------------------------------------------------

    e. Inadequate carcinogenicity and toxicokinetic data for 
oxybenzone. High population exposure to oxybenzone, coupled with a lack 
of carcinogenicity testing for this ingredient, caused the National 
Cancer Institute to nominate oxybenzone for toxicology testing in 1979 
(Ref. 123). The NTP reports that 2-year oral (dosed feed) 
carcinogenicity studies in rats and mice are in a draft report stage, 
but results are not yet publicly available (Ref. 122). In addition, no 
reports of either ongoing or planned dermal carcinogenicity studies for 
oxybenzone have been published. To support a positive GRASE finding for 
oxybenzone, carcinogenicity data from well-conducted dermal and 
systemic carcinogenicity studies should be provided. Toxicokinetic data 
in rodents (oral and dermal) and rabbits (oral) are also recommended; 
these data could be obtained from either stand-alone studies or as part 
of DART and dermal carcinogenicity studies.
    Our search of the available literature also revealed information 
suggesting that oxybenzone may generate reactive oxygen species (ROS) 
\34\ in the presence of UV light, but that this issue, and the harms 
associated with it, have not been fully explored (Ref. 124). We invite 
comment and input on the extent to which ROS generation is a concern 
for sunscreens containing oxybenzone and whether additional data on 
this topic are needed.
---------------------------------------------------------------------------

    \34\ Reactive oxygen species are ``a type of unstable molecule 
that contains oxygen and that easily reacts with other molecules in 
a cell. A buildup of ROS in cells may cause damage to DNA, RNA, and 
proteins, and may cause cell death.'' https://www.cancer.gov/publications/dictionaries/cancer-terms?cdrid=687227.
---------------------------------------------------------------------------

    f. Dermal safety of oxybenzone. The available data indicate that 
oxybenzone (at concentrations up to 6 percent) has a favorable safety 
profile with respect to irritation and sensitization potential. For 
example, the North American Contact Dermatitis Group conducted an 
analysis of patients who were patch tested for allergies between 2001 
and 2010 (see, e.g., Ref. 125). From 2001 to 2008, oxybenzone was 
tested at 3 percent; from 2009 to 2010, the concentration used for the 
test was increased to 10 percent. Of the 23,908 patients patch tested, 
only 82 patients (0.34 percent) had positive test patch results with 
oxybenzone. In addition, a search of FAERS for case reports of 
hypersensitivity reactions to oxybenzone-containing sunscreen products 
resulted in only 31 cases (4 with anaphylaxis) between 1988 and 2011. 
Because sufficient data exist to make a determination, we do not 
consider additional dermal irritation or sensitization studies to be 
necessary to support a positive GRASE finding for oxybenzone up to 6 
percent. As is customary in clinical trials, however, we recommend that 
dermal safety data for oxybenzone be collected during MUsT studies.
    Nevertheless, the overwhelming majority of results from available 
studies (see, e.g., Refs. 125 to 136) addressing allergic contact 
dermatitis for oxybenzone show that oxybenzone is an allergen for 
persons with preexisting skin conditions. Because the evidence 
establishing oxybenzone as a photoallergen in individuals with 
photosensitivity is clear, no further dermal photosafety studies to 
characterize this risk are needed. However, if we were to receive 
adequate data to support a positive GRASE finding for oxybenzone, we 
would consider requiring labeling language to address the risk of 
allergic reactions associated with oxybenzone use. We invite comment on 
whether such labeling should be required for sunscreens containing 
oxybenzone and, if so, what that labeling should entail.
    g. Safety questions regarding use of oxybenzone in pediatric 
populations. Sunscreens are currently labeled for use in children as 
young as 6 months old. The available literature, however, includes 
several publications that raise concerns about the use of sunscreens 
containing oxybenzone in young children. Among these publications is a 
2006 report from the Swedish Research Council noting that children 
under the age of 2 years old have not fully developed the enzymes 
believed to metabolize oxybenzone (Ref. 137), which suggests, in 
theory, that small children may not be able to eliminate oxybenzone as 
easily as adults. The possibility for bioaccumulation in children, 
taken together with the potential increased absorption of oxybenzone in 
young children (due to their greater body surface-area-to-weight ratio) 
and the potential harms associated with absorption discussed above,

[[Page 6225]]

militates in favor of caution when using oxybenzone products in young 
children. Accordingly, we are seeking any existing pediatric data on 
the safety of oxybenzone use in children under 2 years old. We are also 
requesting input on: (1) Whether additional data on the safety of 
oxybenzone use in young children is necessary to support the use of 
oxybenzone-containing sunscreens in children under 2 years of age 
(taking into consideration the practical hurdles involved in conducting 
studies in children of this age) or (2) whether sunscreen products 
containing oxybenzone should instead be contraindicated for use in 
children younger than 2 years (given, among other things, the 
availability for use as sunscreen active ingredients of physical UV 
filters like titanium dioxide and zinc oxide, which do not raise the 
same questions about safe use in young children).
    h. Conclusion. Given the available data showing significant 
transdermal absorption and systemic availability of oxybenzone, as well 
as the potential for endocrine activity, we propose that oxybenzone is 
not GRASE for use in sunscreens without further data. As described 
above, a MUsT should be conducted to fully characterize the absorption 
of oxybenzone and to calculate a margin of safety for human use. As 
part of the MUsT, we believe that a study of oxybenzone's metabolites 
in humans is also necessary; the results of this study will inform 
whether additional nonclinical studies with metabolites are needed to 
address potential endocrine effects. Given that oxybenzone demonstrates 
significant systemic absorption, FDA believes that data on 
carcinogenicity (both systemic and dermal) and developmental/
reproductive toxicity are likely to be needed to support the safety of 
this ingredient, as are toxicokinetic data to bridge between animal and 
human data. We seek any existing data on the pediatric safety of 
oxybenzone. We also seek comment on whether additional safety data are 
needed to support the use of sunscreens containing oxybenzone on 
children under 2 years of age, as well as comment on whether these 
sunscreens should be contraindicated for use in this population. We 
note that, because of the risk of allergic reactions associated with 
oxybenzone use, if we receive adequate data to support a positive GRASE 
finding for oxybenzone, we may require labeling to address this risk. 
We seek comment on whether such labeling should be required for 
sunscreens containing oxybenzone and, if so, what such labeling 
language should entail.
    In summary, table 3 shows the additional studies that FDA 
anticipates would be necessary to support a positive GRASE finding for 
sunscreens containing oxybenzone.

   Table 3--Summary of Recommendations: Studies for Oxybenzone Up to 6
                                 Percent
------------------------------------------------------------------------
    Safety studies FDA proposes are
      necessary to support a GRASE          Additional studies or data
             determination                          necessary?
------------------------------------------------------------------------
Pharmacological Studies:                 ...............................
    Human absorption (MUsT) (including   Yes.
     metabolite study in humans).
Nonclinical Safety Studies:              ...............................
    Toxicokinetics.....................  Yes.
    Dermal Carcinogenicity.............  Yes.
    Systemic Carcinogenicity...........  Yes.
DART: \1\..............................  Yes.
    Fertility and early embryonic
     development.
    Embryofetal development in two
     species (rodent and non-rodent).
    Prenatal and postnatal development.
Clinical Safety Testing:                 ...............................
    Skin irritation and sensitization..  No.
    Skin photoallergenicity and          No.
     phototoxicity.
    Pediatric studies..................  Seeking input on whether
                                          additional studies or
                                          contraindication are necessary
                                          to support the safety of
                                          sunscreens containing
                                          oxybenzone for children under
                                          2 years of age.
------------------------------------------------------------------------
\1\ As noted above, if DART studies do not resolve the concerns raised
  in the literature relating to potential endocrine disruption, it may
  be possible to resolve these concerns through additional testing.

    i. Avobenzone data. Our review of the available scientific 
literature, submissions to the sunscreen monograph docket, and publicly 
available FAERS data also revealed significant gaps in the data we 
expect to be necessary to support a finding that avobenzone (at up to 
either 3 percent or 5 percent, as discussed below) is GRASE for use in 
sunscreens. Most critically, we encountered no studies examining the 
absorption of avobenzone in vivo, and those in vitro studies we located 
had several weaknesses that limit their usefulness in assessing the 
potential absorption of avobenzone from formulated sunscreen products. 
This is a concern given that, as explained in further detail below, 
certain of avobenzone's chemical properties suggest that sunscreen 
products containing avobenzone have a potential for absorption. There 
are also other gaps in the record, including (as discussed below) 
dermal carcinogenicity data, toxicokinetic data, and--potentially, 
depending on the outcome of MUsT studies assessing the absorption of 
avobenzone--systemic carcinogenicity and additional DART studies. 
Accordingly, we propose to find that avobenzone is Category III.
    j. Background of avobenzone. Avobenzone, like oxybenzone, is an 
organic (chemical) UV filter. Because avobenzone primarily absorbs 
radiation in the UVA portion of the UV spectrum, it is typically 
combined with another sunscreen active ingredient that provides 
protection in the UVB range. Avobenzone exhibits greater 
photoinstability than other UV absorbers; the available evidence shows 
that avobenzone degrades quickly upon exposure to sunlight, which can 
cause its efficacy to be decreased by between 50 and 90 percent after 
60 minutes of exposure to sunlight (Refs. 138 and 139).\35\ To address 
this, avobenzone is typically combined with a photostabilizer to 
prevent rapid photodegradation (Refs. 138 and 139).
---------------------------------------------------------------------------

    \35\ Avobenzone's photodegradation also results in the formation 
of free radicals, which could, in theory, create sensitization and 
irritation responses and increase long-term risk of skin cancers and 
photoaging (Ref. 139).

---------------------------------------------------------------------------

[[Page 6226]]

    k. Potential for absorption of avobenzone. Although avobenzone is 
not soluble to any great extent in water, it is soluble in organic 
solvents. These include oils (which are present on human skin), 
alcohols, and other substances regularly included in sunscreen product 
formulations. Although this solubility is not enough, by itself, to 
determine whether transdermal absorption will take place, it is a 
necessary precondition (Ref. 140). In addition, like the 10 active 
ingredients described in section VIII.C.1, avobenzone's melting point 
and molecular weight are similar to those of active ingredients in 
approved drug products that are successfully delivered transdermally 
and therefore available systemically (Ref. 85). As with the 10 
sunscreen active ingredients previously discussed, this suggests a 
potential for transdermal absorption of avobenzone.
    l. Lack of adequate data on transdermal absorption of avobenzone. 
Nevertheless, our review of the available literature on avobenzone 
failed to produce any studies evaluating the in vivo absorption of 
avobenzone at 3 percent or higher under (or even approaching) maximal 
usage conditions. While we were able to locate a few studies evaluating 
avobenzone's absorption in vitro, these studies had a number of 
weaknesses that significantly limited the conclusions that could be 
drawn from them.
    The first in vitro study we located evaluated the penetration--
through excised human skin--of five sunscreen ingredients (including 
avobenzone) that had been diluted in mineral oil and water (Ref. 100). 
The study used a static cell technique. As discussed in section VIII.D, 
in a static cell study, the test product (here, a sunscreen/mineral 
oil/water formulation) is placed on the upper side of a membrane (here, 
the excised skin) in the open donor chamber of a static cell, and a 
sampling fluid is placed on the other side of the membrane in a 
receptor cell. Diffusion of the ingredient (here the avobenzone) from 
the topically applied product to and across the membrane is monitored 
by examining sequentially collected samples of the receptor fluid. To 
ensure that all transdermal penetration of the ingredient that takes 
place is fully reflected in the receptor fluid, the receptor fluid must 
be optimized for absorption (in other words, sink conditions must be 
created in the fluid).
    In this study, the use of skin as the membrane in the system 
allowed for an evaluation of the presence and depth of permeation via 
skin stripping--the sequential application and removal of adhesive tape 
to the skin samples. However, it is unclear whether the receptor phase 
of the study created adequate sink conditions. In addition, the 
formulations used in the study (which, as noted previously, consisted 
of only water, mineral oil, and the sunscreen ingredient) did not 
contain any of the other types of excipients (such as emollients, 
stabilizers, or solubilizers) that can also function as permeation/
absorption enhancers and that are typically present in sunscreen 
product formulations. The study results showed that there was 
avobenzone present in the stratum corneum, the epidermis, and the 
viable dermis of the skin used as the membrane, but not in the receptor 
fluid. Although the lack of avobenzone in the receptor fluid is 
encouraging, the other characteristics of the study limit its value in 
assessing the actual absorption potential of avobenzone used in 
sunscreen products.
    The second in vitro study (Ref. 141) we located suffered from 
similar limitations. This study assessed the avobenzone permeation 
observed using a static cell (as generally described above), and then 
took the skin from the static cell and subjected it to multiple rounds 
of tape stripping to assess the presence of avobenzone at various 
levels of the skin. Following tape stripping, the skin was subjected to 
digestion (i.e., the skin sample was subjected to a chemical treatment 
that breaks down the cell membranes to release any sunscreen that might 
be either bound to proteins or bound up in the cells).
    The study results showed significant retention of avobenzone in the 
stratum corneum, a lesser amount in the epidermis, and none in the 
dermis or receptor fluid. Like the previous study, however, the test 
material used in this study did not include any of the permeation 
enhancers typically included in commercial sunscreen formulations. It 
is also unclear whether sink conditions existed in the receptor phase 
of the study.
    The final in vitro study used a static cell to evaluate the 
transdermal penetration of six sunscreen formulations collected from a 
health spa that marketed its own line of skin care products (Ref. 96). 
This study improved on the design of the previous two studies in 
several respects. First, the receptor fluid contained ethanol, a 
permeation enhancer often used in sunscreen products, which produced 
sink conditions in the receptor phase. Secondly, to create favorable 
conditions for absorption, the products were applied at a thickness of 
20 mg/square centimeters (cm\2\) on the skin's surface (i.e., 10 times 
the skin loading typically expected (Refs. 142 and 143)). In addition, 
the study's use of commercially marketed sunscreen formulations (which, 
as discussed above, typically contain multiple permeation/absorption-
enhancing excipients) more accurately reflects the absorption potential 
of marketed sunscreen products.
    Despite these improvements, the usefulness of the study was limited 
by its use of an analytical method that prevented the detection of any 
avobenzone absorption below 100 ng/mL. This level of absorption is 
hundreds of times higher than what is relevant for our considerations 
in assessing the acceptable absorption level from a topically applied 
product. The concentration of avobenzone used in the study (ranging 
from 0.2 percent to 1 percent) is also significantly lower than what is 
relevant for our current consideration of maximum concentration of this 
ingredient. Although avobenzone was only absorbed to a very small 
extent (between 3 percent and 3.96 percent) under these study 
conditions, these weaknesses in the study's design significantly limit 
the conclusions that can be reached from its results.
    Given that avobenzone's chemical properties suggest that it has a 
potential for transdermal absorption in sunscreen products, the lack of 
adequate data assessing its absorption in realistic sunscreen 
formulations is a concern. We therefore expect that a MUsT 
demonstrating the degree of absorption of avobenzone into the human 
body under maximal use conditions will be needed to support a positive 
GRASE determination for sunscreens containing avobenzone. Further, in 
light of the above-described data showing avobenzone's 
photoinstability, we also expect that, if sufficient data are provided 
to support the safety of avobenzone, any future sunscreen monograph 
including avobenzone as an active ingredient will include the 
limitation that avobenzone is not GRASE for use in sunscreen products 
unless it has been photostabilized (via use of a photostabilizing UV 
filter or other photostabilizing ingredient/mechanism) to prevent its 
photodegradation and (among other concerns) the attendant reduction in 
avobenzone efficacy.
    Because photodegradation can reduce the amount of avobenzone 
absorbed transdermally, we also expect that a MUsT sufficient to 
support the general recognition of safety of avobenzone for sunscreen 
use would need to test formulations of avobenzone that include a 
photostabilizer. Including

[[Page 6227]]

photostabilizers in MUsT formulations will allow for accurate 
assessment of absorption levels in final formulated sunscreen products 
containing avobenzone. This proposal is consistent with our general 
recommendation that materials evaluated under the MUsT paradigm 
represent real-world sunscreen formulations, rather than overly 
simplified solutions that fail to replicate the absorption potential of 
marketed formulations. As noted in section VII.B.4, we encourage 
sunscreen manufacturers to discuss their MUsT protocol with FDA before 
beginning the trial.
    m. Data supporting dermal safety of avobenzone. The available 
clinical dermal studies indicate that avobenzone at concentrations up 
to 5 percent have a favorable safety profile with respect to potential 
irritation, sensitization, and photosafety. In 2009, in conjunction 
with a citizen petition \36\ (L'Oreal Petition, Docket No. FDA-1978-N-
0018-0675) asking FDA to take action to permit the marketing of 
sunscreen products containing avobenzone up to 5 percent, L'Oreal USA 
Products, Inc. (L'Oreal) submitted nine human repeat insult patch, 
phototoxicity, and photoallergy studies with six different sunscreen 
formulations containing avobenzone (3.4 percent, 4 percent, or 5 
percent). The studies showed that the formulations were well tolerated 
for topical use (i.e., essentially non-allergenic, non-irritating, and 
non-sensitizing, with mild to moderate reactions occurring only rarely) 
(L'Oreal Petition).\37\ A separate search of the available scientific 
literature on the clinical safety of avobenzone did not reveal anything 
to undermine these findings. Although the available literature included 
a small number of reports of contact irritation and photosensitization 
in connection with avobenzone-containing products, details about the 
composition of the formulations at issue (and the concentrations of 
avobenzone) were frequently missing from the literature, making it 
difficult to determine the cause of these responses. A small number of 
serious hypersensitivity reports for sunscreens containing avobenzone 
were also located in FAERS. Because the sunscreens at issue usually 
contained three or more active ingredients, however, it is difficult to 
determine what caused the reaction. Because sufficient data exist to 
make a determination, we do not consider additional dermal clinical 
studies (including photosafety, irritation, or sensitization studies) 
to be necessary to support the safety of this ingredient for sunscreen 
use at up to 5 percent. As is customary in clinical trials, however, we 
recommend that dermal safety data for avobenzone be collected during 
MUsT studies.
---------------------------------------------------------------------------

    \36\ FDA-1978-N-0018-0675, two volume submission (February 20, 
2009) (L'Oreal Petition).
    \37\ Id., volume I, pp. 5-8.
---------------------------------------------------------------------------

    n. Other nonclinical safety studies for avobenzone. Dermal 
carcinogenicity studies have not been conducted for avobenzone. The 
available data on the permeation of avobenzone suggest that it may 
permeate into at least the dermis and epidermis, which means that it is 
possible for avobenzone to impact skin tumor development. We therefore 
expect that dermal carcinogenicity studies will be necessary to support 
a positive GRASE finding for sunscreens containing this ingredient. 
Available embryofetal development studies in rats and rabbits did not 
reveal any findings of concern. However, our review of the nonclinical 
data for avobenzone \38\ also revealed that toxicokinetic data 
following repeat-dose exposure will be needed to interpret pivotal 
nonclinical safety studies (including the embryofetal development 
studies in rats and rabbits) once the MUsT data become available. (As 
explained in section VII.B.4, these data are used to compare drug 
levels achieved in animal studies with those observed in humans under 
maximal exposure conditions.) In addition, if results of a MUsT 
demonstrate that there is significant systemic absorption of 
avobenzone, additional fertility and early embryonic development and 
prenatal and postnatal development studies in rats will be needed to 
support a positive GRASE finding. Depending on the results of the MUsT, 
systemic carcinogenicity studies may also be needed.
---------------------------------------------------------------------------

    \38\ The available nonclinical data for avobenzone include acute 
oral and dermal toxicity studies in rats; a 13-week oral toxicity 
study in rats; a 28-day dermal toxicity study in rats; a 21-day 
dermal toxicity study in rabbits; several in vitro genotoxicity 
tests; an in vivo micronucleus test in mice, as well as a 
sensitization test in guinea pigs; a primary skin irritation test in 
rabbits; an ocular irritation test in rabbits; a phototoxicity study 
in guinea pigs; a photoallergenicity study in guinea pigs; and 
embryofetal development studies in rats and rabbits (Givaudan-Roure 
Petition, Docket No. FDA-1978-N-0018-0751). Importantly, (except for 
the embryofetal development studies) these studies are not 
sufficient to resolve safety concerns for a chronically used 
product.
---------------------------------------------------------------------------

    o. Avobenzone in combination with other sunscreen active 
ingredients. As noted in section III.B, our finding in the Stayed 1999 
Final Monograph that avobenzone was GRASE for use in sunscreens would 
have allowed its combination only with certain other sunscreen active 
ingredients (64 FR 27666 at 27688) because we did not have targeted 
evidence to support the safety and effectiveness of avobenzone when 
combined with the remaining active ingredients. We believe this 
limitation was inconsistent with the approach to evaluating sunscreen 
combinations that the Agency has generally taken throughout the OTC 
Drug Review for sunscreens. For this reason, unless evidence is 
submitted to suggest that there is a safety or efficacy concern 
associated with the combination of avobenzone with another active 
ingredient, we expect to conclude that a positive GRASE determination 
for avobenzone will support its use in sunscreens either alone or in 
combination with all other sunscreen active ingredients.
    p. L'Oreal request to increase concentration of avobenzone to 5 
percent. Avobenzone is currently listed in the Stayed 1999 Final 
Monograph at concentrations up to 3 percent. As described earlier, in 
2009 FDA received a citizen petition from L'Oreal requesting, among 
other things, that we amend the sunscreen monograph to increase the 
allowable level of avobenzone to 5 percent (L'Oreal Petition at 1). In 
the Stayed 1999 Final Monograph, the Agency determined that avobenzone 
at concentrations up to 3 percent is an effective sunscreen active 
ingredient. We now likewise conclude that the record contains 
sufficient information to satisfy the effectiveness prong of the GRASE 
standard for sunscreens containing avobenzone at concentrations up to 5 
percent.
    As described above, data submitted with that L'Oreal Petition were 
sufficient to establish that avobenzone at a concentration of up to 5 
percent has a favorable safety profile with respect to potential 
irritation, sensitization, and photosafety. To support a finding that 
avobenzone at concentrations up to 5 percent is GRASE for use in 
sunscreens, however, FDA expects that a MUsT evaluating the transdermal 
absorption of avobenzone up to 5 percent, as well as dermal 
carcinogenicity studies and toxicokinetic data for avobenzone at a 
concentration of at least 5 percent, will also be needed. Depending on 
the outcome of the MUsT, we may also need systemic carcinogenicity data 
and additional DART studies, including fertility and early embryonic 
development, and pre- and postnatal development studies in rats for 
avobenzone at 5 percent. The record does not currently include any of 
these data. However, if FDA were to receive sufficient data to support 
a positive GRASE finding for avobenzone up to 5 percent, we would 
expect to include

[[Page 6228]]

avobenzone at this percentage in a final sunscreen monograph.
    q. Conclusion. Given that: (1) Avobenzone's organic solubility, 
molecular weight, and melting point suggest it has a potential for 
transdermal absorption; (2) there is a lack of available data on the 
transdermal absorption of avobenzone in vivo (including under maximal 
use conditions); and (3) there are limitations in the available in 
vitro studies assessing avobenzone absorption, we expect that a 
properly designed MUsT will be necessary to support a positive GRASE 
finding for avobenzone use in sunscreens. We expect that, to be GRASE 
for sunscreen use, avobenzone will need to be photostabilized to 
address its potential for degradation, and we therefore expect that any 
future sunscreen monograph including avobenzone as an active ingredient 
will include the limitation that avobenzone is not GRASE for use in 
sunscreen products unless it has been photostabilized to prevent its 
photodegradation. In addition, we believe that an adequate MUsT 
evaluating the absorption potential of avobenzone will need to include 
a photostabilizer to ensure that the potential transdermal absorption 
of avobenzone from avobenzone-containing sunscreens is accurately 
assessed.
    We also expect that dermal carcinogenicity and toxicokinetic data 
will be necessary to support a positive GRASE finding for sunscreens 
containing avobenzone. Depending on the outcome of a MUsT assessing the 
absorption of avobenzone, systemic carcinogenicity testing and 
additional DART studies, including fertility and early embryonic 
development and pre- and postnatal development studies in rats may be 
needed as well. We will also determine the extent to which additional 
DART studies may be needed based on the results of the MUsT. Depending 
on the results of the nonclinical and pharmacology studies for this 
ingredient and the safety margin that is calculated from these results, 
pediatric studies for avobenzone may also be needed to support the use 
of sunscreens containing avobenzone in pediatric populations.

 Table 4--Summary of Recommendations: Studies for Avobenzone Up to 3 (or
                               5) Percent
------------------------------------------------------------------------
    Safety studies FDA proposes are
      necessary to support a GRASE          Additional studies or data
             determination                          necessary?
------------------------------------------------------------------------
Pharmacological Studies:
    Human absorption (MUsT) (including   Yes.
     metabolite study in humans).
Nonclinical Safety Studies:
    Toxicokinetics.....................  Yes.
    Dermal Carcinogenicity.............  Yes.
    Systemic Carcinogenicity...........  Dependent on results of the
                                          MUsT.
DART:
    Fertility and early embryonic        Dependent on results of the
     development.                         MUsT.
    Embryofetal development in two       No.
     species (rodent and non-rodent).
    Prenatal and postnatal development.  Dependent on results of the
                                          MUsT.
Clinical Safety Testing:
    Skin irritation and sensitization..  No.
    Skin photoallergenicity and          No.
     phototoxicity.
    Pediatric studies..................  Pediatric studies may be
                                          required depending on the
                                          outcome of the MUsT.
------------------------------------------------------------------------

D. Anticipated Final Formulation In Vitro Permeation Testing

    As noted earlier, a final sunscreen monograph will need to set out 
the conditions under which any product marketed pursuant to it would be 
GRASE and not misbranded. Variations among individual sunscreen product 
formulations--in particular, characteristics of the specific vehicle 
(e.g., the cream, lotion, or oil) in which active ingredients are 
delivered--can affect the transdermal absorption of sunscreens, and 
thus, have an impact on their safety and effectiveness. To address 
this, FDA currently requires final formulation testing of OTC sunscreen 
products to support labeled claims regarding their effectiveness--
namely, testing for SPF value as well as broad spectrum protection and 
water resistance where those attributes are claimed in product 
labels.\39\ For purposes of this proposed rule, we use the term final 
formulation testing to refer to testing conducted on the sunscreen 
product formulation to be marketed. Our expectation is that final 
formulation testing would also generally be necessary to ensure that 
the active ingredient in any given sunscreen formulation permitted 
under the monograph would not be systemically absorbed beyond the 
amount FDA determined to be safe.
---------------------------------------------------------------------------

    \39\ See Sec.  201.327 for the current labeling requirements, 
and underlying testing, for OTC sunscreens containing one or more of 
the 16 active ingredients that are addressed in this rulemaking, for 
use in products marketed without approved NDAs. OTC sunscreens 
marketed under NDAs provide similar information in their product-
specific applications to substantiate their labeling. For proposed 
changes to Sec.  201.327, see codified section of this document. The 
Stayed 1999 Final Monograph also required SPF testing of final 
formulations as a GRASE condition. Elsewhere in this proposed rule, 
we propose to establish monograph conditions in 21 CFR part 352 that 
ensure that all sunscreens are tested for SPF in accordance with 
Sec.  201.327(i) and achieve a minimum SPF of 2, and that certain 
sunscreens pass the broad spectrum test in Sec.  201.327(j).
---------------------------------------------------------------------------

    The discussion that follows provides FDA's thinking about such 
testing of final formulations, which we anticipate requiring in the 
future for sunscreen products marketed under the sunscreen monograph 
(unless FDA determines that the ingredient or ingredients contained in 
the product are unlikely to be absorbed through the skin). Because this 
testing would not be required for sunscreens containing only those 
active ingredients proposed here as Category I (zinc oxide and titanium 
dioxide), FDA has not yet reached a final determination as to the 
particular parameters that might be required for such final formulation 
testing. We anticipate that we may specify final formulation testing 
requirements in the monograph in the future, however, as active 
ingredients that we are now proposing as Category III may be included 
in the monograph in the future if FDA receives data supporting their 
GRASE status. Final formulation testing requirements applicable to such 
ingredients would be established on an ingredient-specific basis, 
taking into consideration the data provided to

[[Page 6229]]

support a positive GRASE determination for the specific ingredient (for 
example, whether any safety signals are detected in well-conducted 
nonclinical carcinogenicity and DART studies). We encourage interested 
parties to provide information and comment for each sunscreen active 
ingredient that is relevant to establishing this kind of final 
formulation testing for each active ingredient.
    FDA's expectation is that this testing would not generally call for 
an in vivo study. Instead, FDA expects that the conditions of marketing 
specified for sunscreens containing a given active ingredient would 
require manufacturers to perform in vitro permeation testing before 
marketing each sunscreen formulation containing that ingredient. 
Consistent with the approach for SPF and broad spectrum final 
formulation testing set forth in Sec.  201.327 (for proposed changes to 
Sec.  201.327, see codified section of this document), FDA anticipates 
that it would not review the results of the in vitro permeation testing 
before product marketing. Rather, FDA expects that any future 
conditions pertaining to final formulation in vitro permeation testing 
in the sunscreen monograph would include a requirement that 
manufacturers maintain records of this testing, and that those records 
be available for FDA inspection upon request.
    FDA anticipates establishing a standard control formulation for 
each sunscreen active ingredient to be used in the in vitro permeation 
testing of products containing that ingredient. The standard control 
formulation would be the formulation that produces the highest in vivo 
absorption in the MUsT. The results of in vitro permeation testing 
using this control formulation would then be used as a bridge to a 
corresponding level of in vivo absorption from the MUsT that is used to 
establish the safety margin for the ingredient. Then, FDA anticipates 
establishing conditions to ensure that final formulation in vitro 
permeation testing would be conducted for each formulation intended to 
be marketed, using the specified vertical diffusion cell described 
below. The results of the in vitro permeation testing of each final 
formulation would be compared to the absorption found in the standard 
control formulation for the active ingredient it contains.
    In vitro permeation testing is a methodology that has been used in 
dermal formulation development for over 30 years and, as used here, 
specifically refers to use of the ``Vertical Diffusion Cell'' (Ref. 
144). A vertical diffusion cell is comprised of three major units: (1) 
An upper chamber (into which the sunscreen formulation is placed); (2) 
the rate-limiting membrane (the prepared human skin); (3) and the lower 
chamber/fluid channel (containing a receptor fluid that is evaluated to 
determine how much of the sunscreen it ``receives'') (Refs. 145 to 
147). The vertical diffusion cell system has been commercialized and is 
available as both single and multiple unit models that can be 
automated.
    Other relevant parameters FDA expects to consider in establishing 
future requirements for in vitro permeation testing include (among 
other things) the thickness and integrity of collected skin, storage 
conditions used for collected skin, receptor fluid composition, skin 
and receptor fluid temperature, the number of skin samples (and donors) 
used, study duration, sampling period, application method, and number 
of experimenters.
    We note that if a final sunscreen formulation contains a 
combination of sunscreen active ingredients, FDA anticipates requiring 
that this final formulation be tested against the standard control 
formulations for each of the sunscreen active ingredients it contains. 
As noted above, a standard control formulation might not be specified 
for (and final formulation in vitro permeation testing might not be 
necessary to establish safety for) a sunscreen containing a particular 
active ingredient if FDA determines that the ingredient is unlikely to 
be absorbed through the skin. As mentioned above, we therefore do not 
propose to require final formulation in vitro permeation testing for 
sunscreen formulations containing only zinc oxide and/or titanium 
dioxide.
    In cases in which such testing is required, FDA anticipates that if 
the in vitro permeation of each sunscreen active ingredient in the 
final formulated product is equal to or less than the value obtained 
from in vitro permeation testing of the standard control formulation 
for that active ingredient, the product's safety margin would be 
considered to fall within the parameters judged to be GRASE, and thus 
to support marketing of the formulation. However, if the in vitro 
permeation of the active ingredient from the specific final formulation 
is greater than the value obtained from in vitro permeation testing of 
the standard control formulation for that active ingredient, FDA 
anticipates that the drug product(s) using that formulation would not 
be considered GRASE. In that situation, the sponsor would have the 
option to either: (1) Reformulate the product and conduct in vitro 
permeation testing to establish that the reformulated product satisfies 
the final formulation in vitro permeation testing requirements set out 
in the sunscreen monograph or (2) seek NDA approval for the new 
formulation.

IX. Additional Proposed Conditions of Use

A. Proposed Requirements Related to Dosage Form

    OTC sunscreens have been marketed in a variety of dosage forms over 
the years. Responding in part to the growing market acceptance of spray 
sunscreens, on June 17, 2011, FDA issued an ANPR addressing sunscreen 
dosage forms (Dosage Forms ANPR) (76 FR 35669, June 17, 2011). The ANPR 
identified dosage forms considered eligible or ineligible for review 
and potential inclusion in the OTC sunscreen monograph, based on FDA's 
knowledge, at that time, of their history of marketing before the OTC 
Drug Review began in 1972. It also solicited specific information about 
the safety, effectiveness, and directions for use of spray sunscreens.
1. Summary of Eligible and Ineligible Dosage Forms
    In this proposed rule, FDA is confirming that the following dosage 
forms identified in the Dosage Forms ANPR are eligible for review and 
potential inclusion in the OTC sunscreen monograph based on their 
history of sunscreen marketing before 1972: Oil, lotion, cream, gel, 
butter, paste, ointment, stick, spray, and powder. With the exception 
of powder, FDA proposes that sunscreens in these dosage forms are GRASE 
subject to certain conditions described below and elsewhere in this 
proposed rule. We note that sunscreen powders were classified as 
ineligible for review in the Dosage Forms ANPR because, at that time, 
we were unable to identify any sunscreen products in powder form that 
were marketed before the OTC Drug Review began. Based on marketing data 
submitted to the ANPR docket and in a related citizen petition (Docket 
No. 1978-N-0018-0741), we have determined that the powder dosage form 
is eligible to be considered for inclusion in the OTC sunscreen 
monograph. However, as described in section IX.A.4, we tentatively 
conclude that additional safety and efficacy data will be necessary to 
classify sunscreens in the powder dosage form as GRASE and include them 
in the final monograph. We are proposing that sunscreens in all dosage 
forms other than those identified as eligible for consideration above--

[[Page 6230]]

including wipes, towelettes, body washes, and shampoos--are new drugs 
because we did not receive data showing that they were marketed prior 
to 1972.
2. Overview of Comments on the Dosage Forms ANPR
    FDA received a total of 14 comments on the Dosage Forms ANPR. Six 
of the comments provided no new data, but generally supported the 
advantages of spray sunscreens, agreed with the need to address 
concerns about spray sunscreens' performance and/or safety (especially 
when used on children), opined that existing SPF methods would not need 
to be modified for sprays, or (in most cases) agreed with FDA's 
suggested directions for use. Other comments argued for the inclusion 
of additional dosage forms identified as ineligible in the Dosage Forms 
ANPR, but failed to provide supporting marketing data. One comment 
contained marketing information showing that sunscreen products in 
powder form, which we had previously identified as ineligible for the 
monograph, had been marketed in the United States before 1972. The 
remaining comments (all from industry) provided data and information 
that directly or indirectly addressed questions raised in the Dosage 
Forms ANPR concerning the safety, effectiveness, and labeling of spray 
sunscreens. These comments are discussed in sections IX.A.3 and IX.A.4 
below.
3. Safety and Effectiveness of Spray Sunscreens
    As we recognized in the Dosage Forms ANPR, compared to traditional 
lotions, oils, and the like, spray sunscreens raise potential concerns 
of both safety and efficacy that FDA must consider in determining 
whether sunscreens in the spray dosage form would be GRASE. With 
respect to efficacy, FDA must consider factors such as whether spraying 
sunscreen rather than applying it by hand provides effective coverage 
on exposed skin, how consumers use spray products, and whether current 
test methods for SPF and broad spectrum protection can be relied on for 
adequate labeling of spray products. With respect to safety, spray 
sunscreens raise the question of potential harm from inhalation of 
sunscreen components as well as potential flammability risks.
    a. Characteristics of sunscreen spray products. Spray sunscreens 
use varying technologies to package and deliver a sunscreen formulation 
as an aerosol spray, i.e., an airborne suspension of fine droplets or 
particles. In some spray products, the sunscreen formulation is mixed 
in a canister with a liquefied gas propellant that supplies the force 
to generate an aerosol containing both dissolved sunscreen formulation 
and propellant upon activation of a valve system. There are also pump 
spray sunscreen products that are not packaged under pressure but 
generate spray by applied mechanical force without the need for a 
propellant. Many currently marketed spray sunscreen products use a 
delivery technology referred to as a bag-on-valve system, in which the 
sunscreen formulation is contained in a bag with an attached valve 
inside a canister filled with propellant, so as not to mix the 
sunscreen formulation and propellant ingredients. For purposes of this 
document, a spray sunscreen product is one discharged from either a 
pressurized or nonpressurized container, with the understanding that 
the degree of atomization will likely vary according to the 
formulation, the container system used, and the design of the spray 
actuator, among other factors.
    b. Spray sunscreen performance and effectiveness. The Dosage Form 
ANPR asked a series of questions relating to the performance and 
effectiveness of spray sunscreens, including questions about the amount 
of spray sunscreen typically applied by consumers, uniformity of 
coverage, how frequently consumers reapply spray sunscreens, whether 
consumers rub spray sunscreens into the skin when directed to do so and 
the resulting effect on effectiveness, and whether--and if so, how--the 
SPF and/or broad spectrum tests need to be modified to address 
sunscreen sprays. The Dosage Forms ANPR also solicited studies 
comparing spray sunscreens to other eligible dosage forms to see 
whether the dosage forms are comparable.
    Four comments provided data from multiple studies examining and 
comparing the performance of spray and lotion sunscreens on a variety 
of parameters, including amounts applied, uniformity of coverage as 
measured with UV filter photography, comparative SPF results, and 
consumer ratings of ease and effectiveness of application, among 
others. FDA's evaluation of the information submitted indicated that 
key questions asked in the Dosage Forms ANPR were directly or 
indirectly addressed by these studies. These studies indicated that 
consumers like the convenience of spray sunscreens and adapt their use 
of these products to achieve effective coverage. Data provided on 
application uniformity lacked study reports and were difficult to 
compare directly, but--taken together--they suggest a high degree of 
uniformity between sprays and lotions in coverage of exposed skin, as 
well as between different spray application scenarios such as spraying 
directly on skin or spraying followed by rubbing. Information submitted 
indicated that the amount of spray sunscreen dispensed is higher than 
the amount dispensed for sunscreen lotions, and that consumers are more 
likely to reapply sprays than lotions. There was no response from any 
stakeholder regarding consumers' compliance with directions to rub a 
spray sunscreen into the skin. However, data was provided suggesting 
that rubbing spray sunscreens into the skin did not enhance 
effectiveness. Based on these comments and the available data, we are 
not proposing to require that labeling provide instructions to rub 
spray sunscreens into the skin.
    Comments on the Dosage Forms ANPR also agreed, and we concur, that 
the current FDA-required SPF and broad spectrum tests are appropriate 
for evaluating the efficacy of sunscreens in spray dosage forms. SPF 
testing requires application of a set amount of sunscreen (2 mg/cm\2\ 
on each test subject), which can readily be done for spray sunscreen 
formulations. For example, comments on the Dosage Form ANPR stated that 
the SPF testing of sunscreen spray products can be conducted following 
the method described in the current rule by weighing out the liquid 
form and applying it to the skin. This premise is supported by data 
from SPF testing submitted in the comments. For example, one comment 
submitted five SPF testing reports conducted on sprays using the FDA-
required methods, in which the expected SPF values for the test 
formulations were almost identical to the SPF testing results. The same 
logic applies to broad spectrum testing, which also uses a defined 
amount of sunscreen by weight. Based on this information, we conclude 
that the current and proposed SPF and broad spectrum testing methods 
are also appropriate for spray dosage forms.
    c. Spray sunscreen safety. FDA has identified two primary safety 
concerns specific to spray sunscreen dosage forms: (1) The potential 
risk of respiratory harm from inhaling sunscreen ingredients and (2) 
the potential flammability risk when consumers are exposed to flame or 
heat before spray solvents have completely dried. For the reasons 
described below, we believe that both potential risks can be acceptably 
mitigated by proposed formulation limitations, labeling requirements, 
and adequate testing, and

[[Page 6231]]

thus propose to establish these as additional conditions in the 
monograph to ensure that sunscreen products in a spray dosage form 
would be GRASE.
    d. Inhalational toxicity. Broadly speaking, the human respiratory 
system consists of the upper respiratory tract (i.e., the airways of 
the nose to the larynx) and lower respiratory tract (the trachea and 
branching airways of the lung, including bronchi, bronchioles, and 
alveoli) (see generally Refs. 148 and 149). Much of the respiratory 
system is lined with a layer consisting of mucus cells and cilia that 
mechanically propel inhaled particles out of the lower respiratory 
tract toward the mouth, where they may be swallowed or expectorated 
(Refs. 148 and 149). The most significant concern associated with any 
product that may be accidentally inhaled is the potential risk of 
adverse effects associated with deep lung deposition, which occurs when 
particles in an aerosol (i.e., a suspension of airborne particles such 
as a sunscreen spray) reach the unciliated airways in the lung. 
Particles that can reach the unciliated airways of the deep lung are 
described as respirable and may be associated with serious adverse 
effects such as asthma, emphysema, bronchospasm, or chronic obstructive 
pulmonary disease; particles that do not reach the deep lung may be 
associated with less harmful adverse events such as local irritation of 
the upper airway, coughing, or sneezing (Refs. 149 to 151). The 
potential health risk associated with inhalation of hazardous aerosols 
depends on how much of a toxic substance is deposited in a given region 
of the respiratory tract and how much remains after physiological 
clearance occurs through mechanisms such as coughing, sneezing, 
mechanical transport, or, in the deep lung, engulfment by specialized 
cells or other protective action (Refs. 148 and 152).
    The pathogenic potential of inhaled aerosols depends on where in 
the respiratory tract a particle is deposited (Ref. 152). Whether spray 
particles that enter the body through inhalation at the nose or mouth 
will be deposited in the lung depends largely on their physical 
characteristics: Most notably particle size, with the likelihood of 
respirability increasing as particle size decreases (Refs. 148 to 153). 
The effects of particle size on respirability of inhaled particles is 
well studied. There is general agreement that particles greater than 10 
micrometers ([mu]m) in diameter may enter the mouth and the airway up 
to the larynx. Approximately 50 percent of particles up to 10 [mu]m in 
diameter can penetrate beyond the larynx to the thoracic region of the 
respiratory tract, while only particles smaller than 4 [mu]m reach the 
unciliated airways and alveolar region of the lungs (see generally 
Refs. 148 to 153). Thus, although there are little or no data on the 
potential inhalation toxicity of particular spray sunscreen 
ingredients, we are proposing that exposure to harmful levels of such 
ingredients can effectively be minimized by imposing particle size 
limitations on spray sunscreen products.
    Several comments on the Dosage Forms ANPR submitted results of 
particle size distribution testing using available methods and 
apparatus, with the aim of showing that exposure to inhaled sunscreen 
products or ingredients would be minimal and thus unlikely to cause 
adverse effects. The data submitted were similar and in some cases 
overlapping. In an analysis of pooled particle size distribution data 
from all submissions, representing 50 U.S.-marketed spray sunscreen 
products, 32 had particles smaller than 4 [mu]m in diameter and thus 
within the respirable portion of the total particle size distribution. 
However, the great majority of the particle sizes observed were 
nonrespirable. The highest percentage that any product had of particles 
smaller than 4 [mu]m in diameter was 0.43 percent and the mean was 0.22 
percent, which is extremely low.
    In addition to reviewing information from comments on the Dosage 
Forms ANPR, FDA conducted its own analysis of particle size 
distribution for 14 marketed spray sunscreens. In those tests, no 
sunscreen had more than 10 percent of particles in sizes less than 10 
[mu]m in diameter and only three had particles smaller than 5 [mu]m 
(Ref. 154).
    To limit the risks of unintentional exposure and potential 
associated adverse events to respirable particles in spray sunscreens, 
we are proposing limits on the size of particles dispensed from the 
consumer container for finished spray sunscreens in order for those 
products to be GRASE. We propose that 90 percent of the particles 
dispensed from the consumer container must be at least 10 [mu]m or 
greater in order to limit exposure beyond the larynx, and to prevent 
deposition in the deep lung, the minimum particle size dispensed from 
the consumer container must be no less than 5 [mu]m. This limit was 
chosen because it is the lowest whole number above the generally 
accepted threshold (4 [mu]m) at which particles enter the unciliated 
airway and because it allows for experimental error that may be 
inherent in particle size measurements. Sunscreen products that do not 
meet both limitations would not be GRASE because there is not 
sufficient information in the record to support a positive finding 
about their safety. We believe that, taken together, these two 
limitations would significantly reduce inhalation risk from spray 
sunscreens by reducing particle exposure to the larynx and deeper lung 
tissues. The particle size data submitted in response to the Dosage 
Forms ANPR also suggest that these limitations would be readily 
achievable without unduly burdening sunscreen spray manufacturers.
    With the establishment of these two limits, FDA believes that the 
risks of adverse events related to unintentional inhalation of spray 
sunscreens will be minimal. Stakeholders asserted that the risk of 
inhalation toxicity is already low, primarily based on particle size of 
marketed sprays. Limited data on adverse event reports and animal 
toxicity studies were also submitted in a few comments on the Dosage 
Forms ANPR, but were inadequate to support the safety of spray 
sunscreens in the absence of particle size limitations. If the particle 
size limitations proposed here are adopted, however, we do not believe 
that additional animal toxicity or other safety data need to be 
provided to support a GRASE finding for spray sunscreens.
    We are proposing that particle size testing to demonstrate 
compliance with the proposed limitations must be conducted on spray 
products as they are dispensed from the consumer container as part of 
the lot release testing that would be routinely completed as part of 
current good manufacturing practice (CGMP) compliance under part 211 
(21 CFR part 211). It is necessary to test the size of particles 
dispensed from the consumer container to ensure that particle size 
requirements are met under conditions of use by consumers.
    For purposes of these proposed particle size requirements, we are 
using the term particle size broadly to mean the discrete unit emitted 
from the spray container that is available for inhalation by a consumer 
when the product is applied. If the particle dispensed from the 
consumer container is a droplet that meets the size requirements, the 
consumer will not accidentally inhale it into the deep lung. However, 
if that same droplet breaks apart into smaller fractions when it is 
dispensed from the consumer container, those fractions would be the 
particles that must meet the size requirement to ensure that consumers 
will not inadvertently inhale them past the larynx.
    We are not proposing a specific test methodology for spray 
sunscreen particle size. Rather, sunscreen manufacturers would be 
obligated to ensure that particle size testing for their

[[Page 6232]]

sunscreen sprays would be conducted on each lot of the final product as 
dispensed from the consumer container in accordance with adequate 
written specifications. USP General Chapter 601 part B provides 
methodology and requirements for sprays, aerosols, and powders that 
include methodology to determine droplet/particle size distribution, 
and we expect to consider testing done in accordance with the USP as 
adequate to meet this proposed requirement (Ref. 155).
    We note that several comments on the Dosage Forms ANPR expressed 
concern about the potential inhalation risk from exposure to spray 
sunscreens that contain nanomaterials (as both active and inactive 
ingredients). One comment also recommended that FDA require the 
presence of such ingredients to be disclosed on spray sunscreen labels. 
FDA's approach to nanotechnology and nanomaterials in sunscreen 
products is discussed in section VII.E. FDA is not now proposing 
conditions of use, including labeling, for spray sunscreens that 
distinguish based on the presence of nanomaterials because we are 
proposing that any sunscreen spray that contains any particles smaller 
than 5 [micro]m when it is dispensed from the consumer container would 
not be GRASE. With respect to nanomaterials in spray sunscreens, we 
note that the primary determinant of inhalation risk is the size of the 
particles in emitted sprays, which may be larger than individual 
formulation components. Nanoscale ingredients would not pass the 
particle size limitations for spray sunscreens; therefore, if they were 
to be detected when sprayed from the consumer container during particle 
size testing, the sunscreen could not be marketed under the OTC 
monograph.
    In addition to the proposed limitations on particle size for 
sunscreen sprays and related testing, we are proposing to require that 
the following labeling be included in the directions for sunscreen 
sprays to minimize unintended inhalation:
     Hold container 4 to 6 inches from skin to apply.
     Do not spray directly into face. Spray on hands then apply 
to face.
     Do not apply in windy conditions.
     Use in a well-ventilated area and avoid inhalation.
    This language is the same as that published in the Dosage Forms 
ANPR. Its adoption was supported by comments on the Dosage Forms ANPR, 
and the language is widely used on currently marketed spray sunscreens 
consistent with the 2018 Final Guidance.
    e. Flammability risk. In July 2013, FDA issued a Consumer Update 
regarding persons catching on fire while wearing spray sunscreen 
products near an open flame:

    The Food and Drug Administration (FDA) has become aware of five 
separate incidents in which people wearing sunscreen spray near 
sources of flame suffered significant burns that required medical 
treatment. The specific products reported to have been used in these 
cases were voluntarily recalled from the market, so should no longer 
be on store shelves. . . . In the five incidents reported to FDA, 
however, the burns occurred after the sunscreen spray had been 
applied. The ignition sources were varied and involved lighting a 
cigarette, standing too close to a lit citronella candle, 
approaching a grill, and in one case, doing some welding (Ref. 156).

These cases all involved a single manufacturer's product that has since 
been voluntarily recalled. Review of adverse event reports since the 
voluntary recall of this product indicates that no additional cases 
involving spray sunscreens have been reported. However, sunscreens are 
often used in very hot outdoor environments with high ambient air 
temperatures. Sunscreens are also frequently used around sources of 
flame or sparks, such as grills, bonfires, smoking, or other ignition 
sources. To ensure safe use of spray sunscreens and to better inform 
consumers about potential flammability risks, we are proposing to limit 
the flammability and require flammability labeling of spray sunscreens 
under the OTC sunscreen monograph.
    FDA's general labeling regulations for OTC drugs provide for OTC 
monographs to require flammability labeling in suitable cases (Sec.  
201.66(c)(5)(ii)(C)) (21 CFR 201.66(c)(5)(ii)(C))), and we have done so 
for products such as topical antitussives (21 CFR 341.74) and wart 
removers (21 CFR 358.150). As we did for those products, we are 
proposing to require each spray sunscreen formulation to be labeled for 
flammability in accordance with the testing methodology described in a 
regulatory provision issued by the Consumer Product Safety Commission 
(CPSC) (see 16 CFR 1500.43a). We have proposed to incorporate this 
flash point testing methodology to address our concern regarding the 
flammability of sunscreen in the spray dosage form after it has been 
dispensed onto the skin. We therefore propose that all batches of 
sunscreen spray products be tested for flammability in accordance with 
16 CFR 1500.43a as part of batch release testing conducted in 
accordance with CGMP requirements.
    We are also proposing to define three flammability categories for 
use in regulating and labeling sunscreens: (1) Extremely flammable, (2) 
flammable, and (3) combustible. These definitions refer to flash point 
testing to be performed using the method described in 16 CFR 1500.43a. 
These definitions are analogous to certain CPSC definitions located at 
16 CFR 1500.3. Given the conditions under which sunscreens may be used, 
we are proposing that spray sunscreens found to meet the definition of 
extremely flammable in proposed Sec.  352.3(f) are not GRASE and may 
not be marketed under the OTC sunscreen monograph. Products found to 
meet the definition of flammable or combustible in proposed Sec.  
352.3(g) or (h) would be required to include the following language in 
the ``Warnings'' section of the drug facts labeling: [bullet] 
``Flammable'' or ``Combustible'' [as applicable] followed by a colon 
and the statement ``Keep away from fire or flame''.
    A further concern related to flammability is the time required for 
volatile solvents in a spray product to dry on the skin before a 
consumer can safely approach a source of heat or flame or can smoke 
without danger of fire. Typical sunscreen spray formulations contain 50 
to 80 percent of a volatile carrier, most commonly ethyl alcohol. These 
volatile solvents are necessary to the formulation to allow the product 
to be sprayed onto the skin. After spraying, the solvents are intended 
to rapidly evaporate leaving a film of UV filters on the skin surface 
as the product dries. Once a spray product is dry, the solvent is no 
longer present so the flammability risk is low. However, prior to this 
point, the flammability risk would be higher.
    We think that consumers should be warned to stay away from sources 
of flame while a flammable or combustible sunscreen spray dries. For 
this reason, we propose to require that each batch of a sunscreen spray 
product that meets the definition of flammable or combustible at Sec.  
352.3(g) or (h) be tested for drying time in accordance with written 
specifications. If the drying time is less than 5 minutes, we propose 
to require that the labeling state, ``Wait 5 minutes after application 
before approaching a source of heat or flame, or before smoking.'' If 
the drying time is at least 5 minutes but less than 10 minutes, we 
propose that the labeling would state, ``Wait 10 minutes after 
application before approaching a source of heat or flame, or before 
smoking.'' We propose that a sunscreen spray that is flammable or 
combustible and that takes 10 minutes or more to dry would not be GRASE 
because of the possibility of consumers approaching sources of fire

[[Page 6233]]

during such an extended drying period. We invite comment on this 
approach.
4. Powder Dosage Forms
    Although we have found powder sunscreens to be eligible for 
consideration in the OTC sunscreen rulemaking, we have tentatively 
determined that additional data as outlined below will be needed to 
support a conclusion that sunscreens in this dosage form are GRASE and 
to support consideration of appropriate labeling. Also, like sprays, 
powder sunscreens pose the potential for unintended inhalation, and for 
this reason, if admitted to the sunscreen monograph, the same 
limitations as to particle size here proposed for sprays would be 
expected to apply. For powder sunscreens that meet the particle size 
limitations proposed for sprays, we do not expect that additional 
toxicology data would be needed to address the potential health risks 
associated with inhalation.
    One comment on the Dosage Forms ANPR provided data on SPF and broad 
spectrum performance of five powder formulations, as well as data from 
repeated insult patch tests and photosensitivity studies that were 
asserted not to show any safety issues. FDA has conducted particle 
distribution testing on five powder sunscreens. The powder sunscreens 
tested had a larger proportion of relatively small particles compared 
to the sprays. Only one of the five powder sunscreens would have 
complied with the requirement we are considering that no more than 10 
percent of the particles could be smaller than 10 [micro]m in diameter, 
and that product was also the only one that would have met the 
prospective limitation of no particles smaller than 5 [micro]m in 
diameter (Refs. 153 and 154). Based on the data submitted, we believe 
that (current and proposed) SPF and broad spectrum test methods are 
appropriate for use with powder sunscreens, and we are not requesting 
additional respiratory safety information for powders that meet the 
same particle size limitations proposed for spray sunscreens.
    FDA invites comments and data on the following topics related to 
powder sunscreens:
     What amounts of powder sunscreens do consumers typically 
dispense?
     What amounts of powder sunscreens are effectively 
transferred to the skin?
     How uniform is the sunscreen application across the sun-
exposed area of the skin?
     How frequently do consumers reapply the product?
     Does rubbing a powder into the skin change sunscreen 
effectiveness?
     Are powder dosage forms water-resistant? If they are not 
water-resistant, is a direction to reapply every 2 hours sufficient to 
assure their safe and effective use?
     Can the powder dosage form be used safely and effectively 
over all areas of skin exposed to the sun, or should this dosage form 
be limited to the face?
     What factors, if any, should FDA consider in connection 
with particle size limitations or test methods for sunscreen powders?
     Are there important differences among powder types (e.g., 
loose, compact) or applicators that would affect particle size testing?

FDA will evaluate data and information submitted in response to these 
questions, as well as any other submitted or available data, to 
determine whether additional data are needed to support a final GRASE 
determination for this dosage form.

B. Proposed Maximum SPF and Broad Spectrum Requirements

    In the Stayed 1999 Final Monograph, FDA established SPF 30+ as the 
maximum labeled SPF value for sunscreen monograph products, and 
required that each sunscreen monograph active ingredient contribute a 
minimum SPF of 2 to finished sunscreen products (64 FR 27666 at 27672, 
27674 and 27675). The final monograph did not include any broad 
spectrum protection provisions. In its 2001 decision to stay the final 
monograph, however, FDA indicated that it was issuing the stay because 
the Agency intended to amend the sunscreen monograph to address 
requirements for both UVA and UVB radiation protection (66 FR 67485). 
FDA later addressed these issues in the 2011 L&E Final Rule, which, 
among other things: (1) Established optional broad spectrum labeling 
based on satisfaction of a critical wavelength test, (2) created an 
optional indication relating to skin cancer and early skin aging risk 
reduction for broad spectrum products with an SPF of 15 or higher, and 
(3) required a labeling warning for sunscreens that did not both 
satisfy the broad spectrum test and provide an SPF of at least 15 (76 
FR 35620 at 35626-35628) (L&E Final Rule). Concurrently with 
publication of the L&E Final Rule, FDA issued a proposed rule to raise 
the maximum labeled SPF value for sunscreen products containing 
sunscreen monograph active ingredients to SPF 50+ (76 FR 35672, June 
17, 2011).
    In the time since these 2011 publications, the body of evidence in 
the published literature on UVA radiation (particularly UVA I 
radiation) and its role in the development of skin cancer has grown. 
This new data about the harms of UVA exposure is a significant concern 
given, among other things, that with currently available sunscreens, 
consumers may unknowingly accumulate excessively large UVA doses by 
using sunscreens with high SPF values that either: (1) Do not pass 
FDA's current critical wavelength-based broad spectrum test or (2) have 
inadequate uniformity in their UVA protection. Because of these 
concerns, we are making a number of proposals designed, among other 
things, to couple a greater magnitude of UVA protection to increases in 
SPF values.
1. Background
    UV radiation includes both UVA and UVB rays. UVB rays (i.e., those 
with wavelengths from 290 to 320 nm) are higher energy, are much more 
effective at producing sunburn, and produce greater amounts of cellular 
damage (including DNA lesions, which can result in gene mutations 
linked to skin cancers) (Refs. 157 and 158). UVA rays (i.e., those with 
wavelengths from 320 to 400 nm) are lower energy and less effective at 
producing sunburn, but make up the majority of UV radiation, and 
penetrate much deeper into the skin, potentially causing oxidative 
damage (through formation of ROS) to skin pigment cells (Ref. 159). UVA 
rays also contribute to photo-aging (Ref. 157 and 160). Although the 
current scientific literature attributes UV-signature DNA lesions 
primarily to UVB wavelengths, UVA wavelengths can also produce DNA 
lesions. Although UVA wavelengths produce DNA lesions to a 
significantly lesser degree than UVB wavelengths do, DNA lesions 
produced by UVA rays have been reported to have slower repair rates 
(Ref. 157). UVA rays are comprised of UVA I rays (340 to 400 nm) and 
UVA II rays (320 to 340 nm). As discussed below, until recently, UVA I 
rays were generally not considered to contribute significantly to the 
harms associated with UV exposure.
    Sunscreen products must be labeled with an SPF value calculated 
using a standardized SPF testing procedure set forth in FDA regulations 
(see Sec.  201.327(i)). ISO 17166 CIE S 007/E was approved for 
incorporation by reference into Sec.  201.327(i) as of June 18, 2012 
(76 FR 35619, June 17, 2011). The SPF test measures the amount of UV 
radiation exposure it takes to cause

[[Page 6234]]

sunburn when a person is using a sunscreen compared with how much UV 
exposure it takes to cause sunburn when the person is not using a 
sunscreen. Sunscreens with increasing SPF values (up to a certain 
point) have been demonstrated to provide increased sunburn protection. 
Because SPF values represent a sunscreen's level of sunburn protection, 
they are primarily (though not exclusively) an indicator of expected 
protection from UVB radiation. To pass FDA's current test for broad 
spectrum labeling (Sec.  201.327(j)), however, sunscreens must 
demonstrate that, in addition to UVB protection, they also provide some 
UVA protection.
    Only products that have been determined to have a minimum SPF value 
of 15 and to pass our broad spectrum test may include statements in 
their labeling indicating that they decrease the risk of skin cancer 
and early skin aging caused by the sun when used as directed with other 
sun protection measures (Sec.  201.327(c)(2)). In contrast, sunscreens 
that have not been determined to provide both broad spectrum protection 
and an SPF value of at least 15 must include a skin cancer/skin aging 
alert warning to consumers that ``[s]pending time in the sun increases 
your risk of skin cancer and early skin aging'' and that ``[t]his 
product has been shown only to help prevent sunburn, not skin cancer or 
early skin aging'' (Sec.  201.327(d)(2)).
2. Increased Evidence of Harms Associated With Exposure to UVA 
Radiation
    Since publication of the 2011 L&E Final Rule and Max SPF PR, the 
strength of scientific evidence linking UVA exposure to skin cancers 
and other harms has increased. This evidence suggests that UVA 
wavelengths continue generating DNA lesions hours after UV exposure 
(Ref. 161) and that if left unrepaired, these DNA lesions can form UV-
induced mutations in many genes that have been detected in both 
melanoma and nonmelanoma skin cancers (Refs. 162 to 165). Further, 
unlike UVB-induced DNA lesions, which attenuate with skin depth, recent 
evidence indicates that DNA lesions induced by UVA I exposure show the 
opposite pattern, with both increased DNA lesions in the basal layer of 
the epidermis (where melanocytes and proliferating keratinocytes 
reside) and less efficient DNA lesion repair in the basal layer (Refs. 
166 and 167).
    Damage to cells in the basal layer (if left unrepaired or if 
inefficiently repaired) can lead to mutations in critical genes that 
increase the possibility that normal cells will transform into cancer 
cells. While inefficient DNA repair is a concern for all individuals 
exposed to UV radiation, this concern is particularly acute in those 
with xeroderma pigmentosum (a disease caused by a disorder of the DNA 
repair system), who have extreme sensitivity to UV radiation, and who 
develop both nonmelanoma skin cancer and melanoma with a high frequency 
and very early in life (Ref. 168). In addition to the skin cancer-
related risks associated with UVA exposure, increasing evidence shows 
that UVA I radiation also produces immunosuppression (Refs. 169 and 
170). This, too, is a general concern for all individuals, but is 
especially dangerous for certain at-risk populations (such as organ 
transplant recipients and others on immunosuppressive drugs).
    Given the above-described evidence, we are concerned about the 
existing potential for inadequate UVA protection in marketed sunscreen 
products. This is a particular concern with respect to high SPF 
sunscreen products that do not pass FDA's current critical wavelength-
based broad spectrum test or that (though they pass our current broad 
spectrum test) have inadequate uniformity in their UVA protection. 
Consumers using these products may, while successfully preventing 
sunburn, accumulate excessively large doses of UVA radiation, thereby 
exposing themselves to additional risks related to skin cancer and 
early skin aging. The International Agency for Research on Cancer has 
found that high SPF sunscreen products are associated with longer 
intentional UV exposures (Ref. 171), raising the concern that use of 
these products may result in significant doses of UVA radiation. We 
note that concerns relating to inadequate UVA protection came up in 
several comments we received in response to the 2011 Max SPF PR, and 
that these comments raised particular concerns about inadequate UVA 
protection in high SPF products. This concern has also grown over time 
in the published literature (Refs. 172 to 175).
    For all of these reasons, we are proposing a number of steps 
designed to couple a greater magnitude of UVA protection to increases 
in SPF values. As discussed in further detail below, we are also making 
proposals designed to address evidence of variability in SPF values and 
evidence showing additional clinical benefits associated with SPF 60 
sunscreens.
3. Broad Spectrum Proposals
    a. UVA I/UV ratio required to pass the broad spectrum test. We are 
proposing certain changes to the requirements to pass the broad 
spectrum test. Specifically, we are proposing to add to the current 
broad spectrum test a requirement that products meet a UVA I/UV ratio 
of 0.7 or higher. We note that the current broad spectrum test 
procedure would remain unchanged \40\ and that this new ratio would be 
calculated using data from the existing test, which should help 
minimize burden on manufacturers.
---------------------------------------------------------------------------

    \40\ We note that, as described in section IX.D.2.i, we are 
proposing a minor revision in equipment specifications for the broad 
spectrum test to respond to feedback that FDA received on this issue 
and proposing some minor revisions to current language to make clear 
our existing expectations.
---------------------------------------------------------------------------

    The current labeling regulation requires that sunscreens labeled as 
broad spectrum achieve a critical wavelength of 370 nm or greater 
(Sec.  201.327(j)). A sunscreen product's UV protection is often 
displayed as a curve on a graph showing the amount of UV absorbance the 
product provides at each wavelength in the UV spectrum (i.e., from 290 
to 400 nm). The ``critical wavelength'' of the product is the 
wavelength corresponding to 90 percent of the area under this curve. 
Higher critical wavelengths, therefore, illustrate greater breadths of 
UV protection across the 290 to 400 nm spectrum.
    Most sunscreen products--even if they achieve a critical wavelength 
of 370 nm or greater and therefore meet the current criteria for broad 
spectrum labeling--have historically covered the UVB and UVA II ranges 
preferentially. Given how much of the UVA portion of the UV spectrum is 
composed of UVA I radiation (see Figure 3 below) and given what we now 
know about the risks associated with UVA exposure, and with UVA I 
exposure in particular, ensuring that sunscreen products provide 
adequate protection in the UVA I portion of the spectrum is critical.

[[Page 6235]]

[GRAPHIC] [TIFF OMITTED] TP26FE19.002

    We are therefore proposing to require that in order to pass the 
broad spectrum test, a product must demonstrate that it provides a UVA 
I/UV ratio of 0.7 or higher, indicating that the product provides a 
minimum measure of UVA I radiation absorbance relative to total UV 
radiation (i.e., UVB + UVA) absorbance, in addition satisfying to the 
370 nm critical wavelength requirement. Requiring a UVA I/UV ratio of 
0.7 or higher for broad spectrum products would mean that these 
products would have a more uniform amount of radiation protection 
across the UVA I, UVA II, and UVB ranges. This improved fidelity across 
the UV spectrum is especially important for high SPF products which, as 
discussed above, are associated with longer intentional sun exposure, 
which in turn can result in significant doses of UVA radiation. This 
proposed UVA I/UV ratio would also help eliminate the current potential 
for a product labeled as broad spectrum that has a higher SPF value to 
provide (unbeknownst to the consumer) poorer broad spectrum protection 
than a product labeled as broad spectrum with a lower SPF value 
(depending on the particular combination of active ingredients used in 
the product and which parts of the UV spectrum they absorb). For 
example, under the current testing regime, a sunscreen that is labeled 
``broad spectrum SPF 30'' could provide less UVA protection than a 
sunscreen labeled ``broad spectrum SPF 15.''
    We note that FDA first raised concerns relating to the adequacy of 
UVA protection in sunscreen products in 2007 (see 72 FR 49070 at 49104 
to 49107). At that time, we proposed a similar ratio to the one we are 
proposing today as part of a different, more complex proposal for 
testing and labeling to address broad spectrum protection that, among 
other things, included both in vitro (spectrophotometric) and in vivo 
(clinical) testing for UVA radiation, as well as a four-tier UVA star 
rating labeling system. In response to comments describing purported 
disadvantages of that proposal, including general comments that the 
proposal was overcomplicated, specific comments on the proposed in 
vitro testing method, and comments indicating that ``[t]he proposed 
ratio places too much emphasis on the UVA I region, which is not 
generally considered to contribute significantly to the harmful effects 
of exposure to UV radiation'' (76 FR 35620 at 35650), we made a number 
of changes to our 2007 proposal in the 2011 L&E Final Rule. Those 
changes included elimination of the UVA I/UV ratio and adoption of the 
above-described critical wavelength test for establishing broad 
spectrum protection instead. As we noted in the preamble to the L&E 
Final Rule, our decision not to require the UVA I/UV ratio at that time 
was based, in part, on our agreement with comments stating that the 
scientific evidence available at that time indicated that UVA I 
exposure did not pose sufficient risk of harm to justify the emphasis 
placed on it by the ratio, and that the critical wavelength test 
provided a superior measure of broad spectrum protection (id. at 
35650).
    As described above, in the time since issuance of the L&E Final 
Rule, the body of evidence showing the harms of UVA exposure, and of 
UVA I exposure, in particular, has grown significantly (Refs.

[[Page 6236]]

159, 161, 162, 166, 167, and 169). It is now clear that in addition to 
producing the immunosuppression described above, UVA I exposure also 
results in increasing DNA damage with increasing skin depth (in 
contrast to UVB-induced DNA damage, which is reduced as skin depth 
increases). In addition, given that UVA I is the predominant portion of 
UVA radiation, new evidence (discussed in section IX.B.2) strengthening 
the link between UVA radiation and skin cancer development raises our 
concerns about the potential for inadequate protection in the UVA I 
portion of the UV spectrum. Accordingly, we no longer agree with the 
earlier comments suggesting that UVA I does not contribute 
significantly to the harmful effects of exposure to UV radiation, or 
with our 2011 conclusion that a UVA I/UV ratio requirement would 
therefore place too much emphasis on this portion of the UV spectrum.
    We emphasize that we are not proposing to replace the existing 
critical wavelength test, and that the proposed ratio would supplement 
(and be calculated using data from) the existing broad spectrum test. 
We also note that the UVA I/UV ratio we are proposing would result in a 
level of UVA protection similar to what is achieved via the European 
Union's recommended minimum UVA protection factor of \1/3\ of the 
labeled SPF and via the United Kingdom's Boots 3-star rating (the 
United Kingdom has for decades used a tiered star rating system based 
on an alternative ratio method) (Refs. 173 and 174). We note that data 
collected in 2009 about 330 sunscreen products commercially available 
in the United States showed that, at that time, more than half of these 
products already satisfied the broad spectrum test we are now proposing 
(see Comment, Docket No. FDA-1978-N-0018-0690).
    b. Broad spectrum requirement for all products that are 
=SPF 15. We are also proposing to require that all sunscreen 
products with SPF values of 15 and above demonstrate that they provide 
more uniform protection across the UVA I, UVA II, and UVB ranges of the 
UV spectrum by satisfying FDA's revised broad spectrum test. This 
proposal is designed to link increases in SPF value not only to 
increases in UVB protection, but to increases in the magnitude of UVA 
protection as well. We note that a consumer using a sunscreen that 
provides robust protection against sunburn but that does not pass FDA's 
revised broad spectrum test--and therefore provides inadequate UVA 
protection--may fail to get out of the sun, thereby exposing themselves 
to higher levels of UVA radiation than if they had not been protected 
from sunburn. Given the increasing evidence of major health risks 
associated with UVA exposure, we propose to find that such products 
(those with SPF values of 15 and greater that do not provide sufficient 
protection across the UV spectrum (as demonstrated by satisfying FDA's 
revised broad spectrum requirement)) are not GRASE. At the same time, 
we conclude that the evidence described above regarding the 
contribution of UVA I to skin carcinogenesis, coupled with the evidence 
reviewed in the 2011 L&E Final Rule (see 76 FR 35620 at 35630-35634), 
supports the proposal to include sunscreen products that have an SPF of 
15 or higher and also pass the revised broad spectrum test in the 
sunscreen monograph with indications both for use to help prevent 
sunburn and for use, as directed with other sun protection measures, to 
reduce the risk of skin cancer and early skin aging caused by the sun. 
As we indicated in the L&E Final Rule, the whole range of UV radiation, 
and not specific wavelengths, is a human carcinogen, and the exact 
wavelengths most responsible for these harmful effects are not known 
(see id. at 35631, 35633). To assure that a clinically meaningful 
reduction in the risks of skin cancer and early skin aging is achieved, 
then, a product must contribute to substantially limiting overall UVB 
and UVA exposure (see id. at 35630, 35631-35632), as will be assured by 
our proposal to couple the enhanced breadth of protection across the 
UVA spectrum provided by the revised pass criteria for the broad 
spectrum test with the magnitude of protection assured by requiring a 
minimum SPF of 15.
    By requiring that all sunscreens with SPF values of 15 or more 
satisfy the (new) broad spectrum standard (including the new ratio 
requiring proportionate protection), this proposal will also enable 
consumers to select a product primarily by numerical (SPF) value on the 
label, having assurance that, when used as directed, a product labeled 
with a higher numerical SPF value provides proportionately more 
protection not only against sunburn, but also against skin cancer and 
skin aging than lower numbered products \41\ (provided that the product 
provides an SPF of at least 15). In doing so, this proposal also 
eliminates another source of potential confusion permitted by the 
current labeling regime, in which a higher numbered product (for 
example, one labeled SPF 30) may provide inferior protection against 
UVA radiation than a lower numbered product (for example, one labeled 
Broad Spectrum SPF 15).
---------------------------------------------------------------------------

    \41\ As noted in section III.A.2, only those broad spectrum 
sunscreen products that have an SPF of 15 or higher have been shown 
to help prevent skin cancer and early skin aging.
---------------------------------------------------------------------------

    c. Sunscreen products with SPFs <15. As noted above and in section 
III.A.2, sunscreen products with SPF values below 15 have not been 
shown to reduce the risk of skin cancer or early skin aging caused by 
the sun, whether or not they provide broad spectrum protection. Because 
of this limitation, we considered proposing to remove from the 
monograph sunscreen products with SPF values lower than 15. However, as 
the Surgeon General has acknowledged (Ref. 5), some consumers may seek 
intentional sun exposure because (for example) they associate tanned 
skin with attractiveness and health. These consumers may seek some 
protection from sunburns and therefore, select a low SPF product (i.e., 
one with an SPF value below 15). If such products are removed from the 
market, these consumers may choose not to use a sunscreen product at 
all rather than use a broad spectrum product with an SPF of 15 or 
above.
    Although the benefits of sunscreen products with SPFs below 15 
(which are not indicated to reduce the risk of skin cancer or early 
skin aging) are limited, FDA believes that the use of such products is 
preferable to the use of no sunscreen at all. Thus, to provide sunburn 
protection for these consumers, FDA is proposing that sunscreens with 
SPF 2 to 14 that bear prominent labeling regarding their limited use 
for sunburn prevention and the risks associated with spending time in 
the sun (see sections IX.B.1 and IX.C) may remain on the market without 
approved NDAs. Because products with SPFs below 15 have not been 
demonstrated to reduce the risk of skin cancer, FDA is not proposing to 
require products with SPF values under 15 to pass the broad spectrum 
test. However, we seek comment on whether the limited benefits such 
sunscreen products confer outweigh the risks of sunscreen drug exposure 
and the potential false sense of security provided regarding UV 
protection (i.e., whether such sunburn-only sunscreen products are 
GRASE and should remain on the market without approved NDAs).
4. Maximum SPF Value Proposals
    a. Maximum labeled SPF value would be SPF 60+. In conjunction with 
the broad spectrum proposals described above, we are also proposing to 
raise the maximum labeled SPF value for

[[Page 6237]]

products containing sunscreen monograph active ingredients to SPF 60+. 
Under this proposal, sunscreen products with SPF values of 60 or 
greater would be labeled ``SPF 60+.''
    FDA has proposed to raise the maximum SPF value that sunscreens 
marketed pursuant to the OTC Monograph System can display on their 
labeling several times. In the 1978 notice of proposed rulemaking, we 
proposed that such sunscreens be labeled with a maximum SPF value of 15 
(43 FR 38206 at 38213 to 38214). In the 1999 final monograph, we 
determined that that cap should be increased to SPF 30+ (64 FR 27666 at 
27675). In 2007 (72 FR 49070 at 49085 to 49087) and then in 2011 (Max 
SPF PR), we tentatively concluded that data existed to show that 
sunscreens with labeled SPF values of up to 50+ provide additional 
clinical benefit to consumers. Our proposal today to increase the 
maximum labeled SPF value to 60+ is similarly based on data showing the 
additional clinical benefit provided by SPF 60 sunscreen products when 
those products also provide broad spectrum protection.
    In the 2011 Max SPF PR proposing an SPF 50+ cap, we noted that the 
record, at that time, lacked adequate data demonstrating that sunscreen 
products with SPF values above 50 provided additional meaningful 
clinical benefit over and above what was provided by SPF 50 protection 
(76 FR 35672 at 35672 to 35674). We requested data showing that such 
clinical benefits existed (id.). In response to both the 2007 and 2011 
proposals, we received comments providing citations to data showing the 
additional meaningful clinical benefit provided by sunscreen products 
with SPF values of 60 for certain at-risk populations when those 
sunscreens also included broad spectrum protection. (See, e.g., Ulrich 
et al. (showing statistically significant protection of organ 
transplant recipients, who are highly susceptible to nonmelanoma skin 
cancer, from squamous cell carcinoma with use of broad spectrum SPF 60 
sunscreen) (Ref. 176); see also Comment FDA-1978-N-0018-0710, August 
31, 2011, citing Kuhn et al. (showing statistically significant 
prevention of skin lesions in topical lupus erythematosus patients with 
use of broad spectrum SPF 60 sunscreen after exposure to either UVA I 
source or UVA II/UVB source) (Ref. 177); Faurschou et al. (showing 
prevention of urticarial reaction in subjects with idiopathic solar 
urticaria with use of broad spectrum SPF 60 sunscreen) (Ref. 178); 
Fourtanier et al. (showing lower levels of polymorphous light eruption 
in subjects using broad spectrum SPF 60 versus SPF 50 products (Ref. 
179)). Based on the additional meaningful clinical benefit provided by 
broad spectrum SPF 60 sunscreens shown in these studies, we are 
proposing to raise the maximum labeled SPF value to SPF 60+.
    Because the studies demonstrating the additional meaningful 
clinical benefit provided by SPF 60 sunscreens all used sunscreens that 
also provided broad spectrum protection, however, the additional 
clinical benefit shown to exist at SPF 60 cannot be decoupled from the 
broad spectrum protection provided by those products. That is, the 
additional meaningful clinical benefit shown in these studies may have 
been the result of the sunscreens' protection against rays in the UVB 
range or in the UVA range, or both. For this reason, our proposal to 
recognize the additional meaningful clinical benefit provided by 
sunscreens with SPF values above 50 is consistent with, and dependent 
upon, our proposal that all sunscreen products with SPF values of 15 
and above be required to provide broad spectrum protection.
    Given the lack of data showing that sunscreens with SPF values 
above 60 provide additional meaningful clinical benefit, however, we 
are proposing not to allow labeled SPF values higher than 60+. Labeling 
sunscreen products with SPF values higher than what has been shown to 
provide additional meaningful clinical benefit could have unintended 
negative consequences. For example, as discussed above, such products 
may inadvertently promote extended solar exposures because consumers 
feel protected and assume that the higher SPF value implies that 
greater UV exposure is safe (see, e.g., Autier, et al., 2007 (Ref. 
171)).
    b. Formulation cap for sunscreen products of SPF 80. Although we 
are proposing that the maximum labeled SPF value will be SPF 60+, we 
are proposing to permit the marketing of sunscreen products formulated 
with determined \42\ SPF values up to 80. We are proposing to permit 
this additional formulation margin in part because of the inherent 
variability in SPF test results. A sunscreen product's SPF value is 
calculated from measurements that are based on an investigator's visual 
evaluation of an individual test subject's erythema response to a 
series of UV doses administered in successive sites on the subject's 
back. Because the administered UV dose series for the final minimal 
erythema dose (MED) \43\ of a sunscreen with an expected SPF of 60 
increases by 15 percent with each successive dose (see Sec.  
201.327(i)(5)(iii)), a difference in judgment of one site in opposing 
directions would result in up to approximately 30 percent variability 
in the assessment of the amount of exposure that resulted in the 
erythema.\44\
---------------------------------------------------------------------------

    \42\ As used in this preamble, the determined SPF value is the 
SPF value that equals the largest whole number less than SPF-(t*SE), 
determined for a sunscreen product in accordance with Sec.  
201.327(i). See also section IX.D.2.b, where we propose to define 
this term in the regulation.
    \43\ The minimal erythema dose (MED) is the smallest UV dose 
that produces perceptible redness of the skin (erythema) with 
clearly defined borders at 16 to 24 hours after UV exposure (Sec.  
201.327(i)(5)(i)).
    \44\ The determination of SPF for each subject is calculated via 
a ratio of the MED of protected skin over the final MED of 
unprotected skin. In a scenario in which the final MED of 
unprotected skin is underestimated by 15 percent and the MED of 
protected skin is overestimated by 15 percent, this would present 
approximately 30 percent variability for the individual subject.
---------------------------------------------------------------------------

    Allowing the marketing of sunscreen monograph products with 
determined SPF test results up to 80 would, therefore, more fully 
account for the range of variability in SPF test results for sunscreen 
products labeled SPF 60+. We are also proposing this formulation margin 
to provide manufacturers with additional formulation flexibility that 
we hope will help facilitate the development of products with greater 
UVA protection, given our expectation that active ingredients added for 
the primary purpose of increasing UVA protection would contribute to a 
sunscreen's determined SPF value as well. We seek comment on whether 
SPF 80 is the appropriate formulation cap to accomplish these 
objectives.
    We are proposing not to allow the marketing (without an approved 
NDA) of sunscreen products with determined SPF values above SPF 80. 
This proposal follows from the principle that if the addition of 
ingredients to a drug does not provide additional clinical benefit but 
potentially increases the risk associated with the drug, this shifts 
the benefit-risk calculation and renders the drug not GRASE (see, e.g., 
76 FR 35673 at 35675). In light of this principle, we solicited 
comments in 2011 on the appropriateness of a formulation cap for 
sunscreen products (id.).
    Some of the comments that we received in response to the 2011 Max 
SPF PR expressed concerns (in general) about the safety of unnecessary 
exposure to sunscreen active ingredients. We received only one comment, 
however, directly addressing the question of an SPF formulation cap. 
That comment emphasized that there was no formulation limit in other 
countries using an SPF labeling cap, and

[[Page 6238]]

that the list of permitted active ingredients in the monograph itself 
establishes an SPF ceiling for the formulation as a whole. FDA rejects 
the premise that the list of permitted active ingredients establishes 
an adequate SPF cap for sunscreen formulations, as this theory does not 
take into account the potential addition of new GRASE ingredients to 
the list of active ingredients under the monograph. This comment also 
appears to imply that the maximum concentration of each active 
ingredient correlates specifically to a particular numerical 
contribution to the total SPF value of the product. This has not been 
established (see 64 FR 27666 at 27674 and 27675 (noting that 
formulation techniques may enable increases in SPF without use of 
higher concentrations of active ingredients)). In addition, as 
mentioned in 2011 in the Max SPF PR (76 FR 35672 at 35674), the 
theoretical increase in protection implied by higher SPF values 
generated in a laboratory does not necessarily correspond to meaningful 
additional sunburn protection for consumers in actual use conditions. 
Given that a solar simulator in a lab can produce much higher UV doses 
than a consumer would receive from the sun (even in the most extreme 
situations), it is unlikely that a consumer could ever actually reach 
the theoretical ceiling created by the list of permitted active 
ingredients.
    Given the lack of demonstrated clinical benefit for sunscreens with 
determined SPF values above SPF 60, and the potential for risks--
discussed elsewhere in this document--associated with exposure to 
sunscreen active ingredients, we propose not to permit the marketing 
(without an approved NDA) of sunscreen products with determined SPF 
values above SPF 80 (which reflects a formulation margin intended both 
to give full effect to the SPF 60 limit and to enable formulation 
flexibility).
    c. Proposal for =SPF 15 labeling. Finally, we are 
proposing to require that sunscreen monograph products with determined 
SPF values of 15 or above be labeled with an SPF number corresponding 
to the lowest number in a range of tested SPF results, as shown in 
table 5.\45\ For example, sunscreens testing at SPF 15 to 19 would be 
labeled ``SPF 15''; those testing at 40 to 49 would be labeled ``SPF 
40.'' \46\
---------------------------------------------------------------------------

    \45\ We note that the use of ranges to represent SPF values on 
product labeling is already in use in Australia and the European 
Union (Refs. 180 and 181).
    \46\ The proposed labeled values are expressed in increments of 
5 for products with determined SPF results of 15 to 29.9 (i.e., SPF 
15, SPF 20, SPF 25), but for determined SPF results of 30 or more, 
the proposed labeled values are expressed in increments of 10 (i.e., 
SPF 30, SPF 40, SPF 50, with a proposed maximum of SPF 60+.).
---------------------------------------------------------------------------

    This proposal is designed to avoid misleading consumers about the 
relative efficacy of sunscreen products, given the lack of clinical 
data showing meaningful efficacy differences between closely grouped 
SPF values. We note that in the 2011 L&E Final Rule, FDA declined a 
request that SPF be labeled in multiples of five, stating that there 
was no mathematical or statistical basis for this labeling approach 
because SPF values could generally be determined with a precision that 
allowed for SPF values to be labeled in intervals of less than five 
units. New data showing variability both between tested SPF values for 
individual study subjects and for determined SPF results achieved 
across multiple labs testing the same sunscreen formulation (i.e., 
variability inherent in a clinical test that relies on visual 
assessments) (FDA-1978-N-0018-0740, 2011; Ref. 182), however, has 
caused us to reexamine this issue.
    As described above, the clinical SPF test is conducted using a 
solar simulator to administer several specified doses of UV radiation 
that increase by 15 to 25 percent with each successive dose to a human 
subject's back in both sunscreen-treated and untreated areas (with the 
specific UV doses being derived from the expected SPF of the product 
and a determination of the individual subject's UV sensitivity). The 
clinical investigator then visually evaluates both the sunscreen-
treated and untreated areas of the subject's back to identify the areas 
with perceptible skin redness (erythema) that has clearly defined 
borders. Determining which of several areas on a single subject's back 
should be considered to meet this ``clearly defined borders'' criteria 
is an exercise of clinical judgment. Once the investigator has made 
this judgment, he or she then records the smallest dose of UV radiation 
it took to create an area with the observed skin reaction of erythema 
with clearly defined borders. After assessing multiple individual test 
subjects this way, the resulting UV exposure information is used in 
calculating the determined SPF value of the sunscreen being tested. The 
data we reviewed suggest that the clinical evaluation undertaken during 
this process creates variability that justifies the use of SPF ranges.
    For example, in a study using panels of five subjects, the mean SPF 
values observed across multiple labs ranged from 54 to 82 for a target 
SPF 80 (FDA-1978-N-0018-0740, 2011). This same study also evaluated a 
scenario where a lab was not told the target SPF, but was rather given 
a range of SPF 20 to 100 for a product with an expected SPF of 100. The 
results showed that it was extremely difficult for labs to reproduce 
the labeled SPF 100, with mean SPF values ranging from 37 to 75. In a 
second study with multiple panels of 25 subjects that was controlled 
and randomized, the determined SPF of two sunscreen formulations tested 
across four labs ranged from 63 to 69 for a target SPF 70 and from 82 
to 89 for a target SPF 90 (Ref. 182). Although the magnitude of the 
differences observed in this second study were not statistically 
significant, the fact that multiple labs determined different specific 
numerical values for a single formulation suggests that the use of 
labeled values representing ranges more accurately represents the sun 
protection provided by a product, and therefore is appropriate to avoid 
misleading consumers.
    We note that variability in SPF values is exacerbated at high SPFs. 
For example, individual test results with 30 percent variability from a 
determined SPF value of 20 would range from SPF 14 to SPF 26; 
individual test results with 30 percent variability from a determined 
SPF value of 50 would range from SPF 35 to SPF 65. Accordingly, as 
shown in table 5, we propose that the range of tested values reflected 
in the labeled SPF number should be wider at higher SPF values and 
narrower at lower ones, and that the requirement that labeled SPF 
values correspond to ranges rather than precise numerical values is not 
necessary below SPF 15.

                  Table 5--Proposed SPF Labeling Ranges
------------------------------------------------------------------------
      Range of determined SPF values        Associated labeled SPF value
------------------------------------------------------------------------
60-80.....................................  60+.
50-59.....................................  50.
40-49.....................................  40.
30-39.....................................  30.
25-29.....................................  25.
20-24.....................................  20.
15-19.....................................  15.
2-14......................................  Determined SPF Value.
------------------------------------------------------------------------

C. Proposed PDP Labeling Requirements

    We are also proposing some revisions to the principal display panel 
(PDP) for sunscreen products (the PDP is the portion of an OTC drug 
product label that is most evident when the product is displayed for 
retail sale (Sec.  201.60)). In addition to satisfying general OTC drug 
labeling requirements found in part 201,

[[Page 6239]]

sunscreen product PDPs are currently required to satisfy specific 
labeling requirements in Sec.  201.327. We are proposing to amend these 
requirements for sunscreen PDP labeling (currently codified in Sec.  
201.327(a) and (b), and (for the statement of identity of products that 
also include skin protectants) in Sec.  201.327(h)) to help consumers 
better understand, evaluate, and compare sunscreen products by 
providing additional information on the PDP, and by ensuring the 
prominence and readability of information required to appear on the 
front of the container or package. We are also proposing to renumber 
and consolidate provisions on PDP labeling and the statement of 
identity (SOI) in Sec.  201.327(b) to incorporate new proposed 
provisions in Sec.  201.327(a), as described in section IX.D.2.b of 
this preamble. In addition, we are proposing that labeling a sunscreen 
product in accordance with proposed Sec.  201.327(b) would be a 
condition for marketing a sunscreen under the OTC sunscreen monograph 
in part 352.
    We are proposing to revise the current SOI, which is required to 
appear on the PDP by both current and proposed Sec.  201.327. 
Currently, the SOI for sunscreens under this regulation contains ``the 
established name of the drug, if any'' and identifies the product as a 
``sunscreen.'' The revised SOI would consist of an alphabetical listing 
of all sunscreen active ingredients in the product using the names 
shown in Sec.  201.327, followed by ``Sunscreen'' and the product's 
dosage form (such as lotion or spray). In light of these proposed 
changes to the SOI for sunscreens, we are also proposing harmonizing 
changes to the provisions that address the SOI for products that 
combine sunscreen and skin protectant active ingredients (proposed 
Sec.  201.327(h) and cross-referenced in the sunscreen monograph in 
Sec.  352.60 (21 CFR 352.60) and in the skin protectant monograph in 
Sec.  347.60 (21 CFR 347.60)).
    The proposal to list all active ingredients as part of the SOI is 
generally consistent with SOI labeling of other OTC and prescription 
drugs. Providing information about a product's active ingredients and 
dosage form would supplement other important elements of the PDP (SPF, 
broad spectrum, and water resistance information) to provide a succinct 
summary of the product's key characteristics on the front of the 
package or container. We expect that this approach would enable 
consumers to more readily compare differing products and either select 
or avoid a given product accordingly. As an indication that consumers 
value information about a sunscreen's active ingredients, an analysis 
of top-rated sunscreen product reviews on Amazon.com found that product 
ingredients were listed as a positive factor in 17 percent of 
responses, and a negative factor in 10 percent of responses (Ref. 183).
    Based on a review of marketed sunscreen product labels, FDA is 
concerned that the SOI may currently be obscured by the inclusion and 
prominence of other printed or graphic information on the PDP. For this 
reason, we also propose to require the SOI to appear in direct 
conjunction with the most prominent display of the proprietary name, in 
a boldface font at least one-fourth the size of the most prominent 
printed matter on the PDP, and displayed so that the text is generally 
parallel to the base of the packaging. We propose that the entire SOI 
appear in the same font style, size, and color with the same background 
color, and as continuous text with no intervening text or graphic 
material other than text provided in accordance with the requirements 
for the SOI for a product that also includes a skin protectant, where 
applicable. These requirements would supplement, and not replace, the 
general requirements regarding the PDP and SOI for all nonprescription 
products in Sec. Sec.  201.60 and 201.61.
    Proposed Sec.  201.327(b) would incorporate the ``Broad Spectrum 
SPF,'' ``SPF,'' and ``Water Resistant'' statements that already must 
appear on the PDP as described in current Sec.  201.327(a). 
Additionally, for all products with SPF values below 15, we propose to 
require that the SPF statement be followed by an asterisk (*) directing 
the consumer to the statement ``*See Skin Cancer/Skin Aging Alert.'' We 
propose that the quoted statement must appear in the bottom 30 percent 
of the PDP. This statement is intended to draw the consumer's attention 
to the Skin Cancer/Skin Aging Alert that would continue to be required 
for these products as part of the ``Warnings'' in the Drug Facts 
portion of the label (Sec.  301.327(d)), because there is evidence that 
some sunscreen consumers are not reading this information in its 
current location (Refs. 184 and 185).
    Under the current regulation, the entirety of the ``Broad Spectrum 
SPF'' or ``SPF'' statement, as applicable, must appear on the sunscreen 
PDP in the same font style, size, and color and with the same 
background color, and, if used, the ``Broad Spectrum SPF'' statement 
must also appear as continuous text with no intervening text or 
graphic. To further ensure the prominence and readability of 
information that is important for consumers to evaluate and compare 
sunscreen products, we propose that these statements must also appear 
in bold typeface at least one-fourth the size of the most prominent 
printed matter on the PDP, and as text generally parallel to the base 
of the packaging.
    The proposed new ``*See Skin Cancer/Skin Aging Alert'' statement 
would also be required to appear in bold typeface at least one-fourth 
the size of the most prominent printed matter on the PDP, and as text 
generally parallel to the base of the packaging. In addition, the 
entire statement would appear in the same font style, size, and color 
with the same background color, and as continuous text with no 
intervening text or graphic.
    Finally, because water resistance is also an important 
characteristic for consumers when choosing a sunscreen, we also propose 
to apply comparable format requirements to the current ``Water 
Resistant'' statement. The statement would also be required to appear 
in bold typeface at least one-fourth the size of the most prominent 
printed matter on the PDP, and displayed so that the text is generally 
parallel to the base of the packaging. In addition, the entire 
statement would appear in the same font style, size, and color with the 
same background color, and as continuous text with no intervening text 
or graphic.

D. Proposed Requirements Related to Final Formulation Testing and 
Recordkeeping

    We are also proposing a number of revisions in Sec.  201.327: (1) 
To ensure that efficacy testing of the sunscreen formulation to be 
marketed is conducted in a way that protects human subjects and 
produces reliable results and (2) to enable FDA to assess compliance 
with this section's provisions going forward. We also propose to make 
compliance with these requirements a monograph condition in part 352.
1. General Approach to Final Formulation Testing
    Current Sec.  201.327 includes technical instructions for 
conducting the final formulation testing required to support the SPF 
values, water resistance statements, and broad spectrum statements 
shown in sunscreen product labeling. However, the current regulation 
does not explicitly address important broader considerations that are 
essential to ensure that final formulation testing is conducted and

[[Page 6240]]

documented in a way that verifiably provides for protection of human 
subjects in SPF and water resistance testing, as well as ensuring the 
reliability of all the testing data that underlies sunscreen labeling. 
We expect that persons responsible for conducting final formulation 
testing should already be following best practices in their current 
testing programs. However, we are concerned that many entities may not 
uniformly observe such practices and/or may not maintain the records 
needed to document compliance with the final formulation testing 
procedures set forth in Sec.  201.327. FDA's experience in conducting 
inspections and other actions to verify testing under the current 
provisions of Sec.  201.327 have suggested latent problems in these 
areas. Although limited, this experience reinforces FDA's belief that 
further clarification of regulatory expectations is necessary given the 
public health importance of ensuring that sunscreen products are 
effective and accurately labeled, and the broad range of entities that 
may be involved in bringing sunscreen products to market. Thus, we are 
proposing to incorporate FDA's current expectations more explicitly in 
the revised provisions. The proposed provisions are broadly consistent 
with current best practices for efficacy testing conducted in human 
subjects, and are not expected to require significant changes by 
reputable and experienced testing establishments. Key areas of concern 
that are addressed by the proposed revisions include the following.
    a. Protection of human subjects and oversight of clinical final 
formulation testing. Ensuring that clinical final formulation testing 
is both designed and conducted in a manner that will yield reliable 
results is critical, as is ensuring the protection of the human 
subjects on whom SPF and water resistance testing are conducted. 
Existing provisions within the SPF test in Sec.  201.327(i)(3)(iv) 
require that informed consent be obtained, but do not otherwise specify 
what this should involve or how clinical final formulation testing 
should be overseen. Across disciplines, testing involving human 
subjects is ordinarily conducted under institutional review board (IRB) 
oversight as a means of ensuring that informed consent and other human 
subject protections are provided and ensuring the integrity of study 
design and execution. FDA likewise expects that IRB review is already 
routinely being obtained by many establishments for SPF and water 
resistance testing.
    Nonetheless, our experience in conducting inspections and other 
actions to verify the reliability of final formulation testing under 
the current provisions of Sec.  201.327 have raised some questions 
about current practices. For example, FDA's observations have raised 
questions about whether and how entities conducting final formulation 
testing have put in place protocols and IRB oversight to ensure that 
test subjects do not repeat participation in testing with a frequency 
that could both compromise the ability to distinguish erythemic 
reactions to the test article and raise other questions about human 
subject protection. We are concerned that the lack of explicit 
requirements with regard to IRB oversight, as well as the cursory 
nature of the informed consent requirement in the current sunscreen 
labeling regulation, may result in inconsistent practices in the 
conduct of SPF testing that would compromise the reliability of 
results. Among other things, IRB review is critical to verify the 
adequacy of informed consent and to ensure that study protocols 
incorporate appropriate inclusion/exclusion criteria for subject 
selection (both to protect test subjects and to ensure the accuracy of 
results).
    b. Qualifications of study personnel. In some instances, it may not 
be clear upon inspection whether all aspects of a study were conducted 
by appropriately qualified personnel. For example, FDA would not 
consider it adequate for a technician, rather than an appropriately 
trained medical professional (such as, for example, a nurse or 
dermatologist), to perform a physical examination for potential nevi, 
moles, or other dermal lesions. As with all clinical and nonclinical 
testing done to support labeling, the use of properly trained and 
appropriately qualified personnel is essential to ensure the 
reliability and accuracy of test results. Documentation of the 
qualifications and training of personnel is also necessary to enable 
FDA's efficient enforcement of the FD&C Act.
    c. Documentation of equipment maintenance, study methods, and 
observations. Failure to maintain adequate records of testing 
equipment, methods, and observations can raise broad questions about 
the reliability of final formulation testing. In FDA's experience since 
the promulgation of current Sec.  201.327, there has been a lack of 
uniformity in testing entities' approaches to recordkeeping for final 
formulation testing, raising concerns about the adequacy of 
recordkeeping procedures. Failure of testing entities to keep adequate 
records to support final formulation testing may leave FDA unable to 
verify that the UV doses provided in SPF and water resistance test 
reports are accurate and valid. This is also true with respect to 
documentation of emission spectrum, the percentage of erythema-
effective radiation contribution, and changes to solar simulator 
components and the UV meter/dose controller system. Failure to 
accurately calibrate and maintain equipment at one testing entity may 
affect data across multiple clinical SPF testing studies and/or broad 
spectrum testing for multiple different final formulations that are 
ultimately sold under different labels. Inadequate recordkeeping may 
interfere with efficient enforcement. We propose to address these 
concerns and align the regulation with our existing expectations 
through revised regulatory provisions that are described further in the 
following sections.
2. Specific Regulatory Proposals
    a. Consequences of failure to observe best practices. We propose to 
clarify in the introductory paragraph of Sec.  201.327 that a product 
is deemed misbranded if its labeling relies on the results of final 
formulation testing that was not conducted in compliance with all of 
the applicable provisions of Sec.  201.327. Unless testing is conducted 
in compliance with all applicable provisions of Sec.  201.327, FDA does 
not have adequate assurance that the labeling reliably reflects the 
properties of the sunscreen product. Therefore, if final formulation 
testing is not properly conducted in accordance with this section, 
labeling a sunscreen with an SPF value or representation of water 
resistance or broad spectrum properties based on that testing is a 
misrepresentation to the consumer that the labeling reliably states the 
product's properties, which should also be consistent with a system of 
standardized sunscreen labeling that can be used to make cross-product 
comparisons. We propose to incorporate the provisions of Sec.  
201.327(a) through (l) into part 352 as conditions under which a 
sunscreen is GRASE and not misbranded. If these provisions are 
finalized, failure to comply with these conditions would make a drug 
subject to regulatory action as misbranded and an unapproved new drug.
    b. General obligations of responsible persons. We are aware that 
many different business relationships involving numerous entities are 
commonly used in the manufacturing, testing, and labeling of 
nonprescription sunscreen drug products. To clarify the locus of 
responsibility for ensuring that adequate final formulation testing 
procedures are in place, and to clearly delineate responsibility for

[[Page 6241]]

recordkeeping related to final formulation testing, FDA proposes a new 
defined term, responsible person.
    We propose to define the term responsible person in a way that is 
consistent with FDA's treatment of regulatory responsibilities for 
other OTC drug products and that is in alignment with requirements for 
adverse event reporting for over-the-counter drug products, in section 
760(b)(1) of the FD&C Act. The proposed definition for responsible 
person is ``the manufacturer, packer, or distributor whose name appears 
on the labeling of a sunscreen product covered by this section.'' 
Defining responsible person in this way will enable FDA to better 
assess compliance with Sec.  201.327 because it creates a chain of 
responsibility that is immediately apparent from the product's 
labeling. The responsible person, as identified on the labeling, is 
ultimately responsible for ensuring that the product bearing its name 
is labeled in accordance with the requirements of Sec.  201.327.
    The proposed revision of Sec.  201.327(a) would broadly set forth 
the general obligations of responsible persons with respect to final 
formulation testing under Sec.  201.327(i) and (j), and it would make 
clear that the responsible person is charged with ensuring that 
sunscreen products are appropriately tested. The obligations of 
responsible persons as enumerated in Sec.  201.327 are modeled after 
those of investigational new drug application (IND) sponsors under part 
312 (21 CFR part 312), but are somewhat modified to accommodate unique 
aspects of clinical and nonclinical sunscreen formulation testing. 
Because final formulation testing under Sec.  201.327(i) and (j) is 
intended to verify the claimed properties of a final formulation, and 
because this purpose is narrower in scope and duration than most 
clinical testing performed under FDA's IND regulations in part 312, a 
responsible person under proposed Sec.  201.327 would have 
responsibilities that incorporate some of the traditional 
responsibilities of investigators as well as those of sponsors under 
part 312. For example, FDA proposes to clarify that responsible persons 
must select appropriately qualified personnel to conduct testing, 
ensure compliance with the requirements for IRB review and obtaining 
informed consent, and monitor the compliance of personnel with 
investigators' statements.
    This proposed approach accounts for situations in which 
investigators and other personnel conducting final formulation testing 
are employees of the responsible person. We also propose to clarify 
that the responsible person must ensure that investigators and other 
personnel conducting investigations under Sec.  201.327(i) comply with 
requirements related to human subject protection and the appropriate 
conduct of clinical testing. We believe that this better reflects the 
employer/employee relationships that are more common in connection with 
final formulation testing rather than with clinical testing conducted 
under an IND. These proposed provisions regarding selection of 
personnel are also consistent with the existing obligations of 
manufacturers under parts 210 and 211 (21 CFR parts 210 and 211), both 
of which govern compliance with CGMPs.
    The proposed revision of Sec.  201.327(a)(1) permits a responsible 
person to transfer some or all of its obligations to another entity, 
consistent with current industry practice, except for obligations with 
respect to recordkeeping. The recordkeeping proposal is discussed in 
section IX.D. Failure of an entity to comply with provisions of this 
part governing responsibilities it has assumed would subject that 
entity to the same regulatory action as if it were a responsible person 
who had failed to comply with those obligations. This provision is 
analogous to the provision in FDA's regulations at part 312 allowing 
for transfer of obligations of IND sponsors.
    c. Adequate clinical testing procedures and conditions. Although 
current Sec.  201.327 requires ``legally effective written informed 
consent from all test subjects'' (Sec.  201.327(i)(3)(iv)), it does not 
address broader underlying requirements for conducting clinical 
testing. In light of the concerns we identified regarding current 
clinical testing procedures and conditions, we propose to amend Sec.  
201.327 by adding paragraph (i)(1), ``Adequate Clinical Testing 
Procedures and Conditions.'' We expect that final formulation testing 
conducted in compliance with the proposals in this paragraph will be 
more likely to ensure protection of human subjects while also more 
reliably determining the SPF value and water resistance properties of 
the final formulations being tested. Unless appropriate clinical 
testing procedures and conditions are adhered to, FDA cannot have 
confidence in the resulting labeled SPF and water resistance properties 
of the product.
    Proposed Sec.  201.327(i)1(B) and (C) have been added to make clear 
that FDA's regulations governing informed consent (part 50 (21 CFR part 
50)) and IRB approval of research (part 56 (21 CFR part 56)) apply to 
clinical final formulation testing that is conducted under Sec.  
201.327(i). In our view, as a matter of good clinical practice, IRB 
approval should already be routinely currently obtained for clinical 
final formulation testing under current Sec.  201.327 because it is 
essential to producing results that are scientifically sound and 
ethically appropriate. Because clinical final formulation testing 
required to support labeling under current Sec.  201.327 is not 
conducted under an IND or in support of a GRASE determination in the 
OTC sunscreen monograph, it was not previously included explicitly in 
the scope of testing covered by parts 50 and 56. We propose to rectify 
this omission by explicitly cross-referencing parts 50 and 56 in 
revised Sec.  201.327(i). This will clarify that both of these parts 
apply to clinical final formulation testing and will resolve any 
inconsistency in current practice.
    The proposed reference to part 50 clarifies FDA's position that 
legally effective written informed consent to participate in clinical 
final formulation testing should share the same properties as informed 
consent required for all other clinical testing covered by FDA's 
regulations in part 50. Similarly, by referencing part 56, the proposal 
ensures that final formulation testing is held to the same standards 
for IRB review as other clinical testing covered by FDA's regulations. 
In reviewing clinical protocols, IRBs have the ability to determine 
whether the protocol is adequately designed to study the endpoints 
sought, and to ensure that protocol elements, such as enrollment 
criteria, adequately protect both human subjects and the scientific 
rigor of the experiment.
    d. Control of personnel. We propose to place responsibility on the 
responsible person to ensure that investigators and other personnel 
conducting clinical final formulation testing adhere to the 
investigational plan, the signed investigator statement, and all 
applicable regulations. We also propose to place responsibility on the 
responsible person for ensuring human subjects' protection, including 
through appropriately reporting changes in the testing to IRBs, and by 
appropriately seeking prior IRB approval for any changes to the 
testing, except where necessary to eliminate apparent immediate hazards 
to human subjects. Under the proposed rule, responsible persons are 
also expected to obtain from each investigator, and retain for their 
records, a signed investigator statement. This is similar to what is 
required of sponsors of INDs, and it helps to ensure that the 
investigator is qualified, understands his or her obligations, and will 
comply with the requirements of

[[Page 6242]]

this paragraph and with the protocol. It also enables better oversight 
of clinical investigations by FDA because it creates a record of the 
investigator's relevant experience and qualifications.
    e. Research monitoring. A number of changes in Sec.  201.327(i)(1) 
are being proposed to ensure adequate monitoring of clinical final 
formulation testing. Revised Sec.  201.327(i)(1) would require that 
responsible parties inform all investigators testing a formulation if 
there are new observations about the drug, particularly with regard to 
adverse events or safe use. This is necessary to ensure proper 
communication between study personnel and protection of human subjects. 
Responsible persons must also monitor the conduct of investigations to 
ensure that clinical testing is being conducted in accordance with the 
protocol and with applicable regulations. If a responsible person 
discovers noncompliance by study personnel, then the responsible person 
must either secure compliance or remove the noncompliant personnel from 
conducting testing.
    Finally, we propose to require that investigators report adverse 
events and/or safety concerns to the responsible person, and that 
investigators also provide responsible persons with final reports at 
the conclusion of testing. We believe that this will ensure there is 
appropriate documentation and communication of adverse events and/or 
safety concerns that arise during testing. It will also ensure there is 
a record of SPF testing conducted under Sec.  201.327(i) that can be 
relied upon should questions related to a particular formulation arise 
when the sunscreen formulation is marketed. The proposed requirements 
are consistent with reporting required in the IND context, although, 
because of the short duration of the clinical final formulation testing 
conducted under Sec.  201.327(i), we are not proposing to require 
annual reporting.
    f. Test subject selection. We propose additional language regarding 
the selection of test subjects in Sec.  201.327(i)(4). This is an area 
in which FDA's inspections of testing entities have suggested a lack of 
consistency. We are particularly concerned that inclusion/exclusion 
criteria provide for adequate time between study and enrollment and 
prior UV exposure, such as from participation in a previous SPF test, 
sunbathing, or sunlamp use. Erythemal responses can remain for days 
after sunbathing, and it is known that pigmentation development takes 
up to a week after initial exposure and remains for weeks to months 
(Ref. 186). SPF clinical studies should not include individuals who 
have participated in sunbathing, tanning bed use, or another SPF 
clinical study for at least the past 4 weeks or perhaps longer if UV-
induced responses remain. The proposed clarification regarding conduct 
of physical examinations of test subjects reflects this consideration, 
and our additional proposal for IRB review, addressed elsewhere, will 
help ensure it is appropriately acted on.
    g. Applicability of registration and CGMP requirements. Proposed 
Sec.  201.327(k) reflects FDA's existing view that final formulation 
testing conducted under Sec.  201.327 constitutes the ``manufacture'' 
of a drug. As such, this testing must be conducted in an establishment 
registered in accordance with part 207 (21 CFR part 207) and section 
510 of the FD&C Act. This interpretation is consistent with the 
definition of manufacture in part 207, which includes ``each step in 
the manufacture, preparation, propagation, compounding, or processing 
of a drug . . . .'' (Sec.  207.1). The definition of manufacture as 
used in part 207 also ``includes manipulation, sampling, testing, or 
control procedures applied to the final product or to any part of the 
process, including, for example, analytical testing of drugs for 
another registered establishment's drug'' (id). Accordingly, a 
sunscreen product labeled in reliance on final formulation testing done 
in an unregistered establishment is misbranded under section 502(o) of 
the FD&C Act. This interpretation is also consistent with FDA's 
regulations in Sec.  330.1, which require that OTC monograph drug 
products be manufactured in a registered establishment in order to be 
generally recognized as safe and effective and not misbranded. The 
incorporation of this provision in Sec.  201.327, therefore, is 
intended to clarify an existing requirement for facilities performing 
this type of testing.
    We also propose to clarify that, as a manufacturing activity, final 
formulation testing conducted under this paragraph is expected to be 
done in accordance with CGMPs as set forth in parts 210 and 211 (see 
Sec.  210.3(b)(12), indicating that for the purposes of parts 210 and 
211, ``Manufacture, processing, packing or holding of a drug product 
includes packaging and labeling operations, testing, and quality 
control of drug products''). This is consistent with FDA's regulations 
in Sec.  330.1, which require compliance with CGMPs as a condition for 
OTC drug products to be GRASE and not misbranded when otherwise 
marketed consistent with conditions in a final monograph. Adherence to 
CGMP requirements in parts 210 and 211 includes compliance with the 
requirements to keep certain records and to have appropriately trained 
and qualified personnel. Failure to comply with CGMPs results in a 
product being adulterated under section 501(a)(2)(B) of the FD&C Act.
    h. Recordkeeping. To enable FDA to better monitor compliance with 
the requirements of Sec.  201.327, we propose to include specific 
recordkeeping requirements for final formulation testing. Accordingly, 
proposed Sec.  201.327(l) clarifies what records of testing performed 
under this section must be kept, by whom, and for how long. This 
provision also allocates responsibility for records maintenance and 
specifies what records must be made available to FDA for inspection. 
Recordkeeping is essential for FDA to evaluate whether required testing 
of final formulations is being conducted in accordance with Sec.  
201.327(i) and (j), and to enable the Agency to investigate 
postmarketing product failures or adverse events. Appropriate 
recordkeeping also enables FDA to conduct better and more efficient 
inspections of entities conducting final formulation testing.
    These recordkeeping requirements are in alignment with what is 
required for other types of manufacturing under CGMPs as set forth in 
parts 210 and 211. The proposed provisions are intended to clarify how, 
and for how long, records must be kept to substantiate required final 
formulation testing. We are proposing that records of testing must be 
kept by the responsible person (as newly defined in Sec.  201.327(a), 
discussed previously), as well as by any other entity that actually 
performs testing (under a transfer of obligations per Sec.  
201.327(a)(1) or otherwise). Requiring that records be kept by both the 
responsible person and the testing entity (if different) will enable 
FDA to more easily identify records supporting the labeling of any 
given final formulation even when the product is labeled with the 
responsible person's information, but testing and manufacturing was 
completed by a third party.
    The proposed recordkeeping requirements reflect FDA's experience in 
interacting with regulated industry. By requiring that records be kept 
by both the responsible person and any other entity that performs final 
formulation testing, the proposed rule will enable more efficient 
enforcement of the FD&C Act by, for example, allowing FDA to identify 
the source of formulation failures or apparent inconsistencies between 
the product labeling and consumer experience. The proposed 
recordkeeping requirements

[[Page 6243]]

will also assist FDA when it is conducting inspections of entities that 
perform final formulation testing for a number of different responsible 
persons and products, as we believe is the norm in this industry. 
Having ready access to records reflecting the overall conduct of final 
formulation testing during an inspection of such an entity is important 
because it will enable FDA to identify potential systemic problems in 
final formulation testing that may have an impact on the reliability of 
results supporting the labeling of multiple different sunscreen 
products marketed by a variety of responsible persons. We note that 
these recordkeeping requirements should not be understood to mandate 
duplicative records within the files of a single testing entity or 
single responsible party. For example, if one investigator is 
responsible for testing multiple final formulations, one copy of the 
signed investigator statement and Curriculum Vitae (CV) would be 
sufficient to support all formulations tested by that investigator.
    Consistent with FDA's view that final formulation testing is 
manufacturing, and thus is subject to CGMPs, equipment maintenance 
records and other records documenting compliance with CGMPs are 
expected to be maintained as required by parts 210 and 211. 
Accordingly, we clarify in proposed Sec.  201.327(l) that records 
documenting proper maintenance of equipment used in final formulation 
testing must be kept, consistent with existing obligations in 21 CFR 
211.68. In our view, this clarification will promote uniformity in 
adherence to best practices and will help ensure more accurate and 
reliable labeling of sunscreen products based on final formulation 
testing. Additional specificity has been proposed here to clarify how 
the more general recordkeeping provisions of part 211 apply to final 
formulation testing. To provide assurance that the test results are not 
compromised by faulty equipment maintenance or equipment failure, FDA 
proposes that testing entities must keep documentation demonstrating 
that equipment used for final formulation testing has been maintained 
in accordance with established written specifications. This requirement 
will enable FDA to more efficiently monitor compliance. Failure to keep 
required records of final formulation testing will render a product 
whose labeling relies on that testing adulterated under section 
501(a)(2)(B) of the FD&C Act. Without recordkeeping, there is no 
assurance that a sunscreen drug product has the identity and strength, 
and meets the quality and purity characteristics, which it purports or 
is represented to possess.
    This proposal also elaborates on recordkeeping necessary to 
document compliance with the requirements of proposed Sec.  201.327 
regarding conduct of final formulation testing.
    Proposed required records for SPF testing include records that: (1) 
Identify the facility conducting the testing; (2) identify the 
equipment used; (3) identify product samples and lots; (4) characterize 
the SPF standard that is used; (5) document parameters for water 
resistance testing; and (6) demonstrate compliance with the provisions 
governing adequate clinical testing procedures and conditions. For 
example, these would include documentation of IRB review, case 
histories for each human subject (which must document protocol 
deviations or injuries), administration of the sunscreen, and reading 
of test results. These proposed recordkeeping obligations are 
consistent with those required of parties engaged in human subjects 
testing governed by other portions of FDA's regulations.
    Required records of broad spectrum testing conducted under proposed 
Sec.  201.327(j) would include those records necessary for identifying 
the facility conducting the testing, providing information associated 
with the sample, identifying equipment used, and documenting sunscreen 
product application. These proposed requirements provide greater 
specificity than existing requirements in FDA's CGMP regulations, and 
are expected to increase uniformity in current practice.
    We propose to clarify FDA's expectations regarding access to 
records that responsible persons and other testing entities are 
required to keep under this paragraph. These provisions are consistent 
with FDA's inspection authorities in section 704 of the FD&C Act.
    i. Minor proposed revisions to test procedures. In addition to the 
changes discussed in section IX.D, we are proposing several 
modifications to the technical instructions for sunscreen final 
formulation testing (Sec.  201.327(i) and (j)) to clarify how the 
testing should be conducted.
    We are concerned that manufacturers conducting the SPF test 
procedure may be relying on determinations of the initial minimal 
erythema dose of unprotected skin (MEDu) generated too far in advance 
of testing the sunscreen product. The current regulation in Sec.  
201.327(i)(5) addresses four different determinations of MED for each 
test subject: (1) An initial MED for unprotected skin (initial MEDu); 
(2) a final MED for unprotected skin (final MEDu); (3) an MED for skin 
to which the SPF standard has been applied (ssMEDp); and (4) an MED for 
skin to which the sunscreen test product has been applied (tpMEDp). The 
initial MEDu is used to set the UV exposures administered to determine 
final MEDu, ssMEDp, and tpMEDp (see Sec.  201.327(i)(5)(iii)).
    Although the regulation already requires that each of the MED 
values be determined 16 to 24 hours after UV exposure, it merely notes 
that the final MEDu, ssMEDp, and tpMEDp are ``typically determined the 
day following determination of the initial MEDu'' (see current Sec.  
201.327(i)(5)(iv)). Because the skin reactivity of a test subject 
changes over time, we propose to clarify that the initial MEDu of a 
person's unprotected skin must be determined no more than 1 day before 
the UV exposures for final MEDu, ssMEDp, and tpMEDp are administered. 
We are also clarifying that to calculate the SPF value for each test 
subject, under proposed paragraph Sec.  201.327(i)(6), it is the 
subject's final MEDu that should be used.
    In our review of the testing requirements as part of this 
rulemaking, we also revisited our position on the input slit bandwidth 
specification in the in vitro broad spectrum test. In the 2011 L&E 
Final Rule, we modified the in vitro broad spectrum test that was 
proposed in the 2007 proposed rule to change the input slit 
spectrometer bandwidth specification from <=5 nm to <=1 nm. After the 
2011 final rule published, FDA received a comment from a spectrometer 
manufacturer arguing that the 1 nm input slit bandwidth specification 
was unreasonable. The manufacturer argued that common spectrometer 
models that are currently used to test sunscreens cannot comply with 
the <=1 nm input slit bandwidth specification, and those that can are 
more expensive, more difficult to use, and take more time to use. The 
manufacturer provided data that indicate that spectrometers with <=1 nm 
input slit bandwidths do not produce more reliable results than 
spectrometers with larger input slit bandwidths (see Comment, Docket 
No. FDA-2010-D-0509-0004). In light of this submission, FDA reassessed 
the input slit bandwidth parameters and concluded that <=5 nm will be 
sufficient for the broad spectrum procedure. Although decreasing 
bandwidth improves the ability to resolve closely spaced peaks (i.e., 
the spectral resolution), this is not a significant consideration for 
in vitro broad spectrum testing of sunscreen products because 
transmittance/absorbance curves for sunscreen

[[Page 6244]]

products are typically smooth with no individual sharp peaks. 
Accordingly, we propose to revise Sec.  201.327(j)(1)(iv) to require 
that spectrometer input slits be set to provide a bandwidth that is <=5 
nm.
    Establishing standardized testing procedures for sunscreen products 
and basing the products' labeling on this testing not only helps assure 
the safety and effectiveness of each product, it also provides 
consumers with consistent information about the sun protection 
properties of sunscreen products across brands, which in turn 
facilitates consumer comparisons when selecting products. Accordingly, 
we propose to delete the provision in Sec.  352.77 (21 CFR 352.77) 
addressing test modifications or alternative testing procedures. 
Section 352.77 indicates that such test modifications or alternative 
testing procedures require submission of a petition in accordance with 
Sec.  10.30 (21 CFR 10.30). The proposed removal of Sec.  352.77 does 
not alter the existing ability of a firm or individual to petition the 
Agency to amend the monograph (see Sec. Sec.  330.10(a)(12) and 10.30) 
to change the conditions that apply to products marketed under its 
provisions, such as to modify testing procedures for all products 
having some particular set of characteristics. Rather, the proposed 
deletion will clarify that the sunscreen monograph does not permit 
variation for individual products from the standardized testing 
procedures that are monograph conditions, because such variation could 
undermine important values supported by standardization.
    We are also proposing to correct a minor inaccuracy in the existing 
regulatory language describing testing procedures. Specifically, Sec.  
201.327(i)(1)(ii)(C) currently states that ``emission spectrum must be 
determined using a handheld radiometer.'' As written, this statement is 
inaccurate because a handheld radiometer cannot determine the emission 
spectrum of a solar simulator. We propose to resolve this error by 
clarifying that the handheld radiometer measures the solar simulator 
radiation intensity rather than the emission spectrum. Finally, we have 
proposed edits to certain provisions describing final formulation 
testing procedures to clarify our long-standing intention that these 
provisions of the test are requirements, not merely suggestions.

E. Proposed Status of Sunscreen-Insect Repellent Combination Products

1. Background
    Sunscreen-insect repellent combination drugs are products used on 
human skin that contain both a sunscreen drug component and an insect 
repellent component. A list of insect repellent products on the EPA 
website identified a number of such products as of November 2017 
(including multiple products within a single brand line).\47\ Among 
those products, the majority contained either N,N-Diethyl-meta-
toluamide (also called DEET) or IR3535 as the insect repellant, and a 
few contained oil of citronella as the insect repellent. Combination 
insect repellent-sunscreen products have been marketed in a variety of 
dosage forms (see section IX.A for a discussion of dosage forms), with 
labeled SPF levels ranging from 15 to 30 (Ref. 187). Some products are 
also labeled as water resistant or very water resistant (Ref. 187). The 
products are generally labeled for use without regard to age (Ref. 
187).
---------------------------------------------------------------------------

    \47\ EPA Product List (Ref. 187); a similar list of insecticide 
products on the National Pesticide Information Center (NPIC) website 
produced similar results (Ref. 188).
---------------------------------------------------------------------------

    FDA regulates sunscreens as drug products under the FD&C Act, and 
EPA concurrently regulates insect repellents as pesticides under 
FIFRA.\48\ FIFRA defines a ``pesticide'' in relevant part as ``any 
substance . . . intended for repelling . . . any pest,'' including 
insects (7 U.S.C. 136)(u)). Before they can be marketed, most skin-
applied insect repellents must be registered by EPA, although a few 
plant-derived insect repellent active ingredients are exempt from 
registration because EPA has determined they present minimum risk 
potential to humans (Ref. 189).
---------------------------------------------------------------------------

    \48\ Some insect repellents are also regulated by FDA as human 
drugs (e.g., pediculicides and scabicides intended to control 
parasites on humans) or animal drugs (e.g., pesticide products for 
oral administration to animals) (7 U.S.C. 136 et seq.); see also 
``MOU 225-73-8010 Memorandum of Understanding Between the 
Environmental Protection Agency and the United States Department of 
Health, Education and Welfare Food and Drug Administration,'' 
(available at https://www.fda.gov/aboutfda/partnershipscollaborations/memorandaofunderstandingmous/domesticmous/ucm115873.htm (accessed April 17, 2018).
---------------------------------------------------------------------------

    Sunscreen-insect repellent combination products have been marketed 
in the United States since before the OTC review began, but they have 
not previously been addressed in the rulemaking for the OTC sunscreen 
monograph (72 FR 7941 at 7943). Both FDA and EPA have historically 
declined to object to the marketing of these products pending the 
issuance of a final sunscreen monograph, provided that the sunscreen 
active ingredient(s) is listed in the stayed final monograph and the 
insect repellent component is registered with the EPA (79 FR 7941 at 
7943). In 2011, FDA issued a draft enforcement guidance intended for 
manufacturers who market OTC sunscreen products without an approved 
application, which recommended that manufacturers of sunscreen-insect 
repellent combination products should comply as closely as possible 
with FDA's sunscreen testing and labeling requirements in Sec.  
201.327. This guidance was finalized in May 2018 (Ref. 1).
    In the Federal Register of February 22, 2007 (72 FR 7941), FDA 
issued a notice seeking public comments on sunscreen-insect repellent 
combination products, and, in particular, whether FDA should amend the 
OTC sunscreen monograph to add conditions for marketing insect 
repellent-sunscreen drug products (FDA Call for Data or call for data). 
The call for data summarized the regulatory status and history of both 
sunscreens and insect repellents, and sought public input on a number 
of issues (see table 6). On that same date (February 22, 2007, 79 FR 
7979), EPA published a similar notice announcing that it was also 
seeking information to determine how insect repellent-sunscreen 
combination products should be regulated.

Table 6--Key Issues and Information Requests in FDA's 2007 Call for Data
------------------------------------------------------------------------
                                        Key concerns and information
           General issue                          requests
------------------------------------------------------------------------
Possible manufacturing conflicts..  Requested information about whether
                                     there are known conflicts between
                                     FDA and EPA manufacturing
                                     requirements and, if so, how to
                                     resolve them.
                                    Asked how FDA should address EPA-
                                     registered insect repellents in
                                     finalizing the OTC sunscreen
                                     monograph; which requirements
                                     should FDA retain, revise, or
                                     eliminate?
                                    Inquired about manufacturer testing
                                     of sunscreen-insect repellent
                                     combination products and whether
                                     any problems were encountered.
Possible formulation conflicts....  Requested comments on the
                                     significance of published research
                                     suggesting a potential formulation
                                     conflict.

[[Page 6245]]

 
Possible labeling conflicts         Labeling differences noted:
 between OTC sunscreen monograph     FDA uses ``warning''; EPA
 and EPA registration requirements.  uses ``caution'' (and only uses the
Note: Since publication of the       word ``warning'' to indicate
 call for data, FDA has              toxicity levels).
 established additional labeling     Many differences in
 regulations for certain OTC         required warning/caution section
 sunscreen products marketed         headings.
 without approved applications.      Directions for sunscreen
 However, the labeling concerns      use call for liberal application
 expressed in the call for data      and frequent reapplication; EPA
 remain relevant..                   directions may limit where and how
                                     to apply product and restrict
                                     frequency of application.
                                    Asked whether different directions
                                     for use can be integrated without
                                     leading to improper application,
                                     overexposure to insect repellent,
                                     and/or underexposure to sunscreen.
                                    FDA requires the outside container
                                     or wrapper of the retail package or
                                     the immediate container label to
                                     list all active and inactive
                                     ingredients (see section
                                     502(e)(1)(A)(iii) of the FD&C Act;
                                     Sec.   201.66(c)). EPA requires
                                     listing of the percentage of each
                                     active ingredient, and the total
                                     percentage of all ``inert'' or
                                     ``other'' ingredients, in the
                                     pesticide. Inert ingredients are
                                     not required to be identified
                                     individually on the product except
                                     in certain cases (in which case all
                                     inert ingredients are listed).
                                     Asked whether there is a way to
                                     label combination sunscreen-insect
                                     repellent drug products in a way
                                     that satisfies both the
                                     requirements of the FD&C Act and
                                     the FIFRA, and whether ``inert''
                                     ingredients under the FIFRA are
                                     equivalent to ``inactive''
                                     ingredients under the FD&C Act.
Safety issues.....................  More safety data needed given
                                     published animal studies indicating
                                     increased absorption of DEET and
                                     various sunscreens active
                                     ingredients when the components are
                                     combined. Asked for more safety
                                     data on combined products.
                                    Requested data on whether increased
                                     absorption of a sunscreen
                                     ingredient occurs when combined
                                     with an insect repellent.
                                    Information needed about incidence
                                     of skin irritation from combination
                                     products.
Effectiveness issues..............  Requested information on:
                                        Possible effects of
                                        insect repellent on sunscreen
                                        SPF; possible decreased
                                        sunscreen efficacy or increased
                                        exposure to insect repellent
                                        without greater efficacy
                                        resulting from inconsistent
                                        reapplication intervals.
                                     Potential chemical or
                                     physical incompatibilities between
                                     particular sunscreens and insect
                                     repellents.
                                        Potential need to
                                        specify minimum SPF for these
                                        combinations.
                                        Any potential
                                        performance benefits of these
                                        combination products other than
                                        convenience.
                                        Possible adjustments to
                                        formulations to minimize
                                        application time disparities.
------------------------------------------------------------------------

2. FDA's Evaluation of Sunscreen-Insect Repellent Combination Products
    FDA has reviewed the comments submitted in response to FDA's and 
EPA's calls for data, as well as pertinent scientific literature and 
publicly available EPA regulatory documents. Based on that review, we 
have tentatively concluded that sunscreen-insect repellent combination 
products, as a class, are not GRASE (i.e., are Category II) and are 
misbranded because conflicting labeling requirements for their 
sunscreen and insect repellent components cannot be reconciled to 
create labeling that will sufficiently ensure safe and effective use of 
the sunscreen component, as well as adequate directions for use as a 
sunscreen, as required by section 502(f) of the FD&C Act. Also, if we 
did not have this labeling concern, we would still tentatively 
determine that available data regarding the safety and effectiveness of 
these products for their use as sunscreens are insufficient to classify 
these sunscreen products as GRASE for such use (i.e., Category III). 
Specifically, evidence suggests that interactions between some 
sunscreen active ingredients and insect repellents may decrease safety 
by increasing systemic absorption of one or both components, and 
potential synergistic effects on the efficacy of sunscreen active 
ingredients apparently have not been studied. Although the available 
data are limited and not conclusive, they give rise to questions about 
the safety and effectiveness of these products. Our reasons for these 
tentative conclusions are detailed in the discussion that follows.
    a. Public comments on the 2007 call for data. FDA received six 
submissions in response to the 2007 call for data. None of the comments 
included substantive data, although some cited published scientific and 
medical literature, which is addressed in the following section of this 
document. Five of the six comments were from manufacturers or a trade 
association. Industry comments generally favored retaining joint 
regulation between EPA and FDA (perhaps with enhanced coordination and 
information-sharing) and amending the stayed OTC sunscreen monograph to 
address sunscreen-insect repellent combinations. Several industry 
comments claimed there was an absence of conflicting requirements 
relating to manufacturing, formulation, and/or labeling. Others 
suggested approaches for minimizing labeling conflicts, such as 
permitting exemptions to FDA's Drug Facts labeling requirements to 
accommodate EPA-required information, or placing FDA- and EPA-required 
information in separate areas of the label. The remaining comment was 
submitted by a medical association that opposed continued marketing of 
sunscreen-insect repellent products, emphasizing concerns about 
children's exposure to DEET. Industry comments favoring the continued 
marketing of combination sunscreen-insect repellent drug products also 
contended that combining sunscreen and insect repellent ingredients in 
a single product is more convenient and cost-effective than using 
separate products. Two comments stated that properly formulated, 
tested, and labeled, combination products are better than the 
unpredictable effects that could arise when consumers use two different 
products. Regarding safety, one comment asserted various flaws in the 
studies cited in the call for data that questioned the safety of these 
combination products. (These studies are discussed in section 
IX.E.2.d.)
    In general, the comments that we received in response to the 2007 
call for data were not accompanied or corroborated by data. Although 
the comments did not identify further concerns relating to product 
manufacturing or formulation, they did not adequately address FDA's 
concerns about safety, effectiveness, and labeling of these products. 
FDA renews its request for data to support labeling and safety for 
sunscreens with insect repellent added.
    b. Pesticide-related information. Pesticides that are or have been 
used in combination products that also contain sunscreens include DEET, 
IR3535, and oil of citronella. In evaluating combination insect 
repellent-sunscreen products for the purposes of this rule, FDA defers 
to EPA's expertise and authority regarding insect repellent 
ingredients. We have not independently evaluated these pesticides, but 
instead have focused on potential sunscreen-insect repellent ingredient 
interactions and the feasibility of effectively labeling these 
combination products for their use as sunscreens.

[[Page 6246]]

    As of June 2017, DEET was by far the most commonly used insect 
repellent. According to the EPA Product list, the amount of DEET in 
combination sunscreen-insect repellent products ranged from 10 to 20 
percent. DEET product labels recommend that users avoid over-
application, use just enough repellent to cover exposed skin and/or 
clothing, and not apply to hands or near the eyes or mouth of young 
children (Ref. 190). DEET-containing products listed on the EPA website 
in 2017 had concentrations ranging from 5 percent to 98 percent and 
provided protection from mosquitos for 2 to 12 hours, with many 
products having protection times of 4 hours or more (Ref. 187). The 
American Academy of Pediatrics recommends that repellents should 
contain no more than 30 percent DEET when used on children, and that 
insect repellent should not be used on children younger than 2 months 
(Ref. 191).
    EPA classifies the acute toxicity of insect repellents and other 
pesticides into one of four toxicity categories (ranging from Category 
I, highly toxic, to Category IV, practically nontoxic) (see 40 FR 
156.62). DEET is classified in Category III based on EPA's review of 
available animal studies, indicating slight acute toxicity for acute 
oral, dermal, ocular, and inhalation tests in animals, and low acute 
toxicity for the human health risk assessment (Ref. 192). Although DEET 
is registered for use in humans of any age, adverse events related to 
DEET toxicity have been documented and these events primarily relate to 
the central nervous system. As summarized by Katz et al., DEET has been 
associated with seizures and other central nervous system symptoms, 
cardiovascular symptoms, and topical and allergic symptoms (Ref. 193). 
Most reported cases of adverse or lethal events involved overuse or 
otherwise incorrect use of the product (Ref. 193), and EPA concluded 
that available data were insufficient to identify DEET as the cause of 
the reported adverse events (Ref. 192). EPA is currently in the process 
of updating its registration of a number of older pesticides, including 
DEET, and is deferring decision on the regulatory status of combination 
DEET/sunscreen products as described in the EPA Call for Data.\49\ 
However, EPA has stated that DEET does not pose a significant health 
risk to the U.S. population.\50\
---------------------------------------------------------------------------

    \49\ DEET 2014 reregistration interim review final decision 
(EPA-HQ-OPP-2012-0162) (available at https://www3.epa.gov/pesticides/chem_search/reg_actions/reregistration/red_PC-080301_1-Apr-98.pdf (accessed April 17, 2018).
    \50\ Id. In June 2014, EPA issued an interim review of DEET and 
did not identify any specific new concerns. The proposed interim 
registration review decision became final on September 24, 2014. 
DEET 2014 reregistration interim review final decision (EPA-HQ-OPP-
2012-0162) (available at https://www.regulations.gov/document?D=EPA-HQ-OPP-2012-0162-0012 (accessed April 17, 2018).
---------------------------------------------------------------------------

    IR3535 is classified by EPA as a biopesticide because it is 
biochemically, functionally identical to beta-alanine, a naturally 
occurring substance that repels insects (Ref. 194). IR3535 is 
classified in Toxicity Category IV (practically nontoxic) for acute 
oral, dermal, and inhalation toxicity and Category III (slightly toxic) 
for eye irritation (Ref. 195). Overall, EPA has assessed IR3535 as not 
harmful when ingested, inhaled, or used on skin (Ref. 195). Eye 
irritation could occur if the chemical enters a person's eyes (Ref. 
195). IR3535 is used at concentrations of 7.5 percent to 20 percent in 
a popular line of sunscreen-insect repellent combination products (EPA 
Product List) (Ref. 187). Products containing IR3535 identified on 
EPA's website in summer 2017 had concentrations ranging from 7.5 
percent to approximately 20 percent and listed protection time against 
mosquitoes of 2 to 8 hours (EPA Product List) (Ref. 187).
    Oil of citronella is a plant-derived biochemical insect repellent 
(72 FR 7979 at 7981). Depending on its source, it may be categorized as 
``Ceylon'' type or ``Java'' type. It is currently listed by EPA as a 
minimum risk pesticide (registration generally not required if 
formulated only with EPA-permitted inert ingredients and not labeled as 
effective against disease-causing pests) (40 FR 152.25(f)). Oil of 
citronella is also an approved food additive for use as a flavoring 
agent in foods and beverages (Ref. 196). EPA has designated oil of 
citronella as Toxicity Category III (slightly toxic) for acute oral 
toxicity (Java type only), dermal toxicity, dermal irritation, and 
acute eye irritation (both types), and Category IV (practically 
nontoxic) for acute oral toxicity (Ceylon type) and acute inhalation 
(Ref. 197). The National Pesticide Information Center (NPIC) fact sheet 
on oil of citronella states that oil of citronella products should not 
be used on children less than 6 months old (Ref. 198).
    c. Disparities in required labeling of sunscreens and insect 
repellents. FDA and EPA regulate the format and content of the labeling 
of nonprescription sunscreen products and pesticides, respectively. FDA 
regulations on nonprescription sunscreen labeling include the general 
drug labeling regulations in subpart A of part 201; the ``Drug Facts'' 
format and other OTC drug labeling requirements in subpart B of part 
201; and the sunscreen-specific labeling requirements that apply to 
sunscreens marketed without an approved NDA, including those based on 
the current requirements for SPF and broad spectrum testing in Sec.  
201.327. The labeling of registered insect repellents is subject to EPA 
labeling requirements under FIFRA (40 CFR 156), as well as specific 
language specified in individual product registration documents. 
Although the FDA and EPA labeling requirements for nonprescription 
sunscreens and registered pesticides cover some of the same information 
(such as ingredient lists, net quantity statements, and warnings/
precautions), there is considerable variation in the language, format, 
and placement of common label elements between the two Agencies, while 
other elements do not overlap.
    Furthermore, both Agencies limit the degree to which a drug 
manufacturer or pesticide registrant may depart from the prescribed 
text, format, and/or location of required labeling elements. This is 
particularly true for the wording and format of ``drug facts'' 
information for OTC drugs (see Sec.  201.66). Similarly, EPA 
regulations state that although a registrant may choose to place non-
FIFRA-required information on a pesticide label, it may not replace, 
obscure, conflict with, or supersede the FIFRA-required text (Ref. 
199).
    The intended uses of sunscreens and insect repellents are quite 
different, as are the associated labeling requirements; in particular, 
the instructions for using the two types of products are different. 
Required labeling for OTC sunscreens marketed without approved NDAs 
calls for reapplication at least every 2 hours (see Sec.  201.327(e)(3) 
through (e)(4)). The duration of protection for insect repellents 
varies according to the active ingredient and strength. Based on 
information from the EPA product list, many insect repellent-sunscreen 
products provide protection against mosquitoes and/or ticks for more 
than 2 hours, and some provide protection for as many as 6 to 10 hours. 
EPA has stated that it is ``concerned about consumer use of products 
that contain sunscreens and DEET, since directions to reapply generally 
and frequently may promote greater use of DEET than needed for 
pesticidal efficacy and thus pose unnecessary exposure to DEET.\51\ The 
Centers for Disease Control and Prevention (CDC) advises consumers

[[Page 6247]]

that ``products that combine sunscreen and repellent are not 
recommended, because sunscreen may need to be reapplied more often and 
in larger amounts than needed for the repellent component to provide 
protection from biting insects.'' (Ref. 200). Similarly, the American 
Academy of Pediatrics advises consumers not to use products that 
combine DEET with sunscreen, in part because ``[t]hese products can 
overexpose your child to DEET because the sunscreen needs to be 
reapplied often'' (Ref. 201). Additionally, DEET is approved for use on 
children with no age restriction (Ref. 202), whereas FDA labeling 
states ``[bullet] children under 6 months of age, ask a doctor'' (see 
Sec.  201.327(e)(1)(iv)).
---------------------------------------------------------------------------

    \51\ DEET 2014 reregistration interim review final decision, 
supra note 49, v.
---------------------------------------------------------------------------

    The recommended manner of application also differs for sunscreens 
and insect repellents. For example, the directions on the label for all 
insect repellent products containing DEET say to apply just enough to 
cover exposed skin, and avoid over-application (Ref. 190), whereas the 
labeling of nonprescription sunscreens marketed without approved NDAs 
calls for liberal or generous application (see Sec.  
201.327(e)(1)(ii)). The EPA-mandated directions on the labels of DEET 
products also state, ``Do not apply near eyes and mouth; apply 
sparingly around ears; do not use under clothing'' (Ref. 190). Such 
statements are potentially troublesome from the standpoint of sun 
protection in light of surveillance data from Australia, which suggest 
that the incidence of certain skin cancers is more frequent on highly 
exposed areas of the body such as ears and the backs of hands (Refs. 
203 and 204). The CDC advises consumers who need protection from both 
sun and insects to apply sunscreen product first, followed by an insect 
repellent (Ref. 200).
    Additional disparities in the content and format of labeling 
elements for sunscreens and registered insect repellents include the 
following:
     EPA pesticide labeling includes required elements that 
generally must appear on the front panel of the label, such as the 
ingredient statement (40 CFR 156.10(g)(2)), specified signal word such 
as ``CAUTION'' (40 CFR 156.64), and child hazard warning (40 CFR 
156.66), which could crowd or detract from drug information required to 
appear on the principal display panel for drugs (see Sec.  201.60 
(``The principal display panel shall be large enough to accommodate all 
the mandatory label information required to be placed thereon by this 
part.'')). Other labeling elements that only EPA requires include 
registration numbers and manufacturing establishment numbers (40 CFR 
156.10(a)).
     FDA labeling for sunscreens uses the word ``warning'' (see 
Sec. Sec.  201.66(c)(5) and 201.327(d)), while the EPA requirements 
specify that pesticide products that, like DEET, IR3535, and oil of 
citronella, meet the criteria of Toxicity Category III or IV as the 
highest category by any route of exposure bear on the front panel 
either no signal word or only the signal word ``CAUTION'' (40 CFR 
156.64). In EPA labeling the word ``WARNING'' is used as a signal word 
only for toxicity category II, which is a higher toxicity category than 
that applicable to any insect repellent ingredients used in sunscreen-
insect repellent combination products (40 CFR 156.64(a)(2)).
     FDA labeling uses the term ``directions'' (see Sec. Sec.  
201.66(c)(6) and 201.327(e)), while EPA regulations use the term 
``directions for use'' (see 40 CFR 156.10(i)(2)).
     FDA calls for ingredients to be listed as ``active'' and 
``inactive'' (see Sec.  201.66(b) through (c)), while EPA labeling uses 
the term ``inert'' or ``other'' instead of ``inactive'' for all non-
pesticide ingredients (40 CFR 156.10(g)).
    Given the extent of the disparities discussed above, FDA 
tentatively concludes that attempting to merge the required labeling 
for monograph sunscreens and insect repellents in a way that would 
comply with both Agencies' requirements and permit adequate consumer 
understanding and proper use would be impracticable. In this regard, we 
specifically disagree with comments made in response to the 2007 FDA 
Call for Data suggesting that acceptable ``merged'' labeling could be 
crafted by varying the OTC sunscreen drug facts to include insect-
repellent-related information, and/or by providing EPA-required 
labeling outside the drug facts box. We are particularly concerned that 
consumers would be confused by the juxtaposition of two sets of 
different and, in some cases, contradictory information in the labeling 
about these products' dual intended uses. We are also concerned that 
the sheer amount of required information would result in crowded, 
difficult-to-read labels lacking in the clarity and prominence of 
important safety and use information that are both required by FDA 
regulations and vital to consumer comprehension. We solicit comment and 
data about how to reconcile the labeling of suncreens and insect 
repellents such that a combined product could meet FD&C Act 
requirements for OTC sunscreen drugs.
    d. FDA's review of published medical literature. The results of 
FDA's literature review raise potential safety concerns about products 
that combine sunscreen and insect repellent active ingredients. The 
available data suggest that the dermal penetration and systemic 
absorption of at least one combination of a sunscreen active ingredient 
and an insect repellent is increased when both are present.
    There have been some studies assessing the penetration of DEET and 
the effects of DEET combined with sunscreen (particularly the active 
ingredient oxybenzone) on dermal penetration. Ross et al. tested for 
synergistic effects between DEET and oxybenzone using an in vitro mouse 
skin diffusion model and showed substantial penetration of a 20 percent 
DEET standard in ethanol, while penetration of sunscreen active 
ingredients was not found (Ref. 205). Despite a lower DEET content (10 
percent), a commercially marketed sunscreen formulation had a 6-fold 
more rapid detection and a 3- to 4-fold greater penetration of DEET 
than the 20 percent standard. Other diffusion tests using pigskin or 
artificial membranes and various combinations of DEET and oxybenzone in 
different media suggested an enhancing effect on dermal penetration of 
both DEET and oxybenzone (Refs. 206 and 207). The same investigators 
obtained similar results in a later in vitro study using human skin 
(Ref. 207).
    Kasichayanula et al. assessed the dermal absorption of DEET and 
oxybenzone using an in vivo piglet model, in which samples were 
collected from plasma, urine, and under the skin. Their results 
indicated that the enhanced dermal penetration evidenced in the in 
vitro studies translated to increased systemic exposure to both 
oxybenzone and DEET (Refs. 208 and 209). Finally, a study by Yiin et 
al. suggests that enhanced systemic absorption would also occur in 
humans (Ref. 210). Yiin et al. used human urinary metabolites of DEET 
and oxybenzone to evaluate the mutual enhancing effect on absorption of 
these ingredients and concluded that their findings confirm that 
concurrent use of DEET-containing insect repellent and oxybenzone-
containing sunscreen results in the enhancement of dermal absorption of 
DEET when insect repellent (DEET) was applied first and then covered by 
sunscreen (Ref. 210). The study authors suggested that placing 
repellent spray on top of sunscreen lotion with no mixing seems to be 
the best approach to diminish DEET penetration through the skin.
    Although insect repellents and sunscreens are designed to exert 
their

[[Page 6248]]

protective effects on the surface of the skin, the studies described 
above suggest that combining a sunscreen and insect repellent in a 
single product may result in unintended systemic exposure to the 
sunscreen ingredient oxybenzone and the insect repellent ingredient 
DEET. We acknowledge the study limitations cited by comments to the FDA 
Call for Data, and that in vitro diffusion studies have their 
limitations in terms of reflecting clinical use. We also note that many 
of the studies tested formulated commercial products with multiple 
sunscreen ingredients and excipients for which details were not given, 
and it is unclear how this may have influenced the results. Although 
we, therefore, do not view these data as conclusory, we have determined 
that they raise a valid safety concern that warrants a tentative 
conclusion that, even if one could overcome the misbranding and 
associated safety and effectiveness concerns created by the 
inconsistent application directions for sunscreens and insect 
repellants, there would not be sufficient evidence to conclude that 
combination sunscreen and insect repellent products are GRASE for 
sunscreen use without further investigation.
    Regarding future investigations that could assist FDA in 
determining whether these products have sufficient evidence of safety 
to be GRASE for use as sunscreen, we are not aware of any data that 
define the extent of systemic exposure to either DEET or oxybenzone 
that would occur with maximal exposure to a sunscreen-insect repellent 
combination product. There also are few data from which to assess 
whether there would be a similar enhancement of skin penetration for 
other combinations of sunscreen and insect repellent active 
ingredients. Moreover, without adequate human absorption studies under 
maximal use conditions of particular sunscreen-insect repellent 
combinations (i.e., a MUsT, as discussed in section VII.B.4), it is 
difficult to evaluate potential risks associated with the use of such 
combination products. Because of the potential synergistic interaction 
between the sunscreen active ingredient and the insect repellent active 
ingredient, human absorption data for the individual components would 
not provide adequate data to estimate the level of systemic absorption. 
Likewise, in vitro data would not be able to provide a reliable 
estimate of the systemic exposure that would occur with such products' 
use.
    In terms of sunscreen active ingredient effectiveness, we have 
little data from which to determine whether the presence of an insect 
repellent would affect the determined SPF value of combination 
sunscreen-insect repellent products. Montemarano et al. reported a 
reduction in sunscreen efficacy because of concomitant use with insect 
repellent. However, in that study, the sunscreen and insect repellent 
ingredients were applied separately and were not part of a combination 
product (Ref. 211).
    With respect to efficacy, we recognize that the testing required by 
Sec.  201.327 (both the current regulation and the regulation if 
amended as proposed elsewhere in this proposed rule) to support labeled 
SPF levels and other efficacy claims that may be made for certain OTC 
sunscreen products could potentially mitigate concerns about the impact 
of insect repellent active ingredients on sunscreen effectiveness. 
However, we are not aware of any data evaluating the reliability of SPF 
testing for sunscreen formulations that contain insect repellent 
ingredients. There also is the possibility that increasing the amount 
of the sunscreen active ingredient to compensate for any loss in 
efficacy because of the presence of the insect repellent could result 
in unnecessarily high exposure to the sunscreen active ingredient. For 
these additional reasons, we tentatively conclude that even if other 
concerns could be overcome, there is not currently sufficient evidence 
to conclude that combination sunscreen-insect repellent products are 
GRASE for use as sunscreens. We solicit comment on the data needs 
identified above and tentative conclusions, including supporting data 
and analysis. We also solicit data and information to address these 
data needs.
3. Conclusion
    FDA tentatively concludes that the inherent disparity in labeling 
requirements that apply to sunscreens marketed under the OTC monograph 
and insect repellents prevent the creation of labeling that will 
sufficiently ensure safe and effective use of the sunscreen component 
of sunscreen-insect repellent combination products, particularly in 
connection with duration of action. We also conclude that these 
conflicting requirements prevent these products from having adequate 
directions for use as a sunscreen, and thus these products would be 
misbranded under section 502(f) of the FD&C Act. In addition, even if 
these issues could be overcome, existing safety concerns about 
potential enhanced systemic absorption resulting from combining 
individual sunscreen active ingredients and insect repellent 
ingredients would also need to be addressed by further studies on both 
combinations of individual sunscreen and insect repellent ingredients 
and final formulations.
    Existing data indicates there is a risk of systemic absorption of 
insect repellent and/or a sunscreen active ingredient when both are 
present. Additional data would be needed to identify any interactions 
between specific sunscreen active ingredients and insect repellents, in 
particular, to characterize any enhancement of skin penetration and/or 
systemic absorption if the resulting data presents safety or 
effectiveness concerns. As stated above, FDA would need adequate human 
absorption studies, such as a MUsT, as part of the clinical safety 
assessment (for more discussion on assessment of dermal absorption of 
sunscreen active ingredients using MUsT, see section VII.B.4). The 
effectiveness of sunscreen-insect repellent combination products is 
also a continuing concern. For all of those reasons, we tentatively 
determine that these products are not GRASE for nonprescription 
sunscreen use. We solicit comment on this tentative determination.

X. Proposed Actions To Effectuate Lifting of Stay and Harmonize 
Impacted Regulations

    In the 2011 L&E Final Rule, FDA explained that although we were not 
yet lifting the stay on the 1999 final monograph, the provisions set 
forth in the L&E Final Rule reflected the Agency's position on the 
appropriate testing and labeling of sunscreen products that were 
previously identified as falling within the Stayed 1999 Final Monograph 
(76 FR 35620 at 35621). We explained that Sec.  201.327 would therefore 
supersede the prior approach to labeling and effectiveness testing 
described in the never-effective provisions of part 352, subparts C and 
D.
    We are now proposing to lift the stay on the 1999 final monograph 
(21 CFR part 352) while making certain changes in its provisions. To 
fully effectuate this proposal, we are proposing several harmonizing 
revisions to part 352 and Sec.  201.327. These changes remove certain 
provisions from part 352 that were superseded by the 2011 L&E Final 
Rule and, where applicable, replace them with appropriate cross 
references to the applicable testing and labeling provisions in Sec.  
201.327, as we propose to amend these regulations in this document. We 
also have made minor revisions in parts 347, 352 and Sec.  201.327 to 
improve readability and to correct certain typographical errors and 
erroneous internal cross references.

[[Page 6249]]

    We are also proposing revisions to certain provisions describing 
requirements for products containing both sunscreen active ingredients 
and skin protectant active ingredients to avoid duplication between 
Sec.  201.327 and part 352 and to harmonize the requirements set forth 
in those provisions. As in the past, the proposed sunscreen monograph 
would include conditions under which a single product could include 
certain sunscreen active ingredients as well as certain ingredients 
determined to be GRASE for use in skin protectants under part 347 (see 
proposed Sec.  352.20(b), as well as current Sec.  347.20(e) (21 CFR 
347.20(e)). Current Sec.  201.327(h) allows for such products to 
combine certain labeling statements applicable to each ingredient in 
the product to eliminate duplicative words or phrases. The stayed 
provisions of part 352 contain similar allowances for products that 
contain both sunscreen and skin protectant active ingredients, but also 
outline more detailed requirements for presenting such a product's 
statement of identity, indications, warnings, and directions. We 
propose to relocate the labeling requirements for such products from 
Sec.  352.60 to Sec.  201.327(h), thereby consolidating labeling 
conditions for these products in one section of the regulations. We 
also propose to retain compliance with these labeling provisions as a 
monograph condition for sunscreen/skin protectant products under both 
parts 352 (the sunscreen monograph) and 347 (the skin protectant 
monograph) by incorporating cross references to Sec.  201.327(h) in 
Sec.  352.20(b)(4), and Sec.  352.60, and incorporating cross 
references to Sec. Sec.  352.20 and 352.60 in Sec. Sec.  347.20(e), and 
347.60.
    Additionally, we propose to consolidate under new Sec.  310.549 (21 
CFR 310.549) certain properties that render an OTC drug product offered 
for use as sunscreen a new drug for which an approved NDA is required 
prior to marketing. Section 310.545 (21 CFR 310.545) currently contains 
several such provisions addressing specific ingredients and efficacy 
claims. We propose to relocate these provisions from Sec.  310.545 to 
Sec.  310.549. In addition, in the interest of completeness, we are 
clarifying in Sec.  310.549 that labeling a product with claims that it 
decreases the risk of skin cancer or early skin aging caused by the sun 
if that product has an SPF of less than 15 when tested in accordance 
with Sec.  201.327(i) and/or does not pass the broad spectrum test in 
Sec.  201.327(j) renders the product a new drug.
    Finally, we propose to add to Sec.  310.549 new characteristics 
that would render a product a new drug. These characteristics include: 
(1) Containing the ingredients we propose to classify as categories II 
and III (see sections VIII.B-C); (2) being labeled, represented, or 
promoted for use as a combined sunscreen-insect repellant (see section 
IX.E); (3) failing to comply with provisions relating to maximum SPF 
values and broad spectrum requirements (see section IX.B); and (4) 
failing to conform to certain other sunscreen formulation and dosage 
form conditions (see sections IX.A and D).

XI. Comment Period

    We are providing a comment period of 90 days (see DATES). FDA will 
also consider requests to defer further rulemaking with respect to a 
specific sunscreen active ingredient to allow the submission of new 
safety and/or effectiveness data to the record if such requests are 
submitted to the docket within the initial 90-day comment period. FDA 
will review all data and information submitted to the record in 
conjunction with all timely and complete requests to extend. In 
assessing whether to extend the comment period to allow for additional 
time for studies to generate new data and information, FDA will 
consider the data already in the docket along with any information that 
is provided in any requests to extend. FDA will determine whether the 
sum of the data, if timely submitted, is likely to be adequate to 
provide all the data that are necessary to make a determination of 
general recognition of safety and effectiveness.

XII. Proposed Effective/Compliance Dates

    The proposed effective date of final regulations resulting from the 
proposals described in this rulemaking is November 26, 2019 (see FD&C 
Act section 586E). We recognize that industry will need time after 
publication of any final regulations to comply with their provisions. 
To allow for orderly implementation of final regulations and help 
assure continued product availability to consumers, we would not expect 
full compliance with such final regulations for units of sunscreen 
product initially introduced or initially delivered for introduction 
into interstate commerce, until 1 year after the effective date of the 
final rule. We also would not expect full compliance, even after that 
date, for units of product that were initially introduced or initially 
delivered for introduction into interstate commerce before that date, 
such as those remaining in retail outlets. Our current thinking on 
implementation is informed in part by our understanding there are no 
currently marketed sunscreen products that contain the active 
ingredients we propose here as Category II. We solicit comment on this 
proposed approach.

XIII. Preliminary Economic Analysis of Impacts

A. Introduction

    We have examined the impacts of the proposed rule under Executive 
Order 12866, Executive Order 13563, Executive Order 13771, the 
Regulatory Flexibility Act (5 U.S.C. 601-612), and the Unfunded 
Mandates Reform Act of 1995 (Pub. L. 104-4). Executive Orders 12866 and 
13563 direct us to assess all costs and benefits of available 
regulatory alternatives and, when regulation is necessary, to select 
regulatory approaches that maximize net benefits (including potential 
economic, environmental, public health and safety, and other 
advantages; distributive impacts; and equity). Executive Order 13771 
requires that the costs associated with significant new regulations 
``shall, to the extent permitted by law, be offset by the elimination 
of existing costs associated with at least two prior regulations.'' We 
believe that this proposed rule is a significant regulatory action as 
defined by Executive Order 12866.
    The Regulatory Flexibility Act requires us to analyze regulatory 
options that would minimize any significant impact of a rule on small 
entities. Because many sunscreen manufacturers are small entities and 
the one-time costs of the proposed rule represent a significant 
fraction of annual revenue to sunscreen manufacturers, we find that the 
proposed rule will have a significant economic impact on a substantial 
number of small entities.
    The Unfunded Mandates Reform Act of 1995 (section 202(a)) requires 
us to prepare a written statement, which includes an assessment of 
anticipated costs and benefits, before proposing ``any rule that 
includes any Federal mandate that may result in the expenditure by 
State, local, and tribal governments, in the aggregate, or by the 
private sector, of $100,000,000 or more (adjusted annually for 
inflation) in any one year.'' The current threshold after adjustment 
for inflation is $150 million, using the most current (2017) Implicit 
Price Deflator for the Gross Domestic Product. This proposed rule would 
result in an expenditure in any year that meets or exceeds this amount.

[[Page 6250]]

    We have developed a comprehensive preliminary regulatory impact 
analysis that assesses the impacts of the proposed rule. We present a 
summary of this analysis below.

B. Summary of Costs and Benefits

    If finalized, the proposed rule would update and make effective 
regulations to ensure the safety and effectiveness of sunscreen 
products marketed under the OTC drug monograph. The rule would update 
sunscreen product labeling standards, address the safety of sunscreen 
active ingredients, revise and clarify our expectations for testing and 
recordkeeping by entities that conduct sunscreen testing, and address 
other sunscreen safety or efficacy concerns, like combination 
sunscreen-insect repellents and alternative dosage forms.
    Consumers would benefit from less exposure to sunscreen products 
containing active ingredients about which safety questions remain, less 
exposure to sunscreen products labeled with potentially misleading sun 
protection information, increased consumption of products with better 
UVA protection, less exposure to flammable spray sunscreens, and less 
exposure to spray and powder sunscreen products posing inhalation 
risks. Consumers would also experience transaction cost savings. The 
costs of the rule to sunscreen manufacturers include administrative 
costs, costs to fill data gaps for active ingredients and powder dosage 
forms, product formulation testing costs, and costs to reformulate and 
relabel sunscreen products. Finally, testing entities would incur 
recordkeeping costs if they do not already maintain adequate records of 
testing equipment, methods, and observations in final formulation 
testing.
    Table 7 summarizes the costs and benefits of the proposed rule, if 
finalized. The annualized benefits of the proposed rule, if finalized, 
would range from $0.00 million to $3.72 million at a 7 percent discount 
rate and from $0.00 million to $3.62 million at a 3 percent discount 
rate. Our primary estimate of annualized benefits would equal $0.91 
million at a 7 percent discount rate and $0.88 million at a 3 percent 
discount rate. The annualized costs of the proposed rule, if finalized, 
would range from $15.57 million to $75.84 million at a 7 percent 
discount rate and from $12.40 million to $60.42 million at a 3 percent 
discount rate. Our primary estimate of annualized costs would be $47.55 
million at a 7 percent discount rate and $37.79 million at a 3 percent 
discount rate.\52\
---------------------------------------------------------------------------

    \52\ The primary estimate of the costs is not the average of the 
lower bound costs and the upper bound costs.

              Table 7--Summary of Benefits, Costs, and Distributional Effects of the Proposed Rule
----------------------------------------------------------------------------------------------------------------
                                                                             Units
                                                               ---------------------------------
           Category             Primary      Low        High                            Period        Notes
                                estimate   estimate   estimate     Year     Discount   covered
                                                                 dollars    rate (%)   (years)
----------------------------------------------------------------------------------------------------------------
Benefits:
    Annualized Monetized ($m/      $0.91      $0.00      $3.72       2017          7         20
     year).                         0.88       0.00       3.62       2017          3         20
    Annualized Quantified         201.79      98.16     286.26                                   Increased use
     (mil oz/year) \1\.                                                                           of products
                                                                                                  with improved
                                                                                                  UVA
                                                                                                  protection.
    Annualized Quantified          51.42      19.43      83.41                                   Less exposure
     (mil oz/year) \2\.                                                                           to sunscreens
                                                                                                  containing
                                                                                                  active
                                                                                                  ingredients
                                                                                                  about which
                                                                                                  safety
                                                                                                  questions
                                                                                                  remain.
    Annualized Quantified         161.04     159.88     162.20                                   Less exposure
     (mil oz/year) \3\.                                                                           to sunscreens
                                                                                                  with
                                                                                                  potentially
                                                                                                  misleading sun
                                                                                                  protection
                                                                                                  information.
    Annualized Quantified         386.44     384.86     388.02                                   Less exposure
     (mil oz/year) \4\.                                                                           to spray and
                                                                                                  powder
                                                                                                  sunscreens
                                                                                                  posing
                                                                                                  inhalation
                                                                                                  risks.
                              ------------------------------------------------------------------
    Qualitative..............   Quicker responses to adverse events, improved inspections, and
                                better protection of human subjects. Potential transaction cost
                                 savings related to changes in the effort required to choose a
                                                          sunscreen.
----------------------------------------------------------------------------------------------------------------
Costs:
    Annualized Monetized ($m/      47.55      15.57      75.84       2017          7         20
     year).                        37.79      12.40      60.42       2017          3         20
    Annualized Quantified....
                              ------------------------------------------------------------------
    Qualitative..............     Recordkeeping costs to testing entities that do not already
                                                  maintain adequate records.
----------------------------------------------------------------------------------------------------------------
Transfers:
    Federal Annualized
     Monetized ($m/year).
                              ----------------------------------------------------------------------------------

[[Page 6251]]

 
                               From:
                               To:
                              ------------------------------------------------------------------
    Other Annualized
     Monetized ($m/year).
                              ----------------------------------------------------------------------------------
                               From:
                               To:
                              ------------------------------------------------------------------
Effects:                       State, Local, or Tribal Government: None.
                               Small Business: Some small businesses could exit the sunscreen
                               market by discontinuing their products or going out of business.
                               Wages: None.
                               Growth: None.
----------------------------------------------------------------------------------------------------------------
\1\ Values represent the 2016 consumption of sunscreens that would provide improved UVA protection under the
  proposed rule.
\2\ Value represent the 2016 consumption of sunscreens that contain active ingredients about which safety
  questions remain.
\3\ Values represent the 2016 consumption of sunscreens with potentially misleading sun protection information.
\4\ Values represent the 2016 consumption of potentially inhalable spray sunscreens and powder sunscreens.

    Table 8 shows the Executive Order 13771 summary over an infinite 
time horizon. In this analysis we assume that the costs and cost 
savings of the rule would end after 20 years. We estimate that this 
rule generates $29.85 million in net annualized costs, discounted at 7 
percent, over a perpetual time horizon. Based on these costs, this 
proposed rule would be considered a regulatory action under E.O. 13771.

                                                            Table 8--E.O. 13771 Summary Table
                                              [In $ millions 2016 dollars, over an infinite time horizon) 1
--------------------------------------------------------------------------------------------------------------------------------------------------------
                                                              Primary       Lower bound     Upper bound       Primary       Lower bound     Upper bound
                                                           estimate (7%)       (7%)            (7%)        estimate (3%)       (3%)            (3%)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Present Value of Costs..................................         $456.33         $149.22         $730.46         $618.16         $201.53       $1,002.22
Present Value of Cost Savings...........................            0.00            0.00            0.00            0.00            0.00            0.00
Present Value of Net Costs..............................          456.33          149.22          730.46          618.16          201.53        1,002.22
Annualized Costs........................................           29.85            9.76           47.79           40.44           13.18           65.57
Annualized Cost Savings.................................            0.00            0.00            0.00            0.00            0.00            0.00
Annualized Net Costs....................................           29.85            9.76           47.79           40.44           13.18           65.57
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ We assume that the benefits and costs of the proposed rule would diminish after 20 years. Negative values denoted in parentheses.

    We have developed a comprehensive Economic Analysis of Impacts that 
assesses the impacts of the proposed rule. The full preliminary 
analysis of economic impacts is available in the docket for this 
proposed rule (Ref. 63) and at https://www.fda.gov/AboutFDA/ReportsManualsForms/Reports/EconomicAnalyses/default.htm.

XIV. Analysis of Environmental Impact

    We have determined under 21 CFR 25.31(c) that this action is of a 
type that does not individually or cumulatively have a significant 
effect on the human environment. Therefore, neither an environmental 
assessment nor an environmental impact statement is required.

XV. Paperwork Reduction Act of 1995

    This proposed rule contains information collection provisions that 
are subject to review by OMB under the Paperwork Reduction Act of 1995 
(PRA) (44 U.S.C. 3501-3520). A description of these provisions is given 
in the Description section of this document with an estimate of the 
annual reporting, recordkeeping, and third-party disclosure burden. 
Included in the estimate is the time for reviewing instructions, 
searching existing data sources, gathering and maintaining the data 
needed, and completing and reviewing each collection of information.
    FDA invites comments on these topics: (1) Whether the proposed 
collection of information is necessary for the proper performance of 
FDA's functions, including whether the information will have practical 
utility; (2) the accuracy of FDA's estimate of the burden of the 
proposed collection of information, including the validity of the 
methodology and assumptions used; (3) ways to enhance the quality, 
utility, and clarity of the information to be collected; and (4) ways 
to minimize the burden of the collection of information on respondents, 
including through the use of automated collection techniques, when 
appropriate, and other forms of information technology.
    Title: Sunscreen Drug Products for OTC Human Use.
    Description: The proposed rule would amend FDA's current sunscreen 
labeling regulation (Sec.  201.327) and sunscreen products monograph 
(part 352) regarding product labeling, testing, and recordkeeping 
requirements. We note that existing regulations (e.g., current Sec.  
201.327) already require SPF testing and labeling. The information 
collections associated with current testing, labeling, and 
recordkeeping requirements have previously been approved in accordance 
with the PRA under OMB control numbers 0910-0139, 0910-0717, and 0910-
0755. For more information about current regulations and their history, 
see the Background and Scope sections of the

[[Page 6252]]

proposed rule (sections III and IV, respectively). The proposed rule 
would also amend parts 310 and 347.
    While the proposed provisions are broadly consistent with current 
best practices for testing conducted in human subjects and are not 
expected to require significant changes by reputable and experienced 
testing establishments, the proposed rule clarifies and confirms the 
application of existing requirements to sunscreens and adds certain new 
requirements, particularly for labeling and recordkeeping. The purpose 
of these changes is to help ensure that sunscreen testing is conducted 
and documented in a way that verifiably provides for protection of 
human subjects and increases the reliability of the testing data that 
underlies sunscreen labeling, and to update the labeling requirements.
    Description of Respondents: Affected entities include: (1) 
``responsible persons,'' as defined in proposed Sec.  201.327(a); (2) 
entities to which the responsible person transfers its obligations as 
permitted under proposed Sec.  201.327(a)(1) (e.g., contract 
manufacturers, contract testing entities, contract research 
organizations); and (3) clinical investigators conducting the testing 
(the investigator(s) required to submit investigator statements and 
other materials to the responsible person).
    FDA estimates that up to 772 entities could meet the proposed 
definition of responsible person (equivalent to ``brands'' in the 
economic analysis found in section XIII, Preliminary Analysis of 
Economic Impacts). The estimate of 772 entities also includes nearly 
all entities to which a responsible person might transfer its 
obligations (``transferees''), such as contract manufacturers, contract 
repackagers, contract distributors. For example, a manufacturer may be 
a responsible person for one brand and a contract manufacturer for 
another. However, in addition to the 772 entities and potential 
transferees already described, we estimate that there are approximately 
10 U.S.-based contract testing entities used by multiple responsible 
persons to conduct sunscreen testing (e.g., contract laboratories and 
contract research organizations). These 10 potential transferees are 
not included in the 772 figure. Thus, for certain information 
collections, the estimated respondent number may be 782. We note that 
this estimate does not include non-U.S.-based contract testing 
entities.
    In addition to the 10 contract testing entities, FDA estimates that 
approximately 10 of the estimated 772 responsible persons conduct their 
own SPF or broad spectrum testing. Thus, we estimate that there are 
approximately 20 entities that conduct covered sunscreen testing; we 
estimate these entities have approximately 20 lead clinical 
investigators to whom certain information collection obligations (e.g., 
reporting) may apply.

A. Labeling for Sunscreen Products and Associated Clinical Testing

    The proposed rule includes third-party disclosure obligations for 
responsible persons. The provisions may also apply to entities to which 
the responsible persons transfer their responsibilities under section 
201.327(a)(1) (``transferees''), depending on the scope of transferred 
obligations. There are labeling-related information collections 
(requirements include certain information on product labels) and a 
related testing burden (requirements for certain clinical testing to 
determine and support labeling information).
1. Labeling-Related Information Collection and Burden
    Proposed Sec.  201.327(b) and Sec.  201.327(h)(1) amend certain 
labeling requirements applicable to the PDP. Among other things, 
proposed Sec.  201.327(b) sets forth labeling requirements for the 
statement of identity and SPF value claims discussed in this section. 
Proposed Sec.  201.327(h)(1) applies to the statement of identity for 
sunscreen products that also contain skin protectant active 
ingredients. Proposed Sec.  352.50 requires that the PDP labeling 
comply with the requirements of Sec.  201.327(b). The SPF value 
statements set forth in proposed Sec.  201.327(b) and referenced in 
proposed Sec.  352.50 are based on the results of the testing required 
in proposed Sec.  201.327(i) and proposed part 352 (Sec.  352.70).
    a. Statement of identity. Proposed Sec.  201.327(b)(1) requires 
that sunscreen drug products bear a statement of identity consisting of 
the name of each sunscreen active ingredient listed in alphabetical 
order, followed by ``Sunscreen'' and ``[Dosage form]'' (e.g., 
``Lotion'', ``Spray''). Proposed Sec.  352.52(a) requires the labeling 
to contain a statement of identity in accordance with Sec.  201.327(b).
    Proposed Sec.  201.327(h)(1) applies to sunscreen drug products 
that also contain skin protectant active ingredients; it requires that 
the product bear a statement of identity consisting of the name of all 
sunscreen and skin protectant active ingredients in alphabetical order, 
followed by ``Sunscreen/Skin Protectant'' and ``[Dosage form],'' 
presented in accordance with Sec.  201.327(b)(1)(ii). Proposed Sec.  
352.60(a) requires that the product bear a statement of identity as set 
forth in Sec.  201.327(h)(1). Proposed Sec.  352.20(b)(4) requires that 
the product must be labeled in accordance with Sec. Sec.  201.327(h) 
and 352.60. Proposed Sec.  347.60(a)(3) requires that the labeling of 
the product bear the statement of identity set forth in proposed Sec.  
352.60(a).
    We note that current regulations already include a requirement that 
OTC products bear a statement of identity (see Sec.  201.66). This 
proposed rule would set forth the specific requirements just described 
for sunscreen drug products and sunscreen drug products that also 
contain skin protectant active ingredients. We believe this analysis 
reflects the additional burden beyond current statement of identity 
requirements.
    b. SPF value. Proposed Sec.  201.327(b)(2) requires, among other 
things, that the labeling display certain statements regarding the 
product's SPF value; the statements must be supported by the testing 
required by proposed Sec.  201.327(i) and referenced in proposed Sec.  
352.70. As previously noted, certain SPF testing and labeling is 
already required under current regulations. This analysis reflects the 
estimated additional burden of the proposed changes to SPF testing and 
labeling requirements.
    c. Burden for proposed statement of identity and SPF value 
information collections. The estimated burden for the statement of 
identity and SPF value information collections just described is 
provided in table 11 (Estimated Annual Third-Party Disclosure Burden). 
For currently marketed OTC sunscreen products, FDA believes that 
responsible persons need only complete the testing (or reanalyze 
existing testing data) and relabel the product as required by the rule 
one time, and may then continue to utilize the resultant labeling going 
forward without additional burden. We estimate that 772 respondents 
would need to complete this relabeling and related testing (if not 
already done) or reanalysis of existing test results one time for up to 
4,078 total products. In addition, there may be new products introduced 
each year. We estimate that as many as 1,500 new OTC sunscreen product 
stock keeping units (SKUs) may be introduced each year by up to 772 
respondents. These new products must be tested and labeled with the SPF 
value and broad spectrum results determined in the tests. We estimate 
that the 1,500 new sunscreen SKUs represent 975 new formulations.

[[Page 6253]]

    Table 11, row 1 provides FDA's estimate that 772 respondents will 
need to create PDP labeling for currently marketed sunscreen 
formulations in accordance with the statement of identity and SPF value 
requirements of proposed Sec.  201.327(b)(1), (b)(2), and (h)(1). This 
would be a one-time burden, and FDA estimates 5.2824 responses per 
respondent for a total of 4,078 responses. FDA estimates a burden of 
0.5 hours per response. We estimate the total burden of this 
recordkeeping to be 2,039 hours.
    Table 11, row 2 provides FDA's estimate that up to 772 respondents 
will need to create PDP labeling for new formulations each year in 
accordance with the statement of identity and SPF value requirements of 
proposed Sec.  201.327(b)(1), (b)(2), and (h)(1). FDA estimates 1.943 
responses per respondent for a total of 1,500 responses. FDA estimates 
a burden of 0.5 hours per response. We estimate the total burden of 
this recordkeeping to be 750 hours.
    Table 11, row 3 provides FDA's estimate that 20 respondents will 
conduct SPF testing in accordance with Sec.  201.327(i) (to determine 
the SPF value required by Sec.  201.327(b)(2)) for currently marketed 
sunscreen formulations, if this has not already been done. This would 
be a one-time burden. The estimated number of respondents reflects 
FDA's assumption based on its knowledge of the existing market that, of 
the 772 responsible persons, approximately 10 will conduct their own 
final formulation testing under Sec.  201.327(i), while most will 
delegate the responsibility for conducting final formulation testing to 
the approximately 10 independent testing entities that FDA believes 
conduct most final formulation testing. FDA estimates 111 responses per 
respondent for a total of 2,220 responses. FDA estimates a burden of 24 
hours per response. We estimate the total burden to be 53,280 hours.
    Table 11, row 4 provides FDA's estimate that 20 respondents will 
conduct SPF testing in accordance with Sec.  201.327(i) (to determine 
the SPF value required by Sec.  201.327(b)(2)) for new sunscreen 
formulations. FDA estimates 48.75 responses per respondent for a total 
of 975 responses. FDA estimates a burden of 24 hours per response. We 
estimate the total burden to be 23,400 hours.
    Regarding proposed Sec.  352.70, because that section does not add 
any additional labeling or testing-related information collections not 
already addressed elsewhere (it incorporates the proposed SPF testing 
requirements as a condition of the part 352 monograph), there is no 
additional burden.
2. Clinical Testing-Related Information Collection and Burden
    Proposed Sec.  201.327(i) contains requirements for clinical 
testing of SPF values for inclusion on sunscreen product labeling. As 
previously noted, current regulations already require SPF testing. 
While FDA expects that SPF testing and some of the proposed 
recordkeeping is already being done, the proposed changes are intended 
to clarify existing requirements applicable to sunscreen drug products 
and set forth certain new requirements intended to improve the 
reliability of SPF testing and ensure the protection of human subjects. 
Proposed Sec.  352.70 references the Sec.  201.327(i) testing 
requirements and makes the referenced testing requirements part of the 
monograph conditions of use.
    Across disciplines, testing involving human subjects is ordinarily 
conducted under IRB oversight as a means of ensuring that adequate 
human subject protections are provided and to ensure the integrity of 
study design and execution. Thus, in this proposed regulation, FDA is 
proposing to apply certain human subject protection requirements to 
sunscreens, with the aim of having a framework similar to that used in 
the IND context, but tailored to sunscreen testing.
    Information collections related to proposed Sec.  201.327(i) are 
addressed in detail in the sections that follow. Regarding proposed 
Sec.  352.70, as in the previous section, because the proposed change 
does not add any additional labeling or testing-related information 
collections not already addressed elsewhere (it cross-references the 
proposed Sec.  201.327(i) testing requirements as a condition of the 
part 352 monograph), there is no additional burden.
    a. Investigator statements and notifications. Proposed Sec.  
201.327(i), among other things, requires responsible persons to obtain 
a signed investigator statement and an investigator CV, and to provide 
certain notifications (e.g., notification of adverse drug experiences). 
These may result in third-party disclosure or reporting requirements 
for responsible persons (and entities to which they have transferred 
relevant obligations) as well as for clinical investigators. As noted 
above, our experience leads us to believe that most responsible persons 
will transfer their obligations under Sec.  201.327(i) to the 
approximately 20 entities that currently conduct clinical SPF testing. 
This assumption is reflected in the estimates regarding the number of 
respondents below.
    b. Investigator statements, CVs, and related burden. Proposed Sec.  
201.327(i)(1)(i) requires responsible persons to, among other things, 
obtain a signed investigator statement from each investigator. Proposed 
Sec.  201.327(i)(1)(iv)(B) requires responsible persons to obtain a 
signed investigator statement and CV. In FDA's experience, 
investigators for SPF testing are most often employed by the testing 
entities, and we therefore believe this is a recordkeeping requirement 
rather than a third-party reporting requirement. We request comment on 
this assumption. As noted above, we estimate that responsible persons 
will typically delegate this obligation to the approximately 20 
entities conducting final formulation testing. We estimate that each 
testing entity employs one clinical investigator to run the SPF testing 
they conduct. One investigator may run multiple SPF tests, and so long 
as the responsible person (or testing entity) has the investigator 
statement and CV on file for each investigator, there need not be a 
separate copy for each investigation.
    Table 10, row 1 provides FDA's estimate that approximately 20 
respondents will need to obtain and keep a signed investigator 
statement and CV in accordance with Sec.  201.327(i)(1)(i) and 
(i)(1)(iv)(B). FDA estimates 2 responses per respondent (1 CV and 1 
investigator statement) for a total of 40 annual responses. FDA 
estimates a burden of 0.6 hours per response. We estimate the total 
burden of this recordkeeping to be 24 hours.
    c. Notifications and related burden. Proposed Sec.  
201.327(i)(1)(i) requires responsible persons to, among other things, 
ensure that FDA and all participating investigators are promptly 
informed of significant new adverse effects or risks with respect to 
the drug. Proposed Sec.  201.327(i)(1)(v) requires responsible persons 
to keep each participating investigator informed of new observations 
about the drug, particularly with respect to adverse effects and safe 
use. As mentioned above, like other obligations associated with testing 
under proposed Sec.  201.327(i), we anticipate that this obligation 
will be delegated in most instances to the approximately 20 entities 
that currently conduct SPF testing on behalf of responsible persons.
    Table 9, row 1 provides FDA's estimate that approximately 20 
respondents will need to inform FDA and participating investigators of 
significant new adverse effects or risks in accordance with Sec.  
201.327(i)(1)(i) and

[[Page 6254]]

of new safety and other observations in accordance with Sec.  
201.327(i)(1)(v). FDA estimates up to 40 responses per respondent for a 
total of up to 800 annual responses. FDA estimates a burden of 0.5 
hours per response. We estimate the total burden of this recordkeeping 
to be 400 hours.
    d. Informed consent, IRB review, and related burden. Proposed Sec.  
201.327(i)(1)(ii) requires responsible persons to obtain informed 
consent, as defined in part 50, before clinical final formulation 
testing and proposed Sec.  201.327(i)(1)(iii) requires that clinical 
testing under Sec.  201.327(i) be reviewed and approved by an IRB 
meeting the requirements of part 56. These two proposed provisions make 
clear that FDA's regulations governing informed consent (part 50) and 
IRB approval of research (part 56) apply to clinical final formulation 
testing conducted pursuant to Sec.  201.327(i).
    Regarding proposed Sec.  201.327(i)(1)(ii) and (iii), the 
information collections associated with FDA's regulations governing 
informed consent (part 50) and IRB approval of research (part 56) have 
previously been approved in accordance with the PRA under OMB control 
number 0910-0755. FDA does not expect that proposed Sec.  
201.327(i)(1)(ii) or (iii) would affect the number of recordkeepers, 
records, reports, or associated burdens included in the existing 
approval (0910-0755), but we invite stakeholders to comment if they 
have a different view.
    Proposed Sec.  201.327(i)(1)(vii) requires investigators to provide 
safety reports and a final study report to the responsible person. 
Although investigators are often employees of testing entities, we are 
basing our estimate on our assumption the respondents in this case are 
the investigators themselves because of the framing of the duty 
proposed by the regulation.
    Table 9, row 2 provides FDA's estimate that up to 20 respondents 
will need to provide safety reports in accordance with Sec.  
201.327(i)(1)(vii)(A). FDA estimates 24.4 responses per respondent for 
a total of 488 annual responses. FDA estimates a burden of 0.5 hours 
per response. We estimate the total burden of this recordkeeping to be 
244 hours.
    Table 9, row 3 provides FDA's estimate that up to 20 respondents 
will need to provide a final report in accordance with Sec.  
201.327(i)(1)(vii)(B). This will occur one time per study, with each of 
the 20 investigators conducting multiple studies per year. FDA 
estimates 48.75 responses per respondent for a total of 975 annual 
responses. FDA estimates a burden of 3 hours per response. We estimate 
the total burden of this recordkeeping to be 2,925 hours.
    Proposed Sec.  352.40(i)(1) references limitations on particle size 
for sunscreens in a spray dosage form. Proposed Sec.  352.40(i)(2) and 
(3) proposes limitations on flammability and drying time for spray 
sunscreen formulations. These proposed sections (Sec.  352.40(i)(1) 
through (3)) make the referenced limitations on flammability and 
particle size requirements part of the monograph conditions of use. 
Proposed Sec.  352.40(i)(5) states that applicable requirements for 
particle size, flammability, and drying time for spray sunscreens must 
be verified through batch and lot testing as part of CGMP compliance 
under part 211. Entities conducting testing required by these sections 
must also comply with associated recordkeeping requirements, including 
those set forth in parts 210 and 211.
    The recordkeeping associated with ensuring compliance with Sec.  
352.40(i)(5) (batch and lot testing to ensure compliance with particle 
size, flammability, and drying time limitations) is considered to be 
part of the manufacturers' CGMP requirements under parts 210 and 211 
(OMB control number 0910-0139). While FDA believes that sunscreen 
manufacturers are already included among the respondents counted for 
that collection, and that many of those manufacturers who have spray 
dosage products may already be conducting flammability and drying time 
testing (e.g., many are including flammability statements and 
information about drying time in current product labeling), the 
proposed inclusion of these requirements in the sunscreen regulations 
is new. The proposed rule specifies the particle size, flammability, 
and drying time limitations that would be required for sunscreens in 
spray dosage forms to be GRASE under the monograph. The proposed rule 
also specifies that compliance with these limitations must be verified 
through batch and lot testing. While this greater specificity as to 
required testing might have a marginal effect on the burden associated 
with recordkeeping for manufacturing facilities that are not already 
conducting such testing, FDA believes that the total change would be 
minimal in light of the total recordkeeping burden under parts 210 and 
211, which is estimated across thousands of manufacturers of a wide 
variety of drugs. We request comment on these assumptions. If FDA 
determines that the assumptions are incorrect, then, concurrent with 
publication of the final rule, FDA plans to amend its approved 
information collection 0910-0139, if necessary, to adjust the 
respective burden estimate(s) to account for any change. We request 
comment on the accuracy of our assumptions and the resulting burden 
estimate.

B. Regulatory Status of Testing Entities

    Proposed Sec.  201.327(k) clarifies the regulatory status of final 
formulation testing, including that final formulation testing conducted 
pursuant to Sec.  201.327 constitutes ``manufacture'' of a drug. As 
such, this testing must be conducted in an establishment registered in 
accordance with part 207 and section 510 of the FD&C Act, and entities 
conducting final formulation testing required by this section must 
comply with CGMP and associated recordkeeping requirements, including 
those set forth in Sec.  201.327(l) and in parts 210 and 211. As this 
provision is intended only to clarify an existing requirement, it does 
not create a new information collection.
    Entities covered by this provision are already included in the 
burden estimates for the information collections associated with 
registration and listing requirements. Recordkeeping obligations 
related to registration and listing under part 207 and section 510 of 
the FD&C Act are part of FDA's approved information collection for part 
207 (OMB control number 0910-0829). CGMP recordkeeping obligations are 
part of FDA's approved information collection for part 211 (OMB control 
number 0910-0139).

C. Generating and Maintaining Records of SPF and Broad Spectrum Testing

    FDA is proposing specific recordkeeping requirements for SPF and 
broad spectrum testing to enable FDA to better monitor responsible 
persons' compliance with the requirements of Sec.  201.327. 
Recordkeeping is essential for FDA to evaluate whether required testing 
of final formulations is being conducted properly (both as to human 
subject protection and as to study design) and to enable the Agency to 
investigate postmarketing product failures or adverse events. 
Appropriate recordkeeping also enables FDA to conduct better and more 
efficient inspections of entities conducting final formulation testing. 
The proposed recordkeeping requirements are in alignment with the 
records required for other types of manufacturing under CGMPs as set 
forth in parts 210 and 211.
    Failure to maintain adequate records of testing equipment, methods, 
and observations can raise broad questions

[[Page 6255]]

about the reliability of final formulation testing. In FDA's 
experience, there has been a lack of uniformity in testing entities' 
approaches to recordkeeping for final formulation testing, raising 
concerns about the Agency's ability to assess the reliability of the 
results of final formulation testing. The proposed regulation would 
address these concerns, clarify FDA's expectations, and align the 
regulation with current best practices.
    a. Potential transfer of obligations. Proposed Sec.  201.327(a)(1) 
permits a responsible person (defined in Sec.  201.327(a)) to transfer 
some or all of its obligations to another entity (a ``transferee''), 
except for obligations with respect to recordkeeping under Sec.  
201.327(l). We note that this could create some situations in which 
both the responsible person and the transferee would be required to 
comply with applicable recordkeeping requirements. The proposed 
provision would also require a written record of the transfer of 
obligations to be maintained by both parties to the transfer.
    Regarding the record of an obligation transfer, FDA believes that 
it is usual and customary business practice for a written record of a 
transfer of obligations to be maintained by both parties to the 
transfer. FDA does not believe this requirement would incur any 
additional recordkeeping burden and believes it would meet the 
exception at 5 CFR 1320.3(b)(2). Regarding the potential for some 
recordkeeping obligations to fall on both responsible persons and 
transferees, although proposed Sec.  201.327(a)(1) does not itself 
impose a specific requirement to generate records, it does create the 
potential for some recordkeeping obligations to fall on both 
responsible persons and transferees. In particular, if a responsible 
person has delegated all other responsibilities under Sec.  201.327(i) 
and (j), they would nonetheless need to maintain a copy of the records 
of final formulation testing required by Sec.  201.327(l)(2) and (3). 
We have included the burden associated with keeping this copy in our 
assumption that there are 782 respondents for recordkeeping obligations 
as described below (20 entities that conduct testing, 10 of whom are 
also responsible persons, plus 762 responsible persons that delegate 
their responsibility for conducting testing (e.g., to one of the 10 
independent testing entities that are not themselves responsible 
persons)). We invite comment on whether our estimates properly reflect 
the recordkeeping obligations.
    b. Maintenance records and related burden. Proposed Sec.  
201.327(l)(1) addresses maintenance records. The proposed rule 
clarifies that, as manufacturing, final formulation testing must comply 
with CGMPs, and, accordingly, records documenting proper maintenance of 
equipment used in final formulation testing must be generated and 
maintained by testing entities, consistent with existing obligations in 
part 211.
    Regarding proposed Sec.  201.327(l)(1), the existing maintenance 
record obligations are part of FDA's approved information collection 
for part 211 (OMB control number 0910-0139), and FDA believes that most 
of the respondents for this collection of information (the 
approximately 20 entities we believe are conducting final formulation 
testing) are already included among the recordkeepers counted for that 
collection. The proposed rule provides greater specificity regarding 
what information should be included in maintenance records maintained 
by facilities conducting final formulation testing. While this greater 
specificity might have a marginal effect on the burden associated with 
recordkeeping for these facilities, and the number of respondents for 
this requirement may need to be increased by 10 (to reflect contract 
testing entities that may not be currently registered as 
manufacturers), FDA believes that the total change would be minimal in 
light of the total recordkeeping burden under parts 210 and 211, which 
is estimated across thousands of manufacturers of a wide variety of 
drugs. We request comment on these assumptions. If FDA determines that 
the assumptions are incorrect, then, concurrent with publication of the 
final rule, FDA plans to amend its approved information collection 
under OMB control number 0910-0139 as necessary to adjust the 
respective burden estimate(s) in order to account for any change.
    c. SPF testing records and related burden. Proposed Sec.  
201.327(l)(2) addresses SPF testing records and requires that 
respondents keep records related to the identification of the entity 
conducting the testing, the formulation being tested, equipment used, 
investigators, SPF standards, specific subject and test result data, 
and records demonstrating compliance with Sec.  201.327(i)(1) governing 
the establishment of adequate clinical testing procedures and 
conditions. This is important because failure of testing entities to 
keep adequate records to support final formulation testing may leave 
FDA unable to verify the reliability of the results of SPF testing. 
Because one testing entity may conduct final formulation testing on 
behalf of multiple responsible persons, an error at one testing entity 
may affect data across multiple clinical SPF testing studies for 
multiple different final formulations that are ultimately sold under 
different labels.
    In particular, proposed Sec.  201.327(l)(2) requires that, in 
addition to any records required to be kept pursuant to parts 210 and 
211, records of SPF testing must include: (1) Identification of the 
testing entity; (2) the product identifier and expected SPF; (3) 
characterization of the SPF standard sunscreen required by proposed 
Sec.  201.327(i)(3) (lot number, manufacturing date, and results of 
high performance liquid chromatography (HPLC) SPF standard assay); (4) 
documentation linking any blinded samples with the product lot number 
and formulation tested; (5) specific testing records for each human 
subject (identification of the UV source used for testing and various 
specific test results and the individual(s) who determined the values); 
(6) the mean and standard deviation from SPFi values, standard error 
and determined SPF value derived as set forth in proposed Sec.  
201.327(i)(7); (7) records for water resistance testing of pool 
temperature, air temperature, and relative humidity as required by 
proposed Sec.  201.327(i)(8); and (8) records demonstrating compliance 
with proposed Sec.  201.327(i)(1) requirements for adequate clinical 
testing procedures and conditions (e.g., individual case histories and 
documentation of IRB review).
    Table 10, row 2 provides FDA's estimate that approximately 20 
respondents will need to generate SPF testing records in accordance 
with proposed Sec.  201.327(l)(2) for existing products that will be 
reformulated. FDA estimates 85.5 records per recordkeeper for a total 
of 1,710 records. This is a one-time burden. FDA estimates a burden of 
24 hours per recordkeeping. We estimate the total burden of this 
recordkeeping to be 41,040 hours.
    Table 10, row 3 provides FDA's estimate that up to 20 respondents 
will need to generate SPF testing records in accordance with proposed 
Sec.  201.327(l)(2) for new formulations. FDA estimates 48.75 records 
per recordkeeper for a total of 975 records. FDA estimates a burden of 
24 hours per recordkeeping. We estimate the total burden of this 
recordkeeping to be 23,400.
    Table 10, row 4 provides FDA's estimate that up to 782 respondents 
will need to keep SPF testing records in accordance with proposed Sec.  
201.327(l)(2) for existing products that will be reformulated. This is 
a one-time

[[Page 6256]]

burden. FDA estimates 2.1867 records per recordkeeper for a total of 
1,710 records. FDA estimates a burden of 0.33 hours per recordkeeping. 
We estimate the total burden of this recordkeeping to be 564.3 hours.
    Table 10, row 5 provides FDA's estimate that up to 782 respondents 
will need to keep SPF testing records in accordance with proposed Sec.  
201.327(l)(2) for new formulations. FDA estimates 1.2468 records per 
recordkeeper for a total of 975 records. FDA estimates a burden of 0.33 
hours per recordkeeping. We estimate the total burden of this 
recordkeeping to be 321.75 hours.
    With regard to the testing-related estimates, we note that the 
requirements for obtaining certain medical history information from 
test subjects are not considered collections of information because 
information collected from subjects of clinical testing does not 
constitute information under 5 CFR 1320.3(h)(5), and that the 
referenced informed consent and IRB requirements under parts 50 and 56 
are covered by existing approvals, as previously discussed.
    d. Broad spectrum testing records and related burden. Proposed 
Sec.  201.327(l)(3) addresses broad spectrum testing records. The 
proposed rule requires records related to the identification of the 
entity conducting the testing, the formulation being tested, equipment 
used, investigators, UV standards, sunscreen application, and specific 
test result data. This is important because failure of testing entities 
to keep adequate records to support broad spectrum testing may leave 
FDA unable to verify the reliability of testing results. Failure at one 
testing entity may affect data across multiple broad spectrum testing 
studies for multiple different final formulations that are ultimately 
sold under different labels.
    In particular, proposed Sec.  201.327(l)(3) requires that records 
of broad spectrum testing must include: (1) Identification of the 
testing entity; (2) records of sample information (product identifier 
and expected SPF, master key for blinded samples, sample number and 
identifier code, polymethylmethacrylate (PMMA) plate surface topography 
measurement, and sample holder orientation); (3) identification of each 
UV source used for sunscreen product pre-irradiation; (4) records of 
sunscreen product application (sample weights, equipment 
identification); (5) measurements required by proposed Sec.  
201.327(j)(4) to (6)); (6) records of critical wavelength and UVA1/UV 
ratio values; (7) for each sample: The identity of the individual(s) 
conducting specific testing steps; and (8) test dates for the broad 
spectrum test conducted pursuant to Sec.  201.327(j), and sample report 
forms and supporting data.
    Table 10, row 6 provides FDA's estimate that approximately 20 
respondents will need to generate broad spectrum testing records in 
accordance with proposed Sec.  201.327(l)(3) for existing products. As 
with records of SPF testing, this number of respondents reflects FDA's 
assumption that most responsible persons will delegate responsibility 
for conducting testing under Sec.  201.327(j) to the approximately 20 
testing entities. FDA estimates 203.9 records per recordkeeper for a 
total of 4,078 records. This is a one-time burden. FDA estimates a 
burden of 1.5 hours per recordkeeping. We estimate the total burden of 
this recordkeeping to be 6,117 hours.
    Table 10, row 7 provides FDA's estimate that up to 20 respondents 
will need to generate broad spectrum testing records in accordance with 
proposed Sec.  201.327(l)(3) for new formulations. FDA estimates 48.75 
records per recordkeeper for a total of 975 records. FDA estimates a 
burden of 1.5 hours per recordkeeping. We estimate the total burden of 
this recordkeeping to be 1,462.5 hours.
    Table 10, row 8 provides FDA's estimate that up to 782 respondents 
will need to keep broad spectrum testing records in accordance with 
proposed Sec.  201.327(l)(3) for existing products. This is a one-time 
burden. FDA estimates 5.215 records per recordkeeper for a total of 
4,078 records. FDA estimates a burden of 0.17 hours per recordkeeping. 
We estimate the total burden of this recordkeeping to be 693.3 hours.
    Table 10, row 9 provides FDA's estimate that up to 782 respondents 
will need to keep broad spectrum testing records in accordance with 
proposed Sec.  201.327(l)(3) for new formulations. FDA estimates 1.2468 
records per recordkeeper for a total of 975 records. FDA estimates a 
burden of 0.17 hours per recordkeeping. We estimate the total burden of 
this recordkeeping to be 165.75 hours.
    The recordkeeping burden is estimated as described in the tables at 
the end of the PRA discussion.
    With the exceptions noted above, we conclude that the other 
provisions of this rule are not subject to OMB review under the PRA.
    The proposed changes to part 310 do not include any collections of 
information subject to the PRA.
    The remaining sections of part 347 do not include any collections 
of information not already addressed in this analysis.
    Section 201.327 and the remaining sections of part 352 either do 
not contain an information collection subject to PRA, or contain 
specific labeling information, including directions and warnings, which 
are a ``public disclosure of information originally supplied by the 
Federal Government to the recipient for the purpose of disclosure to 
the public'' (5 CFR 1320.3(c)(2)) and, therefore, are not collections 
of information.
    FDA estimates the burden of this information collection as follows:

                                                     Table 9--Estimated Annual Reporting Burden \1\
--------------------------------------------------------------------------------------------------------------------------------------------------------
                                                                  Number of
         Activity and 21 CFR section              Number of     responses per   Total annual          Average burden per response           Total hours
                                                 respondents     respondent       responses
--------------------------------------------------------------------------------------------------------------------------------------------------------
Inform FDA and investigators of significant                20              40             800  0.5 (30 minutes).........................             400
 new adverse effects or risks (Sec.
 201.327(i)(1)(i)) and new safety and other
 observations (Sec.   201.327(i)(1)(v)).
Investigators provide safety reports in                    20            24.4             488  0.5 (30 minutes).........................             244
 accordance with Sec.   201.327(i)(1)(vii)(A).
Investigators provide a final report in                    20           48.75             975  3........................................           2,925
 accordance with Sec.   201.327(i)(1)(vii)(B)
 (one time per study).
                                              ----------------------------------------------------------------------------------------------------------
    Total....................................  ..............  ..............  ..............  .........................................           3,569
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ There are no capital costs or operating and maintenance costs associated with this collection of information.


[[Page 6257]]


                                                   Table 10--Estimated Annual Recordkeeping Burden \1\
--------------------------------------------------------------------------------------------------------------------------------------------------------
                                                                  Number of
         Activity and 21 CFR section              Number of      records per    Total annual        Average burden per recordkeeping        Total hours
                                                recordkeepers   recordkeeper       records
--------------------------------------------------------------------------------------------------------------------------------------------------------
Obtain and keep a signed investigator                      20               2              40  0.6 (36 minutes).........................              24
 statement and CV in accordance with Sec.
 201.327(i)(1)(i) and (iv)(B).
Generate SPF testing records for existing                  20            85.5           1,710  24.......................................          41,040
 products (Sec.   201.327(l)(2)) (one-time).
Generate SPF testing records for new                       20           48.75             975  24.......................................          23,400
 formulations (Sec.   201.327(l)(2)).
Keep SPF testing records for existing                     782          2.1867           1,710  0.33 (20 minutes)........................           564.3
 products (Sec.   201.327(l)(2)) (one-time).
Keep SPF testing records for new formulations             782          1.2468             975  0.33.....................................          321.75
 (Sec.   201.327(l)(2)).                                                                       (20 minutes).............................
Generate Broad Spectrum testing records for                20           203.9           4,078  1.5......................................           6,117
 existing products (Sec.   201.327(l)(3)).
Generate Broad Spectrum testing records for                20           48.75             975  1.5......................................         1,462.5
 new formulations (Sec.   201.327(l)(3).
Keep Broad Spectrum testing records for                   782           5.215           4,078  0.17 (10 minutes)........................           693.3
 existing products (Sec.   201.327(l)(3)).
Keep Broad Spectrum testing records for new               782          1.2468             975  0.17 (10 minutes)........................          165.75
 formulations (Sec.   201.327(l)(3)).
                                              ----------------------------------------------------------------------------------------------------------
    Total....................................  ..............  ..............  ..............  .........................................       773,788.6
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ There are no capital costs or operating or maintenance costs associated with this collection of information.


                                              Table 11--Estimated Annual Third-Party Disclosure Burden \1\
--------------------------------------------------------------------------------------------------------------------------------------------------------
                                                                  Number of
         Activity and 21 CFR section              Number of      disclosures    Total annual         Average burden per disclosure          Total hours
                                                 respondents   per respondent    disclosures
--------------------------------------------------------------------------------------------------------------------------------------------------------
Create PDP labeling in accordance with                    772          5.2824           4,078  0.5 (30 minutes).........................           2,039
 statement of identity and SPF value
 requirements (Sec.   201.327(b)(1), (b)(2)
 and (h)(1)) for currently marketed sunscreen
 formulations (one-time burden).
Create PDP labeling in accordance with                    772           1.943           1,500  0.5 (30 minutes).........................             750
 statement of identity and SPF value
 requirements (Sec.   201.327(b)(1), (b)(2),
 and (h)(1)) for new formulations.
Conduct SPF testing in accordance with Sec.                20             111           2,220  24.......................................          53,280
 201.327(i) to determine SPF value for
 currently marketed sunscreen formulations
 (if not already done) (one-time burden).
Conduct SPF testing in accordance with Sec.                20           48.75             975  24.......................................          23,400
 201.327(i) to determine SPF value for new
 sunscreen formulations.
                                              ----------------------------------------------------------------------------------------------------------
    Total....................................  ..............  ..............  ..............  .........................................          79,469
--------------------------------------------------------------------------------------------------------------------------------------------------------
\1\ There are no capital costs or operating or maintenance costs associated with this collection of information.

    In compliance with the PRA (44 U.S.C. 3407(d)), the Agency has 
submitted the information collection provisions of this proposed rule 
to OMB for review. These requirements will not be effective until FDA 
obtains OMB approval. FDA will publish a notice concerning OMB approval 
of these requirements in the Federal Register.

XVI. Federalism

    We have analyzed this proposed rule in accordance with the 
principles set forth in Executive Order 13132. Section 4(a) of the 
Executive order requires Agencies to ``construe . . . a Federal statute 
to preempt State law only where the statute contains an express 
preemption provision or there is some other clear evidence that the 
Congress intended preemption of State law, or where the exercise of 
State authority conflicts with the exercise of Federal authority under 
the Federal statute.'' The sole statutory provision giving preemptive 
effect to this proposed rule is section 751 of the FD&C Act (21 U.S.C. 
379r). We have complied with all of the applicable requirements under 
the Executive order and have determined that the preemptive effect of 
this proposed rule, if finalized, would be consistent with Executive 
Order 13132. Through publication of this proposed rule, we are 
providing notice and an opportunity for State and local officials to 
comment on this rulemaking.

XVII. Consultation and Coordination With Indian Tribal Governments

    We have analyzed this proposed rule in accordance with the 
principles set forth in Executive Order 13175. We have tentatively 
determined that the rule does not contain policies that would have a 
substantial direct effect on one or more Indian Tribes, on the 
relationship between the Federal Government and Indian Tribes, or on 
the distribution of power and responsibilities between the Federal

[[Page 6258]]

Government and Indian Tribes. The Agency solicits comments from tribal 
officials on any potential impact on Indian Tribes from this proposed 
action.

XVIII. References

    The following references marked with an asterisk (*) are on display 
at the Dockets Management Staff (see ADDRESSES) and are available for 
viewing by interested persons between 9 a.m. and 4 p.m., Monday through 
Friday; they also are available electronically at https://www.regulations.gov. References without asterisks are not on public 
display at https://www.regulations.gov because they have copyright 
restriction. Some may be available at the website address, if listed. 
References without asterisks are available for viewing only at the 
Dockets Management Staff. FDA has verified the website addresses, as of 
the date this document publishes in the Federal Register, but websites 
are subject to change over time.

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Double-Blind Study,'' Journal of the American Academy of 
Dermatology, vol. 64(1), pp. 37-48, 2011.
178. Faurschou, A. and H.C. Wulf, ``Synergistic Effect of Broad-
Spectrum Sunscreens and Antihistamines in the Control of Idiopathic 
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179. Fourtanier, A., D. Moyal, and S. Seite, ``Sunscreens Containing 
the Broad-Spectrum UVA Absorber, Mexoryl SX, Prevent the Cutaneous 
Detrimental Effects of UV Exposure: a Review of Clinical Study 
Results,'' Photodermatology, Photoimmunology & Photomedicine, vol. 
24(4), pp. 164-174, 2008.
* 180. Therapeutic Goods Administration, ``Australian Regulatory 
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Sunscreens (ARGS),'' TGA Publication, pp. 1-43, 2016.
* 181. European Commission, ``Commission Recommendation of 22 
September 2006 on the Efficacy of Sunscreen Products and the Claims 
Made Relating Thereto (2006/647/EC),'' Official Journal of the 
European Union, vol. 265, pp. 39-43, 2006 (available at https://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:32006H0647&from=EN), accessed March 27, 2018.
182. Stanfield, J.W., H. Ou-Yang, T. Chen, et al., ``Multi-
Laboratory Validation of Very High Sun Protection Factor Values,'' 
Photodermatology, Photoimmunology & Photomedicine, vol. 27(1), pp. 
30-34, 2011.
183. Xu, S., M. Kwa, A. Agarwal, et al. ``Sunscreen Product 
Performance and Other Determinants of Consumer Preferences,'' 
Journal of the American Medical Association Dermatology, vol. 52(8), 
pp. 920-927, 2016.
184. Chao, L.X., S.L. Sheu, B.Y. Kong, et al. ``Identifying Gaps in 
Consumer Knowledge About Sunscreen,'' Journal of the American 
Academy of Dermatology, vol. 77(6), pp. 1172-1173, 2017.
185. Kong, B.Y., S.L. Sheu, and R.V. Kundu, ``Assessment of Consumer 
Knowledge of New Sunscreen Labels,'' JAMA Dermatology, vol.151(9), 
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186. Coelho, S.G., Y. Zhou, H.F. Bushar, et al., ``Long-Lasting 
Pigmentation of Human Skin, A New Look at an Overlooked Response to 
UV,'' Pigment Cell and Melanoma Research, vol. 22(2), pp. 238-241, 
2009.
* 187. EPA, ``Find the Repellent That is Right for You,'' (available 
at https://www.epa.gov/insect-repellents/find-repellent-right-you), 
accessed March 27, 2018.
188. NPIC, ``Insect Repellent Locator,'' (available at https://pi.ace.orst.edu/repellents/), accessed March 27, 2018.
* 189. EPA, ``Active Ingredients Eligible for Minimum Risk Pesticide 
Products'' (Updated December 2015) (available at https://www.epa.gov/sites/production/files/2015-12/documents/minrisk-active-ingredients-tolerances-2015-12-15.pdf), accessed March 27, 2018.
* 190. EPA, ``Using Insect Repellents Safely and Effectively'' 
(available at https://www.epa.gov/insect-repellents/using-insect-repellents-safely-and-effectively), accessed March 27, 2018.
191. American Academy of Pediatrics, ``Choosing an Insect Repellent 
for Your Child'' (available at https://www.healthychildren.org/English/safety-prevention/at-play/Pages/Insect-Repellents.aspx), 
accessed March 27, 2018.
* 192. EPA, ``Reregistration Eligibility Decision (R.E.D.) Facts, 
DEET,'' April 1998 (available at https://www3.epa.gov/pesticides/chem_search/reg_actions/reregistration/fs_PC-080301_1-Apr-98.pdf), 
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193. Katz, T.M., J.H. Miller, and A. Hebert, ``Insect Repellents: 
Historical Perspectives and New Developments,'' Journal of the 
American Academy of Dermatology, vol. 58(5), pp. 865-871, 2008.
*194. EPA, ``3-[N-Butyl-N-acetyl]-Aminopropionic Acid, Ethyl Ester 
(113509) Technical Document'' (available at https://www3.epa.gov/pesticides/chem_search/reg_actions/registration/related_PC-113509_1-Feb-99.pdf), accessed March 27, 2018.
* 195. EPA, ``3-[N-Butyl-N-acetyl]-Aminopropionic Acid, Ethyl Ester 
(113509) Fact Sheet'' (available at https://www3.epa.gov/pesticides/chem_search/reg_actions/registration/fs_PC-113509_01-Jan-00.pdf), 
accessed March 27, 2018.
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* 197. EPA, ``Reregistration Eligibility Decision (R.E.D) Facts, Oil 
of Citronella,'' February 1997 (available at https://www3.epa.gov/pesticides/chem_search/reg_actions/reregistration/fs_PC-021901_1-Feb-97.pdf), accessed March 27, 2018.
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https://npic.orst.edu/factsheets/citronellagen.pdf), accessed March 
27, 2018.
* 199. EPA, Office of Pesticide Programs, Label Review Manual, 
``Chapter 3: General Labeling Requirements,'' revised March 2018 
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International Journal of Cancer, vol. 53, pp. 886-891, 1993.
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Interactions: Sunscreens Enhance DEET (N,N-Diethyl-M-Toluamide) 
Absorption,'' Drug Metabolism and Disposition, vol. 32, pp.783-785, 
2004.
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Sciences, vol. 882(1-2), pp. 271-277, 2005.
209. Kasichayanula S., J.D. House, T. Wang, et al., ``Percutaneous 
Characterization of the Insect Repellent DEET and the Sunscreen 
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Pharmacology, vol. 223(2), pp. 187-194, 2007.
210. Yinn, L.M., J.N. Tian, and C.C. Hung, ``Assessment of Dermal 
Absorption of DEET-Containing Insect Repellent and Oxybenzone-
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Environmental Science and Pollution Research International, vol. 22, 
pp. 2062-2070, 2015.
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Repellents and the Efficacy of Sunscreens,'' The Lancet, vol. 
349(9066), pp. 1670-1671, 1997.

List of Subjects

21 CFR Part 201

    Drugs, Incorporation by reference, Labeling, Reporting and 
recordkeeping requirements.

21 CFR Part 310

    Administrative practice and procedure, Drugs, Labeling, Medical 
devices, Reporting and recordkeeping requirements.

21 CFR Part 347

    Labeling, Over-the-counter drugs.

21 CFR Part 352

    Labeling, Over-the-counter drugs.

    Therefore, under the Federal Food, Drug, and Cosmetic Act and under 
authority delegated to the Commissioner of Food and Drugs, we propose 
that 21 CFR parts 201, 310, 347, and 352 be amended as follows:

PART 201--LABELING

0
1. The authority citation for part 201 continues to read as follows:


[[Page 6264]]


    Authority:  21 U.S.C. 321, 331, 351, 352, 353, 355, 358, 360, 
360b, 360gg-360ss, 371, 374, 379e; 42 U.S.C. 216, 241, 262, 264.

0
2. Revise Sec.  201.327 to read as follows:


Sec.  201.327  Over-the-counter sunscreen drug products; required 
labeling based on effectiveness testing.

    The following provisions apply to an over-the-counter (OTC) 
sunscreen drug product that is intended for application to the skin of 
humans for purposes of absorbing, reflecting, or scattering radiation 
in the ultraviolet (UV) range at wavelengths from 290 to 400 nanometers 
(nm), and that contains one or more of the following as an active 
ingredient: Avobenzone, cinoxate, dioxybenzone, ensulizole, homosalate, 
meradimate, octinoxate, octisalate, octocrylene, oxybenzone, padimate 
O, sulisobenzone, titanium dioxide, or zinc oxide, alone or in 
combination. The provisions do not apply to OTC sunscreen drug products 
marketed under approved new drug applications or abbreviated new drug 
applications. The failure of a product covered by this section to 
comply with any provision of this section, including the labeling of 
such a product with any effectiveness claim based on testing that fails 
to comply with any provision of this section, renders that product 
misbranded under section 502 of the Federal Food, Drug, and Cosmetic 
Act.
    (a) General obligations of responsible persons. As used in this 
section, a ``responsible person'' is the manufacturer, packer, or 
distributor whose name appears on the labeling of a product covered by 
this section. A responsible person must assure that final formulation 
testing conducted on its product(s) pursuant to paragraphs (i) and (j) 
of this section complies with all applicable provisions of this 
section.
    (1) Transfer of obligations. (i) A responsible person may transfer 
responsibility for any or all of its obligations set forth in this 
section to another entity (e.g., a contract research organization and/
or testing laboratory), except as set forth in paragraph (l) 
(recordkeeping) of this section. Any such transfer must be described in 
writing. If not all obligations are transferred, the writing is 
required to describe each of the obligations being assumed by the 
transferee. If all obligations are transferred, a general statement 
that all obligations have been transferred is acceptable. Any 
obligation not covered by the written description will be deemed not to 
have been transferred. A written record of the transfer of obligations 
must be maintained by both parties to the transfer for the time period 
set forth in paragraph (l) of this section.
    (ii) An entity that assumes any obligation(s) of a responsible 
person must comply with the provisions of this section applicable to 
the assumed obligation and will be subject to the same regulatory 
action as a responsible person for failure to comply with any 
obligation assumed under this section. Thus, all references to 
``responsible person'' in this section apply to another entity (e.g., a 
contract research organization or testing laboratory) to the extent 
that it assumes one or more obligations of a responsible person.
    (2) Personnel. A responsible person must select only investigators 
and other personnel qualified by appropriate training and/or experience 
to conduct final formulation testing pursuant to this section. 
Personnel engaged in testing under this section must have the 
education, training, and experience, or any combination thereof, to 
enable that person to adequately perform their assigned functions.
    (b) Principal display panel. The following labeling must be 
prominently placed on the principal display panel:
    (1) Statement of identity--(i) Placement. The principal display 
panel of an over-the-counter sunscreen drug product bears a statement 
of identity as one of its principal features. Except as set forth in 
paragraph (h) of this section, the statement of identity consists of 
the name of each sunscreen active ingredient in the product as 
identified in this section, listed in alphabetical order and followed 
by ``Sunscreen'' and ``[Dosage form]'' (e.g., ``Lotion'' ``Spray'').
    (ii) Prominence. The statement of identity must appear on the 
principal display panel in boldface type at least one-quarter as large 
as the size of the most prominent printed matter on the principal 
display panel, in lines generally parallel to the base on which the 
package rests as it is designed to be displayed and in direct 
conjunction with the most prominent display of the proprietary name or 
designation. The entire text of the statement of identity must appear 
in the same font style, size, and color with the same background color, 
and as continuous text with no intervening text or graphic, other than 
additional text provided in accordance with paragraph (h) of this 
section.
    (2) Effectiveness claim. For purposes of this section, the term 
``determined SPF value'' refers to the SPF value that equals the 
largest whole number less than SPF-(t*SE), determined for a sunscreen 
product in accordance with paragraph (i) of this section.
    (i) SPF Broad Spectrum Statement. For a product that has been shown 
to pass the broad spectrum test in paragraph (j) of this section, the 
labeling states ``Broad Spectrum SPF [insert the labeled SPF value 
associated with the range into which the determined SPF value falls, as 
set forth in the following table.]''

           Table 1 to Paragraph (b)(2)(i)--SPF Labeling Ranges
------------------------------------------------------------------------
      Range of determined SPF values        Associated labeled SPF value
------------------------------------------------------------------------
60-80.....................................  60+.
50-59.....................................  50.
40-49.....................................  40.
30-39.....................................  30.
25-29.....................................  25.
20-24.....................................  20.
15-19.....................................  15.
2-14......................................  Determined SPF Value.
------------------------------------------------------------------------

    (ii) SPF Statement. For a product that has not been shown to pass 
the broad spectrum test in paragraph (j) of this section, the labeling 
states ``SPF [insert labeled SPF value associated with the range into 
which the determined SPF value falls, as set forth in the table in 
paragraph (b)(2)(i) of this section]''.
    (iii) For a product with a determined SPF value of at least 2 but 
less than 15. The SPF statement is immediately followed by an asterisk 
(``*''), and the associated statement ``*See Skin Cancer/Skin Aging 
Alert'' appears in the bottom 30 percent of the principal display 
panel.
    (iv) Prominence of required statements. The SPF Broad Spectrum 
statement, SPF statement, and ``*See Skin Cancer/Skin Aging Alert'' 
statement, as applicable, must appear in boldface type at least one-
quarter as large as the most prominent printed matter on the principal 
display panel and in lines generally parallel to the base on which the 
package rests as it is designed to be displayed. The entire text of the 
Broad Spectrum SPF or SPF statement, as applicable, must appear in the 
same font style, size, and color with the same background color and 
must appear as continuous text with no intervening text or graphic. The 
entire text of the ``See Skin Cancer/Skin Aging Alert'' statement, as 
applicable, must appear in the same font style, size, and color with 
the same background color and must appear as continuous text with no 
intervening text or graphic.
    (3) Water resistance statements--(i) For products that provide 40 
minutes of water resistance according to the test in paragraph 
(i)(8)(i) of this section. The

[[Page 6265]]

labeling states ``Water Resistant (40 minutes).''
    (ii) For products that provide 80 minutes of water resistance 
according to the test in paragraph (i)(8)(ii) of this section. The 
labeling states ``Water Resistant (80 minutes).''
    (iii) Prominence of water resistance statement. For all products 
bearing a water resistance statement, the statement must appear in 
boldface type at least one-quarter as large as the most prominent 
printed matter on the principal display panel and in lines generally 
parallel to the base on which the package rests as it is designed to be 
displayed. The entire text of the water resistance statement must 
appear in the same font style, size, and color with the same background 
color, and as continuous text with no intervening text or graphic.
    (c) Indications. The labeling of the product states, under the 
heading ``Uses,'' the phrases listed in this paragraph, as appropriate. 
Other truthful and nonmisleading statements, describing only the uses 
that have been established and listed in this paragraph, may also be 
used, as provided in Sec.  330.1(c)(2) of this chapter, subject to the 
provisions of section 502 of the Federal Food, Drug, and Cosmetic Act 
relating to misbranding and the prohibition in section 301(d) of the 
Federal Food, Drug, and Cosmetic Act against the introduction or 
delivery for introduction into interstate commerce of unapproved new 
drugs in violation of section 505(a) of the Federal Food, Drug, and 
Cosmetic Act.
    (1) For all sunscreen products, the following indication statement 
must be included under the heading ``Uses'': ``[bullet] helps prevent 
sunburn''. See Sec.  201.66(b)(4) for definition of bullet.
    (2) For sunscreen products that have been shown to pass the broad 
spectrum test in paragraph (j) of this section and have a determined 
SPF value of 15 or higher, the labeling may include the following 
statement in addition to the indication in paragraph (c)(1) of this 
section: ``[bullet] if used as directed with other sun protection 
measures (see Directions [in bold italic font]), decreases the risk of 
skin cancer and early skin aging caused by the sun''.
    (3) Any labeling or promotional materials that suggest or imply 
that the use, alone, of any sunscreen reduces the risk of or prevents 
skin cancer or early skin aging will cause the product to be misbranded 
under section 502 of the Federal Food, Drug, and Cosmetic Act (21 
U.S.C. 352).
    (d) Warnings. The labeling of the product contains the following 
warnings under the heading ``Warnings''.
    (1) For all sunscreen products. (i) The labeling states ``Do not 
use [bullet] on damaged or broken skin.''
    (ii) The labeling states ``When using this product [bullet] keep 
out of eyes. Rinse with water to remove.''
    (iii) The labeling states ``Stop use and ask a doctor if [bullet] 
rash occurs.''
    (2) For sunscreen products that are broad spectrum with determined 
SPF values of at least 2 but less than 15 according to the SPF test in 
paragraph (i) of this section or that have not been shown to pass the 
broad spectrum test in paragraph (j) of this section. The first 
statement under the heading ``Warnings'' states ``Skin Cancer/Skin 
Aging Alert [in bold font]: Spending time in the sun increases your 
risk of skin cancer and early skin aging. This product has been shown 
only to help prevent sunburn, not [in bold font] skin cancer or early 
skin aging.''
    (3) For products in a spray dosage form that meet the definition of 
either the term ``flammable'' or the term ``combustible'' as defined in 
Sec.  352.3(g) or (h) of this chapter, as applicable, when tested in 
accordance with 16 CFR 1500.43a--(i) Labeling statement. The labeling 
states [bullet] ``Flammable'' or ``Combustible'' (as applicable) 
followed by a colon and the statement ``Keep away from fire or flame.''
    (ii) For products that have a drying time of less than 5 minutes. 
The labeling states [bullet] ``Wait 5 minutes after application before 
approaching a source of heat or flame, or before smoking.''
    (iii) For products that have a drying time of at least 5 minutes 
but less than 10 minutes. The labeling states [bullet] ``Wait 10 
minutes after application before approaching a source of heat or flame, 
or before smoking.''
    (e) Directions. The labeling of the product contains the following 
statements, as appropriate, under the heading ``Directions.'' More 
detailed directions applicable to a particular product formulation may 
also be included.
    (1) For all sunscreen products. (i) As an option, the labeling may 
state ``For sunscreen use:''.
    (ii) The labeling states ``[bullet] apply [select one of the 
following: `liberally' or `generously'] [and, as an option: `and 
evenly'] 15 minutes before sun exposure''.
    (iii) As an option, the labeling may state ``[bullet] apply to all 
skin exposed to the sun''.
    (iv) The labeling states ``[bullet] children under 6 months of age: 
Ask a doctor''.
    (2) For sunscreen products that have been shown to pass the broad 
spectrum test in paragraph (j) of this section and have a determined 
SPF value of 15 or higher. The labeling states ``[bullet] Sun 
Protection Measures. [in bold font] Spending time in the sun increases 
your risk of skin cancer and early skin aging. To decrease this risk, 
regularly use a sunscreen with a Broad Spectrum SPF value of 15 or 
higher and other sun protection measures including: [bullet] limit time 
in the sun, especially from 10 a.m.-2 p.m. [bullet] wear long-sleeved 
shirts, pants, hats, and sunglasses''.
    (3) For products that satisfy the water resistance test in 
paragraph (i)(8) of this section. The labeling states ``[bullet] 
reapply: [bullet] after [select one of the following determined by 
water resistance test: `40 minutes of' or `80 minutes of'] swimming or 
sweating [bullet] immediately after towel drying [bullet] at least 
every 2 hours''.
    (4) For products that do not satisfy the water resistance test in 
paragraph (i)(8) of this section. The labeling states ``[bullet] 
reapply at least every 2 hours [bullet] use a water resistant sunscreen 
if swimming or sweating''.
    (5) For sunscreen products in a spray dosage form. The labeling 
states ``[bullet] Hold container 4 to 6 inches from the skin to apply. 
[bullet] Do not spray directly into face. Spray on hands then apply to 
face. [bullet] Do not apply in windy conditions. [bullet] Use in a 
well-ventilated area and avoid inhalation''.
    (f) Other information. The labeling of the product contains the 
following statement under the heading ``Other information:'' ``[bullet] 
protect the product in this container from excessive heat and direct 
sun''.
    (g) False or misleading claims. There are claims that would be 
false and/or misleading on sunscreen products. These claims include but 
are not limited to the following: ``Sunblock,'' ``sweatproof,'' and 
``waterproof.'' These or similar claims will cause the product to be 
misbranded under section 502 of the Federal Food, Drug, and Cosmetic 
Act.
    (h) Labeling of products containing a combination of sunscreen and 
skin protectant active ingredients. Statements of identity, 
indications, warnings, and directions for use, respectively, applicable 
to each ingredient in the product may be combined to eliminate 
duplicative words or phrases so that the resulting information is clear 
and understandable. Labeling provisions in Sec.  347.50(e) of this 
chapter do not apply to these products.
    (1) Statement of identity. The statement of identity of a sunscreen 
product that also contains one or more skin protectant active 
ingredients, identified in Sec. Sec.  347.10(a), (d), (e), (g), h),

[[Page 6266]]

(i), (k), (l), (m), and (r) of this chapter, consists of the names of 
all sunscreen and skin protectant active ingredients in alphabetical 
order followed by ``Sunscreen/Skin Protectant'' and ``[Dosage form].'' 
The statement of identity must be prominently placed on the principal 
display panel and presented in accordance with paragraph (b)(1)(ii) of 
this section.
    (2) Indications. The labeling of the product states, under the 
heading ``Uses,'' any or all of the applicable indication(s) included 
in Sec.  347.50(b) of this chapter or in paragraph (c) of this section. 
Other truthful and nonmisleading statements, describing only the 
indications for use that have been established in Sec.  347.50(b) of 
this chapter or listed in paragraph (c) of this section, may also be 
used, as provided by Sec.  330.1(c)(2) of this chapter, subject to the 
provisions of section 502 of the Federal Food, Drug, and Cosmetic Act 
relating to misbranding and the prohibition in section 301(d) of the 
Federal Food, Drug, and Cosmetic Act against the introduction or 
delivery for introduction into interstate commerce of unapproved new 
drugs in violation of section 505(a) of the Federal Food, Drug, and 
Cosmetic Act.
    (3) Warnings. The labeling of the product states, under the heading 
``Warnings,'' the applicable warnings for sunscreens in paragraph (d) 
of this section and for skin protectants in Sec.  347.50(c) of this 
chapter.
    (4) Directions. The labeling of the product states, under the 
heading ``Directions,'' any or all of the applicable directions for 
sunscreens, as set forth in paragraph (e) of this section, and for skin 
protectants, as set forth in Sec. Sec.  347.50(d) and 347.60(d) of this 
chapter, unless otherwise stated in this paragraph. When the time 
intervals or age limitations for administration of the individual 
ingredients differ, the directions for the product may not contain any 
dosage that exceeds those established for any individual ingredient in 
the applicable OTC drug monograph(s), and may not provide for use by 
any age group lower than the highest minimum age limit established for 
any individual ingredient. When the directions for administration of 
the sunscreen and skin protectant differ in any other way, the 
directions for sunscreens in paragraph (e) of this section should be 
used.
    (i) Sun Protection Factor (SPF) testing--(1) Adequate clinical 
testing procedures and conditions--(i) General obligations of 
responsible persons for testing under this paragraph. Responsible 
persons must provide investigators and other personnel engaged in SPF 
testing with the information they need to conduct an investigation 
properly; must obtain a signed investigator statement from each 
investigator; must ensure proper monitoring of the investigation(s); 
must ensure that the investigation(s) is conducted in accordance with 
written general investigational plan(s) and protocol(s); must ensure 
compliance with paragraphs (i)(1)(ii) and (iii) of this section; and 
must ensure that FDA and all participating investigators are promptly 
informed of significant new adverse effects or risks with respect to 
the drug.
    (ii) Informed consent. Effective informed consent, as defined in 
part 50 of this chapter, must be obtained from all human subjects 
before initiating clinical final formulation testing under this 
paragraph (i).
    (iii) Institutional review board (IRB) approval. Clinical testing 
under this paragraph (i), must be reviewed and approved by an IRB 
meeting the requirements of FDA's regulations in part 56 of this 
chapter.
    (iv) Control of personnel--(A) General obligations. A responsible 
person is responsible for ensuring that investigators and other 
personnel conducting any testing under this paragraph (i), conduct all 
investigations in accordance with the signed investigator statement, 
the investigational plan, and applicable regulations. Responsible 
persons must ensure the implementation of adequate safeguards to 
protect the rights, safety, and welfare of subjects under he 
investigator's care. The responsible person must also ensure that 
investigators or other study personnel will promptly report to the IRB 
all changes in the clinical final formulation testing and all 
unanticipated problems involving risk to human subjects or others, and 
that investigators or other personnel will not make any changes in the 
clinical final formulation testing without IRB approval, except where 
necessary to eliminate apparent immediate hazards to human subjects.
    (B) Obtaining information from the investigator. Before permitting 
an investigator to begin participating in clinical final formulation 
testing under this paragraph (i), the responsible person must obtain 
the following:
    (1) Investigator statement. A signed investigator statement 
containing the name and address of the investigator and a commitment by 
the investigator that he or she--
    (i) Will conduct the testing in accordance with the relevant, 
current protocol(s) and will only make changes in a protocol after 
notifying the responsible person and the IRB, except when necessary to 
protect the safety, the rights, or welfare of subjects;
    (ii) Will comply with all requirements regarding the obligations of 
clinical investigators and all other pertinent requirements in this 
subpart;
    (iii) Will personally conduct or supervise the described 
investigation(s);
    (iv) Will inform any potential subjects that the drugs are being 
used for investigational purposes and will comply with the requirements 
relating to obtaining informed consent (part 50 of this chapter) and 
institutional review board review and approval (part 56 of this 
chapter);
    (v) Will report to the responsible person adverse experiences that 
occur during the investigation(s);
    (vi) Will ensure that all personnel assisting in the conduct of the 
testing are informed about their obligations in meeting the above 
commitments.
    (2) Curriculum vitae. A curriculum vitae or other statement of 
qualifications of the investigator showing the education, training, and 
experience that qualifies the investigator to conduct the final 
formulation testing pursuant to this paragraph (i).
    (v) Informing investigators. The responsible person must, as the 
overall investigation proceeds, keep each participating investigator 
informed of new observations discovered by or reported to the 
responsible person on the drug, particularly with respect to adverse 
effects and safe use.
    (vi) Review of ongoing investigations. (A) The responsible person 
must monitor the progress of all clinical testing being conducted on 
its final formulation pursuant to this paragraph (i).
    (B) A responsible person who discovers noncompliance by an 
investigator or other personnel with the signed agreement, the general 
investigational plan, or the requirements of this paragraph (i) or 
other applicable regulations (e.g., parts 50 and 56 of this chapter) 
must promptly either secure compliance or end the investigator's or 
other personnel's participation in testing conducted under this 
paragraph (i).
    (C) The responsible person must review and evaluate the evidence 
relating to the safety and effectiveness of the final formulation as it 
is obtained from the investigator.
    (vii) Investigator reports--(A) Safety reports. An investigator 
must immediately report to the responsible person any serious adverse 
event, whether or not considered related to the final formulation, 
including those listed in the protocol, and must include an

[[Page 6267]]

assessment of whether there is a reasonable possibility that the final 
formulation being tested caused the adverse event. The investigator 
must record nonserious adverse events and report them to the 
responsible person according to the timetable specified in the 
protocol.
    (B) Final report. An investigator must provide the responsible 
person with an adequate report shortly after completion of each 
investigation conducted by that investigator for the responsible person 
under this paragraph (i).
    (2) UV source (solar simulator)--(i) Emission spectrum. Filter a 
single port or multiport solar simulator so that it provides a 
continuous emission spectrum from 290 to 400 nanometers (nm) with a 
limit of 1,500 watts per square meter (W/m\2\) on total irradiance for 
all wavelengths between 250 and 1,400 nm.
    (A) The solar simulator must have the following percentage of 
erythema-effective radiation in each specified range of wavelengths:

  Table 2 to Paragraph (i)(2)(i)(A)--Solar Simulator Emission Spectrum
------------------------------------------------------------------------
                                                             Percent
                 Wavelength range (nm)                      erythemal
                                                         contribution 1
------------------------------------------------------------------------
<290..................................................              <0.1
290-300...............................................           1.0-8.0
290-310...............................................         49.0-65.0
290-320...............................................         85.0-90.0
290-330...............................................         91.5-95.5
290-340...............................................         94.0-97.0
290-400...............................................        99.9-100.0
------------------------------------------------------------------------
1 Calculation of erythema action spectrum described in paragraph
  (i)(2)(ii) of this section.

    (B) In addition, UVA II (320-340 nm) irradiance must equal or 
exceed 20 percent of the total UV (290-400 nm) irradiance. UVA I (340-
400 nm) irradiance must equal or exceed 60 percent of the total UV 
irradiance.
    (ii) Erythema action spectrum. (A) Calculate the erythema action 
spectrum weighting factor (Vi) at each wavelength [lgr]:

(1) Vi ([lgr]) = 1.0 (250 <[lgr] <=298 nm)
(2) Vi ([lgr]) = 10\0.094\ * (\298\ - [lgr]) (298 <[lgr] 
<=328 nm)
(3) Vi ([lgr]) = 10\0.015\ * (\140\ - [lgr]) (328 <[lgr] 
<=400 nm)

    (B) Calculate the erythema-effective UV dose (E) delivered by a 
solar simulator as follows:
[GRAPHIC] [TIFF OMITTED] TP26FE19.003

Where

Vi([lgr]) = erythema action spectrum weighting factor at 
each wavelength [lgr]
I([lgr]) = irradiance (Watts per square meter) at each wavelength 
[lgr]
t = exposure time (seconds)
Erythema-effective dose (E) is expressed as effective Joules per 
square meter (J/m\2\-eff).

    (C) The solar simulator radiation intensity must be determined 
using a handheld radiometer with a response weighted to match the 
spectrum in ISO 17166 CIE S 007/E entitled ``Erythemal reference action 
spectrum and standard erythema dose,'' dated 1999 (First edition, 1999-
12-15; corrected and reprinted 2000-11-15), which is incorporated by 
reference in accordance with 5 U.S.C. 552(a) and 1 CFR part 51. You may 
obtain a copy from the ISO Copyright Office, Case Postale 56, CH-1211, 
Geneva 20, Switzerland, telephone +41-22-749-01-11 or fax +41-22-74-09-
47. https://www.iso.org. You may inspect a copy at the Center for Drug 
Evaluation and Research, 10903 New Hampshire Ave., Bldg. 22, Silver 
Spring, MD 20993, call 301-796-2090, or at the National Archives and 
Records Administration (NARA). For information on the availability of 
this material at NARA, call 202-741-6030, or go to: https://www.archives.gov/federal-register/cfr/ibr-locations.html. The solar 
simulator output should be measured before and after each phototest or, 
at a minimum, at the beginning and end of each test day. This 
radiometer should be calibrated using side-by-side comparison with the 
spectroradiometer (using the weighting factors determined according to 
paragraph (i)(2)(ii)(A) of this section) at the time of the annual 
spectroradiometric measurement of the solar simulator as described in 
paragraph (i)(2)(iv) of this section.
    (iii) Operation. A solar simulator must have no significant time-
related fluctuations (within 20 percent) in radiation emissions after 
an appropriate warm-up time and demonstrate good beam uniformity 
(within 20 percent) in the exposure plane. The delivered dose to the UV 
exposure site must be within 10 percent of the expected dose.
    (iv) Periodic measurement. To ensure that the solar simulator 
delivers the appropriate spectrum of UV radiation, the emission 
spectrum of the solar simulator must be measured at least annually with 
an appropriate and accurately calibrated spectroradiometer system 
(results should be traceable to the National Institute for Standards 
and Technology). In addition, the solar simulator must be recalibrated 
if there is any change in the lamp bulb or the optical filtering 
components (i.e., filters, mirrors, lenses, collimating devices, or 
focusing devices). Daily solar simulator radiation intensity should be 
monitored with a broadband radiometer with a response weighted to match 
the erythema action spectrum in ISO 17166 CIE S 007/E entitled 
``Erythemal reference action spectrum and standard erythema dose,'' 
which is incorporated by reference in paragraph (i)(2)(ii)(C) of this 
section. If a lamp must be replaced due to failure or aging during a 
phototest, broadband device readings consistent with those obtained for 
the original calibrated lamp will suffice until measurements can be 
performed with the spectroradiometer at the earliest possible 
opportunity.
    (3) SPF standard--(i) Preparation. The SPF standard must be a 
formulation containing 7-percent padimate O and 3-percent oxybenzone.

Table 3 to Paragraph (i)(3)(i)--Composition of the Padimate O/Oxybenzone
                              SPF Standard
------------------------------------------------------------------------
                                                            Percent by
                       Ingredients                            weight
------------------------------------------------------------------------
Part A:
    Lanolin.............................................            4.50
    Cocoa butter........................................            2.00
    Glyceryl monostearate...............................            3.00
    Stearic acid........................................            2.00
    Padimate O..........................................            7.00
    Oxybenzone..........................................            3.00
Part B:
    Purified water USP..................................           71.60
    Sorbitol solution...................................            5.00
    Triethanolamine, 99 percent.........................            1.00
    Methylparaben.......................................            0.30
    Propylparaben.......................................            0.10
Part C:
    Benzyl alcohol......................................            0.50
Part D:
    Purified water USP..................................            QS 1
------------------------------------------------------------------------
\1\ Quantity sufficient to make 100 grams.

    (A) Step 1. Add the ingredients of Part A into a suitable stainless 
steel kettle equipped with a propeller agitator. Mix at 77 to 82 [deg]C 
until uniform.
    (B) Step 2. Add the water of Part B into a suitable stainless steel 
kettle equipped with a propeller agitator and begin mixing at 77 to 82 
[deg]C. Add the remaining ingredients of Part B and mix until uniform.
    (C) Step 3. Add the batch of Step 1 to the batch of Step 2 and mix 
at 77 to 82 [deg]C until smooth and uniform. Slowly cool the batch to 
49 to 54 [deg]C.
    (D) Step 4. Add the benzyl alcohol of Part C to the batch of Step 3 
at 49 to 54 [deg]C. Mix until uniform. Continue to cool batch to 35 to 
41 [deg]C.
    (E) Step 5. Add sufficient water of Part D to the batch of Step 4 
at 35 to 41 [deg]C to obtain 100 grams of SPF standard. Mix until 
uniform. Cool batch to 27 to 32 [deg]C.

[[Page 6268]]

    (ii) HPLC assay. Use the following high performance liquid 
chromatography (HPLC) procedure to verify the concentrations of 
padimate O and oxybenzone in the SPF standard:
    (A) Instrumentation--(1) Equilibrate a suitable liquid 
chromatograph to the following or equivalent conditions:

----------------------------------------------------------------------------------------------------------------
 
----------------------------------------------------------------------------------------------------------------
(i) Column..................................  C-18, 250 millimeters (mm) length, 4.6 mm inner diameter (5
                                               microns).
(ii) Mobile Phase...........................  85:15:0.5 methanol: water: acetic acid.
(iii) Flow Rate.............................  1.5 milliliters (mL) per minute.
(iv) Temperature............................  Ambient.
(v) Detector................................  UV spectrophotometer at 308 nanometers.
(vi) Attenuation............................  As needed.
----------------------------------------------------------------------------------------------------------------

    (2) Use HPLC grade reagents for mobile phase.
    (B) Preparation of the HPLC reference standard. (1) Weigh 0.5 gram 
(g) of oxybenzone USP reference standard into a 250-mL volumetric 
flask. Dissolve and dilute to volume with isopropanol. Mix well.
    (2) Weigh 0.5 g of padimate O USP reference standard into a 250-mL 
volumetric flask. Dissolve and dilute to volume with isopropanol. Mix 
well.
    (3) Pipet 3 mL of the oxybenzone solution and 7 mL of the padimate 
O solution into a 100-mL volumetric flask. Dilute to volume with 
isopropanol and mix well.
    (C) HPLC system suitability. (1) Make three replicate 10-microliter 
injections of the HPLC reference standard (described in paragraph 
(i)(3)(ii)(B) of this section). The relative standard deviation in peak 
areas should not be more than 2 percent for either oxybenzone or 
padimate O.
    (2) Calculate the resolution (R) between the oxybenzone and 
padimate O peaks from one chromatogram as follows:
[GRAPHIC] [TIFF OMITTED] TP26FE19.004

Where

to = retention time for oxybenzone
tp = retention time for padimate O
Wo = oxybenzone peak width at baseline
Wp = padimate O peak width at baseline
If the resolution (R) is less than 3, adjust the mobile phase or 
replace the column.

    (D) SPF standard assay. (1) The SPF standard is diluted to the same 
concentration as the HPLC reference standard according to the following 
steps:
    (i) Step 1. Weigh 1 g of the SPF standard (described in paragraph 
(i)(3)(i) of this section) into a 50-mL volumetric flask.
    (ii) Step 2. Add approximately 30 mL of isopropanol and heat with 
swirling until contents are evenly dispersed.
    (iii) Step 3. Cool to room temperature (15 to 30 [deg]C) and dilute 
to volume with isopropanol. Mix well.
    (iv) Step 4. Pipet 5.0 mL of the preparation into a 50-mL 
volumetric flask and dilute to volume with isopropanol. Mix well.
    (2)(i) Inject 10-microliter of diluted SPF standard from paragraph 
(i)(3)(ii)(D)(1) of this section and calculate the amount of oxybenzone 
and padimate O as follows:
[GRAPHIC] [TIFF OMITTED] TP26FE19.005

    (ii) The percent of oxybenzone and padimate O in the SPF standard 
must be between 95 and 105.
    (4) Test subjects--(i) Number of subjects. A test panel should 
include enough subjects to produce a minimum of 10 valid test results. 
A maximum of three subjects may be rejected from this panel based on 
paragraph (i)(6)(v) of this section.
    (ii) Medical history. (A) Obtain a medical history from each 
subject with emphasis on the effects of sunlight on the subject's skin. 
Determine that each subject is in good general health with skin type I, 
II, or III as follows:
    (1) Always burns easily; never tans (sensitive).
    (2) Always burns easily; tans minimally (sensitive).
    (3) Burns moderately; tans gradually (light brown) (normal).
    (4) Burns minimally; always tans well (moderate brown) (normal).
    (5) Rarely burns; tans profusely (dark brown) (insensitive).
    (6) Never burns; deeply pigmented (insensitive).
    (B) Skin type is based on first 30 to 45 minutes of sun exposure 
after a winter season of no sun exposure. Determine that each subject 
is not taking topical or systemic medication that is known to alter 
responses to UV radiation. Determine that each subject has no history 
of sensitivities to topical products and/or abnormal responses to 
sunlight, such as a phototoxic or photoallergic response.
    (iii) Physical examination. Conduct a physical examination to 
determine the presence of sunburn, suntan, scars, active dermal 
lesions, and uneven skin tones on the areas of the back to be tested. 
Adequate time must have passed following any previous UV exposure 
(e.g., participation in a prior SPF clinical study, tanning, etc.) so 
that the test subject has no preexisting skin pigmentation at the time 
of enrollment. A suitable source of low power UVA, such as a Woods 
lamp, is helpful in this process. If any of these conditions are 
present, the subject is not qualified to participate in the study. The 
presence of nevi, blemishes, or moles will be acceptable if, in the 
physician's judgment, they will neither compromise the study nor 
jeopardize a subject's safety. Subjects with dysplastic nevi should not 
be enrolled. Excess hair on the back is acceptable if the hair is 
clipped. Shaving is unacceptable because it may remove a significant 
portion of the stratum corneum and temporarily alter the skin's 
response to UV radiation.
    (iv) Informed consent. Obtain legally effective written informed 
consent from all test subjects as required by paragraph (i)(1)(ii) of 
this section.

[[Page 6269]]

    (5) Sunscreen application--(i) Test site. Test sites are locations 
on each subject's back, between the beltline and the shoulder blades 
(scapulae) and lateral to the midline, where skin responses to UV 
radiation are determined. Responses on unprotected skin (no test 
material applied) and protected skin (sunscreen test product(s) or SPF 
standard applied) are determined at separate unprotected and protected 
test sites, respectively. Test sites should be randomly located in a 
blinded manner. Each test site should be a minimum of 30 square 
centimeters and outlined with indelible ink.
    (ii) Test subsite. Test subsites are the locations to which UV 
radiation is administered within a test site. Administer UV doses to at 
least five test subsites within each test site. Test subsites must be 
at least 0.5 square centimeters (cm\2\) in area and must be separated 
from each other by at least 0.8 cm. Each test subsite must be outlined 
with indelible ink.
    (iii) Applying test materials. Apply the sunscreen test product and 
the SPF standard at 2 milligrams per square centimeter (mg/cm\2\) to 
their respective test sites. Use a finger cot compatible with the 
sunscreen to spread the product as evenly as possible.
    (iv) Waiting period. Wait at least 15 minutes after applying a 
sunscreen product before exposing the test sites to UV radiation as 
described in paragraph (i)(6) of this section. For water resistant 
sunscreen products, proceed with the water resistance testing procedure 
described in paragraph (i)(8) of this section after waiting at least 15 
minutes.
    (6) UV exposure and erythema reading--(i) Definition of minimal 
erythema dose (MED). The minimal erythema dose (MED) is the smallest UV 
dose (quantity of erythema-effective energy expressed as Joules per 
square meter) that produces perceptible redness of the skin (erythema) 
with clearly defined borders at 16 to 24 hours after UV exposure. The 
MED for unprotected skin (MEDu) is determined on a test site 
that does not have sunscreen applied. The MED for protected skin 
(MEDp) is determined on a test site that has sunscreen 
applied. An MEDp is determined for the SPF standard 
(ssMEDp). An MEDp is determined for the sunscreen 
test product (tpMEDp).
    (ii) UV exposure for initial MEDu. For each test 
subject, no more than 1 day before testing a product, determine the 
initial MEDu by administering a series of UV radiation doses 
expressed as J/m\2\-eff (as determined according to paragraph 
(i)(2)(ii)(B) of this section) to the test subsites within an 
unprotected test site using an accurately calibrated solar simulator. 
Select doses that are a geometric series represented by 1.25\n\ (i.e., 
each dose is 25 percent greater than the previous dose).
    (iii) UV exposure for final MEDu, 
ssMEDp, and tpMEDp. For 
each subject, determine the final MEDu, 
ssMEDp, and tpMEDp by 
administering a series of five UV doses to the appropriate test sites. 
The middle dose (X) in each of these dose series (i.e., the third dose) 
should equal the initial MEDu times the expected SPF. Note 
that the expected SPF equals 1 and 16.3 for the final MEDu 
and ssMEDp, respectively. The remaining UV doses in the 
series depend upon the expected SPF value of the sunscreen test 
product(s). For products with an expected SPF less than 8, administer 
UV doses that increase by 25 percent with each successive dose (i.e., 
0.64X, 0.80X, 1.00X, 1.25X, and 1.56X). For products with an expected 
SPF from 8 to 15, administer UV doses that increase by 20 percent with 
each successive dose (i.e., 0.69X, 0.83X, 1.00X, 1.20X, and 1.44X). For 
products with an expected SPF higher than 15, administer UV doses that 
increase by 15 percent with each successive dose (i.e., 0.76X, 0.87X, 
1.00X, 1.15X, and 1.32X).
    (iv) Evaluation of test subsites. In order that the study personnel 
who evaluates the test subsites is not biased, he/she should not be the 
same study personnel who applied the sunscreen product to the test site 
or administered the UV doses. After UV doses are administered, record 
all immediate responses. These may include an immediate darkening or 
tanning, typically grayish or purplish in color, which fades in 30 to 
60 minutes; an immediate reddening at the subsite, due to heating of 
the skin, which fades rapidly; and an immediate generalized heat 
response, spreading beyond the subsite, which fades in 30 to 60 
minutes. After the immediate responses are noted, each subject should 
shield the exposed area from further UV radiation until the MED is 
determined. Determine the final MEDu, 
ssMEDp, and tpMEDp 16 to 24 
hours after UV exposure. Evaluate the erythema responses of each test 
subsite using either tungsten or warm white fluorescent lighting that 
provides at least 450 lux of illumination at the test site. For the 
evaluation, the test subject should be in the same position as when the 
test site was irradiated.
    (v) Invalid test data. Reject test data for a test subject if 
erythema is not present on either the unprotected or protected test 
sites; or erythema is present at all subsites; or the responses are 
inconsistent with the series of UV doses administered; or the subject 
was noncompliant (e.g., the subject withdraws from the test due to 
illness or work conflicts or does not shield the exposed testing sites 
from further UV radiation until the MED is determined).
    (7) Determination of SPF. (i) Calculate an SPF value for each test 
subject (SPFi) as follows:
[GRAPHIC] [TIFF OMITTED] TP26FE19.006

    (ii) Calculate the mean
    [GRAPHIC] [TIFF OMITTED] TP26FE19.007
    

and the standard deviation(s) from the SPFi values. 
Calculate the standard error (SE), which equals s/[radic]n (where n 
equals the number of subjects who provided valid test results). Obtain 
the t value from Student's t distribution table corresponding to the 
upper 5-percent point with n - 1 degrees of freedom. Determine the SPF 
value that is equal to the largest whole number less than
[GRAPHIC] [TIFF OMITTED] TP26FE19.008


In order for the SPF determination of a test product to be considered 
valid, the SPF value of the SPF standard must fall within the standard 
deviation range of the expected SPF (i.e., 16.3  3.43).
    (8) Determination of water resistance. To support labeling claims 
of water resistance in accordance with paragraph (b) of this section, 
the following procedure must be performed in an indoor fresh water 
pool, whirlpool, and/or hot tub maintained at 23 to 32 [deg]C. Fresh 
water is clean drinking water that meets the standards in 40 CFR part 
141. The pool and air temperature and the relative humidity must be 
recorded.
    (i) Water resistance (40 minutes). Determine the SPF value after 40 
minutes of water immersion using the following procedure:
    (A) Step 1: Apply the sunscreen test product as described in 
paragraph (i)(5) of this section.
    (B) Step 2: Perform moderate activity in water for 20 minutes.
    (C) Step 3: Rest out of water for 15 minutes. Do not towel test 
site(s).
    (D) Step 4: Perform moderate activity in water for 20 minutes.
    (E) Step 5: Allow test sites to dry completely without toweling.
    (F) Step 6: Apply the SPF standard as described in paragraph (i)(5) 
of this section.
    (G) Step 7: Expose test sites to UV doses as described in paragraph 
(i)(6) of this section.
    (ii) Water resistance (80 minutes). Determine the SPF value after 
80 minutes of water immersion using the following procedure:

[[Page 6270]]

    (A) Step 1: Apply the sunscreen test product as described in 
paragraph (i)(5) of this section.
    (B) Step 2: Perform moderate activity in water for 20 minutes.
    (C) Step 3: Rest out of water for 15 minutes. Do not towel test 
site(s).
    (D) Step 4: Perform moderate activity in water for 20 minutes.
    (E) Step 5: Rest out of water for 15 minutes. Do not towel test 
site(s).
    (F) Step 6: Perform moderate activity in water for 20 minutes.
    (G) Step 7: Rest out of water for 15 minutes. Do not towel test 
site(s).
    (H) Step 8: Perform moderate activity in water for 20 minutes.
    (I) Step 9: Allow test sites to dry completely without toweling.
    (J) Step 10: Apply the SPF standard as described in paragraph 
(i)(5) of this section.
    (K) Step 11: Expose test sites to UV doses as described in 
paragraph (i)(6) of this section.
    (j) Broad spectrum testing--(1) UV Spectrometry--(i) Plate. Use 
optical-grade polymethylmethacrylate (PMMA) plates suitable for UV 
transmittance measurements. The plate should be roughened on one side 
to a three-dimensional surface topography measure (Sa) between 2 and 7 
micrometers and must have a rectangular application area of at least 16 
square centimeters (with no side shorter than 4 cm).
    (ii) Sample holder. The sample holder should hold the PMMA plate in 
a horizontal position to avoid flowing of the sunscreen product from 
one edge of the PMMA plate to the other. Mount the PMMA plate as close 
as possible to the input optics of the spectrometer to maximize capture 
of forward scattered radiation. The sample holder should be a thin, 
flat plate with a suitable aperture through which UV radiation can 
pass. Place the PMMA plate on the upper surface of the sample holder 
with the roughened side facing up.
    (iii) Light source. The light source must produce a continuous 
spectral distribution of UV radiation from 290 to 400 nanometers.
    (iv) Input optics. Unless the spectrometer is equipped with an 
integrating sphere, an ultraviolet radiation diffuser should be placed 
between the sample and the input optics of the spectrometer. The 
diffuser will be constructed from any UV radiation transparent material 
(e.g., Teflon or quartz). The diffuser ensures that the radiation 
received by the spectrometer is not collimated. Set the spectrometer 
input slits to provide a bandwidth that is less than or equal to 5 
nanometers.
    (v) Dynamic range of the spectrometer. The dynamic range of the 
spectrometer should be sufficient to measure transmittance accurately 
through a highly absorbing sunscreen product at all terrestrial solar 
UV wavelengths (290 to 400 nm).
    (2) Sunscreen product application to PMMA plate. The accuracy of 
the test depends upon the application of a precisely controlled amount 
of sunscreen product with a uniform distribution over the PMMA plate. 
The product is applied at 0.75 mg per square centimeter to the 
roughened side of the PMMA plate. The sunscreen product should be 
applied in a series of small amounts over the entire PMMA plate and 
then spread evenly using a gloved finger. Spreading should be done with 
a very light spreading action for approximately 30 seconds followed by 
spreading with greater pressure for approximately 30 seconds. The plate 
should then be allowed to equilibrate for 15 minutes in the dark before 
the pre-irradiation described in paragraph (j)(3) of this section.
    (3) Sunscreen product pre-irradiation. To account for lack of 
photostability, irradiate the PMMA plate with a solar simulator 
described paragraph (i)(2) of this section. The irradiation dose must 
be 4 MEDs which is equivalent to an erythemal effective dose of 800 J/
m\2\ (i.e., 800 J/m\2\-eff).
    (4) Calculation of mean transmittance values. (i) After pre-
irradiation, determine the mean transmittance values for each 
wavelength [lambda] over the full UV spectrum (290 to 400 nanometers). 
Measure the transmittance values at 1 nanometer intervals. Measurements 
of spectral irradiance transmitted for each wavelength [lambda] through 
control PMMA plates coated with 15 microliters of glycerin (no 
sunscreen product) must be obtained from at least five different 
locations on the PMMA plate [C1([lambda]), C2([lambda]), C3([lambda]), 
C4([lambda]), and C5([lambda])]. In addition, a minimum of five 
measurements of spectral irradiance transmitted for each wavelength 
[lambda] through the PMMA plate covered with the sunscreen product will 
be similarly obtained after pre-irradiation of the sunscreen product 
[P1([lambda]), P2([lambda]), P3([lambda]), P4([lambda]), and 
P5([lambda])].
    (ii) The mean transmittance for each wavelength is the ratio of the 
mean of the C([lambda]) values to the mean of the P([lambda]) values, 
as follows:
[GRAPHIC] [TIFF OMITTED] TP26FE19.009

Where

n >=5

    (5) Calculation of mean absorbance values. (i) Mean transmittance 
values,
[GRAPHIC] [TIFF OMITTED] TP26FE19.010

are converted into mean absorbance values,
[GRAPHIC] [TIFF OMITTED] TP26FE19.011

at each wavelength by taking the negative logarithm of the mean 
transmittance value as follows:
[GRAPHIC] [TIFF OMITTED] TP26FE19.012

    (ii) The calculation yields 111 monochromatic absorbance values in 
1 nanometer increments from 290 to 400 nanometers.
    (6) Number of plates. For each sunscreen product, determine mean 
absorbance values from at least three individual PMMA plates. Because 
paragraph (j)(4) of this section requires at least 5 measurements per 
plate, there must be a total of at least 15 measurements.
    (7) Calculation of the critical wavelength. The critical wavelength 
is identified as the wavelength at which the integral of the spectral 
absorbance curve reaches 90 percent of the integral over the UV 
spectrum from 290 to 400 nm. The following equation defines the 
critical wavelength:
[GRAPHIC] [TIFF OMITTED] TP26FE19.013

Where

[lambda]c = critical wavelength
A([lambda]) = mean absorbance at each wavelength
d[lambda] = wavelength interval between measurements

    (8) Calculation of the UVA I/UV ratio. The ratio of UVA I/UV is 
calculated as the area (per unit wavelength) under the UVA I portions 
of a plot of wavelength versus A([lambda]), divided by the area (per 
unit wavelength) under the total curve, as follows:
[GRAPHIC] [TIFF OMITTED] TP26FE19.014

Where

A([lambda]) = effective absorbance given as -log T([lambda])mean 
absorbance at each wavelength,
d([lambda]) = wavelength interval between measurements
B([lambda]) = any biological action spectrum factor
Because no appropriate biological action spectrum for UVA radiation 
damage has been universally accepted, no action spectrum is 
specified. The value of B([lambda]) is, therefore, equal to 1.0 for 
all wavelengths.

    (9) Determination of broad spectrum protection. A product that has 
both a mean critical wavelength of 370 nm or

[[Page 6271]]

greater, calculated in accordance with paragraph (j)(7) of this 
section, and a mean UVA I/UV ratio of 0.70 or greater, calculated in 
accordance with paragraph (j)(8) of this section, is determined to pass 
the broad spectrum test.
    (k) Regulatory status of final formulation testing and related 
requirements. Final formulation testing required under this section is 
considered a part of the manufacture of a sunscreen product. Therefore, 
final formulation testing required under this section must be performed 
in an establishment registered in accordance with part 207 of this 
chapter and section 510 of the Federal Food, Drug, and Cosmetic Act. 
Entities conducting final formulation testing required by this section 
must also comply with current good manufacturing practices (CGMPs) and 
associated recordkeeping requirements including those set forth in 
paragraph (l) of this section and in parts 210 and 211 of this chapter. 
Failure to comply with CGMPs or recordkeeping requirements will mean 
that any product labeled in reliance on that testing will be 
adulterated.
    (l) Recordkeeping. Records required to be kept under this section 
must be maintained for at least 1 year after the expiration date of all 
products labeled in reliance on that testing or, in the case of certain 
OTC drug products lacking expiration dating because they meet the 
criteria for exemption under Sec.  211.137 of this chapter, 3 years 
after distribution of the last lot of drug product bearing labeling 
that relies on the testing. Recordkeeping requirements under this 
section may not be transferred. Maintenance records required to be kept 
under (l)(1) must be kept by the testing entity. Records of final 
formulation testing as described in paragraphs (l)(2) and (3) of this 
section must be kept by the responsible person and any entity that is 
performing final formulation testing required by this section on behalf 
of a responsible person pursuant to a transfer of obligations.
    (1) Maintenance records. Entities performing final formulation 
testing are expected to maintain equipment in accordance with paragraph 
(k) of this section and, as applicable, parts 210 and 211 of this 
chapter. Maintenance records must be kept for all equipment used for 
final formulation testing under this section and must include:
    (i) Documentation that equipment has been maintained in accordance 
with established written specifications as required by paragraph (k) of 
this section and parts 210 and 211 of this chapter; and
    (ii) Documentation of characterization of UV sources including:
    (A) Record of emission spectrum, total irradiance, and percent of 
erythema-effective radiation contribution required by paragraph 
(i)(2)(i) of this section;
    (B) Record of each periodic measurement required by paragraph 
(i)(2)(iv) of this section for each solar simulator;
    (C) Record of each calibration, realignment, or change in 
components of each solar simulator, or any changes to the broadband 
radiometer (or UV meter/dose control system), required by paragraph 
(i)(2)(iv) of this section; and
    (D) Record of each solar simulator output measurement required by 
paragraph (i)(2)(ii)(C) of this section.
    (2) SPF testing records. In addition to any records required to be 
kept pursuant to parts 210 and 211 of this chapter, records of SPF 
testing performed pursuant to paragraph (i) of this section must 
include:
    (i) Identification of the entity that conducted the final 
formulation testing, including the name and address of the 
establishment(s) at which testing was carried out;
    (ii) The sunscreen test product identifier and characterization of 
the formulation being tested, including lot number, manufacture date, 
and expected SPF;
    (iii) Characterization of the SPF standard sunscreen required by 
paragraph (i)(3) of this section, including:
    (A) Lot number;
    (B) Manufacturing date; and
    (C) Results of HPLC SPF standard assay that verify compliance with 
the concentrations of padimate O and oxybenzone in the SPF standard.
    (iv) Documentation linking any blinded samples with the product 
identifier.
    (v) For each human subject, records of:
    (A) The identification of the UV source used for testing on that 
subject, including make, model, and serial number;
    (B) Initial and final individual MED for unprotected skin 
(MEDu), and the identity of the study personnel who 
determined that value;
    (C) Final MED for sunscreen test product protected skin 
(tpMEDp), and the identity of the study personnel 
who determined that value;
    (D) Final MED for SPF standard sunscreen protected skin 
(ssMEDp), and the identity of the study personnel 
who determined that value; and
    (E) Individual SPFi values, including all valid test 
data and invalid test data for the test product and for the SPF 
standard sunscreen, and the identity of the study personnel who 
determined that value.
    (vi) Records of the mean and standard deviation from 
SPFi values, standard error, and determined SPF value 
derived as set forth in paragraph (i)(7) of this section.
    (vii) Records for water resistance testing of pool temperature, air 
temperature, and relative humidity as required by paragraph (i)(8) of 
this section.
    (viii) Records demonstrating compliance with paragraph (i)(1) of 
this section governing the establishment of adequate clinical testing 
procedures and conditions, including, but not limited to:
    (A) Case histories. Responsible persons are required to prepare and 
maintain adequate and accurate case histories on each individual 
participant enrolled in SPF testing performed under paragraph (i) of 
this section. Case histories must record all observations and other 
data pertinent to the investigation. Case histories include the case 
report forms and supporting data (for example, signed and dated consent 
forms, medical records including progress notes of the physician, the 
individual's hospital chart(s), and the nurses' notes (if applicable)). 
The case history for each individual participant must document that 
informed consent was obtained pursuant to part 50 before each 
individual's participation in the study. Case histories as required by 
this section must include:
    (1) Protocol deviations or injuries, if any; and
    (2) Identification, by subject, of the study personnel who: 
Examined the potential study site areas, who weighed and applied the 
sunscreen, and who provided the UV irradiation.
    (B) IRB review. Documentation that clinical research conducted 
pursuant to paragraph (i) of this section was reviewed and approved by 
a registered IRB as required by paragraph (i)(1)(iii) of this section.
    (3) Broad spectrum testing records. Records of broad spectrum 
testing conducted pursuant to paragraph (j) of this section must 
include:
    (i) Identification of the entity that conducted the final 
formulation testing, including the name and address of the 
establishment(s) at which testing was carried out;
    (ii) Records of sample information, including:
    (A) A sunscreen test product identifier and expected SPF. If the 
samples used in testing under paragraph (j) of this section are 
blinded, then records must include a master key that enables samples to 
be re-identified. In all other cases, records must include a

[[Page 6272]]

master key that links samples used to a sunscreen test product 
identifier.
    (B) Sample number;
    (C) Identifier code;
    (D) Measurement of PMMA plate surface topography in micrometers; 
and
    (E) Sample holder orientation (vertical or horizontal).
    (iii) Identification of each UV source used for sunscreen product 
pre-irradiation, including make, model, and serial number.
    (iv) Records of sunscreen product application, including:
    (A) A record of all sample weights, including analytical balance; 
and
    (B) For all equipment used; make, model, and serial number;
    (v) For each sample, all measurements required by paragraphs (j)(4) 
to (6) of this section.
    (vi) For each sample, records of critical wavelength and the UVA I/
UV ratio values required by paragraphs (j)(7) and (8) of this section.
    (vii) For each sample: The identity of the study personnel who 
weighed and applied the sunscreen to the PMMA plates; the identity of 
the study personnel who provided the pre-irradiation; and the identity 
of the study personnel, or, if calculated by software, what software, 
calculated the mean transmittance, mean absorbance values, critical 
wavelength, and UVA I/UV.
    (viii) For each sample, the test dates for the broad spectrum test 
conducted pursuant to paragraph (j) of this section, and sample report 
forms and supporting data including, for example, spectral data, Excel 
files containing transmittance or absorbance values, or any notes from 
the lab investigator.
    (4) Food and Drug Administration (FDA) inspection of records--(i) 
Testing entity. Anentity performing final formulation testing under 
this section, including a responsible person or an entity that has been 
transferred any obligations of a responsible person under this section, 
must, upon request from any properly authorized officer or employee of 
FDA, at reasonable times, permit such officer or employee to have 
access to, and copy and verify any records or reports of testing 
pursuant to this section. The testing entity is not required to divulge 
subject names unless the records of particular individuals require a 
more detailed study of the cases, or unless there is reason to believe 
that the records do not represent actual case studies, or do not 
represent actual results obtained.
    (ii) Responsible persons. A responsible person must upon request 
from any properly authorized officer or employee of FDA, at reasonable 
times, permit such officer or employee to have access to and copy and 
verify any records and reports relating to final formulation testing 
conducted under this section. Upon written request by FDA, the 
responsible person must submit the records or reports (or copies of 
them) to FDA. The responsible person must discontinue from further 
participation in final formulation testing required by this section any 
investigator who has failed to maintain or make available records or 
reports of the investigation as required by this paragraph (l).

PART 310--NEW DRUGS

0
3. The authority citation for part 310 continues to read as follows:

    Authority: 21 U.S.C. 321, 331, 351, 352, 353, 355, 360b-360f, 
360j, 360hh-360ss, 361(a), 371, 374, 375, 379e, 379k-l; 42 U.S.C. 
216, 241, 242(a), 262.


Sec.  310.545   [Amended]

0
4. Amend Sec.  310.545 by removing and reserving paragraphs (a)(29) and 
(d)(31),and (40).
0
5. Add Sec.  310.549 to subpart E to read as follows:


Sec.  310.549  Drug products offered over-the-counter (OTC) for use as 
sunscreen.

    (a) Any drug product offered OTC for use as sunscreen and 
identified in any of paragraphs (b) through (i) of this section is not 
generally recognized as safe and effective and is regarded as a new 
drug within the meaning of section 201(p) of the Federal Food, Drug, 
and Cosmetic Act, for which an approved new drug application under 
section 505 of the Federal Food, Drug, and Cosmetic Act and part 314 of 
this chapter is required for marketing. In the absence of an approved 
new drug application, such product is also misbranded under section 502 
of the Federal Food, Drug, and Cosmetic Act. Products offered OTC for 
use as sunscreen include those represented, labeled, or promoted as 
sunscreen, or for use to help prevent sunburn, skin cancer, and/or skin 
aging caused by the sun, or with similar claims or representations. 
Clinical investigations designed to obtain evidence that any sunscreen 
drug product covered by this section is safe and effective for the 
purpose intended must comply with the requirements and procedures 
governing the use of investigational new drugs set forth in part 312 of 
this chapter.
    (b) A sunscreen drug product that contains any of the following 
ingredients:
    (1) Diethanolamine methoxycinnamate
    (2) Digalloyl trioleate
    (3) Ethyl 4-[bis(hydroxypropyl)] aminobenzoate
    (4) Glyceryl aminobenzoate
    (5) Lawsone with dihydroxyacetone
    (6) Red petrolatum
    (7) Trolamine salicylate
    (8) Aminobenzoic acid
    (9) Avobenzone
    (10) Cinoxate
    (11) Dioxybenzone
    (12) Ensulizole
    (13) Homosalate
    (14) Meradimate
    (15) Octinoxate
    (16) Octisalate
    (17) Octocrylene
    (18) Oxybenzone
    (19) Padimate O
    (20) Sulisobenzone
    (c) A sunscreen drug product that has a determined sun protection 
factor (SPF) value, as defined in Sec.  352.3(d) of this chapter, of at 
least 15 when tested in accordance with Sec.  201.327(i) of this 
chapter, but that has not been shown to pass the broad spectrum test in 
Sec.  201.327(j) of this chapter.
    (d) A sunscreen drug product that has a determined sun protection 
factor (SPF) value, as defined in Sec.  352.3(d) of this chapter, of 
less than 2 or greater than 80 when tested in accordance with Sec.  
201.327(i) of this chapter.
    (e) A sunscreen drug product that has a determined sun protection 
factor (SPF) value, as defined in Sec.  352.3(d) of this chapter, of 
less than 15 when tested in accordance with Sec.  201.327(i) of this 
chapter and/or that does not pass the broad spectrum test in Sec.  
201.327(j) of this chapter, and labeled with any of the following or 
similar claims:
    (1) Decreases the risk of skin cancer caused by the sun; or
    (2) Decreases the risk of early skin aging caused by the sun.
    (f) A sunscreen drug product labeled with any of the following or 
similar claims:
    (1) Instant protection or protection immediately upon application; 
or
    (2) Claims for ``all-day'' protection or extended wear claims 
citing a specific number of hours of protection that is inconsistent 
with the directions for application in Sec.  201.327 of this chapter.
    (g) A sunscreen drug product that is labeled, represented, or 
promoted for use as a combined sunscreen-insect repellant.
    (h) A sunscreen drug product that is in any dosage form other than 
the following: Oil, lotion, cream, gel, butter, paste, ointment, stick, 
or spray.
    (i) A sunscreen drug product in a spray dosage form that has any of 
the following properties:
    (1) The product meets the definition of the term ``extremely 
flammable'' as

[[Page 6273]]

defined at Sec.  352.3(f) of this chapter when tested in accordance 
with 16 CFR 1500.43a;
    (2) More than 10 percent of the particles dispensed from the 
consumer container are smaller than 10 micrometers;
    (3) Any of the particles dispensed from the consumer container are 
smaller than 5 micrometers; or
    (4) The product meets the definition of either the term 
``flammable'' or the term ``combustible'' as defined at Sec. Sec.  
352.3(g) or (h) of this chapter, as applicable, when tested in 
accordance with 16 CFR 1500.43a and has a measured drying time of 10 
minutes or more.

PART 347--SKIN PROTECTANT DRUG PRODUCTS FOR OVER-THE-COUNTER HUMAN 
USE

0
6. The authority citation for part 347 continues to read as follows:

    Authority:  21 U.S.C. 321, 351, 352, 353, 355, 360, 371.

0
7. Amend Sec.  347.20 by lifting the stay on paragraph (e) (previously 
paragraph (d), redesignated at 74 FR 9765, March 6, 2009) and revising 
paragraph (e) to read as follows:


Sec.  347.20  Permitted combinations of active ingredients.

* * * * *
    (e) Combinations of skin protectant and sunscreen active 
ingredients. Any one (two when required to be in combination) or more 
of the skin protectant active ingredients identified in Sec.  
347.10(a), (d), (e), (g), (h), (i), (k), (l), (m), and (r) of this 
chapter may be combined with any single sunscreen active ingredient 
identified in Sec.  352.10 of this chapter, or any permitted 
combination of these ingredients identified in Sec.  352.20 of this 
chapter, provided the product meets the conditions in Sec.  352.20(b) 
of this chapter and is labeled according to Sec. Sec.  347.60 and 
352.60 of this chapter.
0
8. Amend Sec.  347.60 by revising paragraphs (a), (b)(3), (c)(1), and 
(d)(1) to read as follows:


Sec.  347.60  Labeling of permitted combinations of active ingredients.

* * * * *
    (a) Statement of identity. (1) Except as set forth in paragraph 
(a)(3) of this section, for a combination drug product that has an 
established name, the labeling of the product states the established 
name of the combination drug product, followed by the statement of 
identity for each ingredient in the combination, as established in the 
statement of identity sections of the applicable OTC drug monographs.
    (2) Except as set forth in paragraph (a)(3) of this section, for a 
combination drug product that does not have an established name, the 
labeling of the product states the statement of identity for each 
ingredient in the combination, as established in the statement of 
identity sections of the applicable OTC drug monographs.
    (3) For a product containing a combination of skin protectant and 
sunscreen active ingredients, the labeling of the product bears the 
statement of identity set forth in Sec.  352.60(a) of this chapter.
    (b) * * *
    (3) Combinations of skin protectant and sunscreen active 
ingredients in Sec.  347.20(e). In addition to any or all of the 
indications for skin protectant drug products in Sec.  347.50(b)(2)(i) 
of this chapter, the required indications for sunscreen drug products 
in Sec.  352.60(b) of this chapter must be used and any or all of the 
additional indications for sunscreen drug products may be used.
    (c) * * *
    (1) For combinations containing a skin protectant and a sunscreen 
identified in Sec. Sec.  347.20(e) and 352.20(b). The warnings in Sec.  
352.60(c) of this chapter are used.
* * * * *
    (d) * * *
    (1) For combinations containing a skin protectant and a sunscreen 
identified in Sec. Sec.  347.20(e) and 352.20(b). The directions in 
Sec.  352.60(d) of this chapter are used.
* * * * *

PART 352--SUNSCREEN DRUG PRODUCTS FOR OVER-THE-COUNTER HUMAN USE

0
9. The authority citation for part 352 continues to read as follows:

    Authority:  21 U.S.C. 321, 351, 352, 353, 355, 360, 371.

0
10. Lift the stay of 21 CFR part 352.


Sec.  352.1   [Amended]

0
11. In paragraph (a), remove the words ``in a form suitable for topical 
administration''.
0
12. Revise Sec.  352.3 to read as follows:


Sec.  352.3  Definitions.

    As used in this part:
    (a) [Reserved]
    (b) [Reserved]
    (c) Sunscreen active ingredient. An active ingredient listed in 
Sec.  352.10 that absorbs, reflects, or scatters radiation in the 
ultraviolet (UV) range at wavelengths from 290 to 400 nanometers.
    (d) Determined sun protection factor (SPF) value. The SPF value 
that equals the largest whole number less than SPF - (t * SE), 
determined for a sunscreen product in accordance with Sec.  201.327(i) 
of this chapter.
    (e) Labeled sun protection factor (SPF) value. The SPF value 
associated with the range into which the determined SPF value falls, as 
set forth in the table in Sec.  201.327(b)(2)(i) of this chapter.
    (f) Extremely flammable. The term ``extremely flammable'' applies 
to any product that has a flashpoint at or below 20 [deg]F (-6.7 
[deg]C) as determined by the test method described at 16 CFR 1500.43a, 
except that any product having one component or more with a flashpoint 
higher than 20 [deg]F (-6.7 [deg]C) that comprises at least 99 percent 
of the total volume of the product is not considered to be extremely 
flammable.
    (g) Flammable. The term ``flammable'' applies to any product that 
has a flashpoint above 20 [deg]F (-6.7 [deg]C) and below 100 [deg]F 
(37.8 [deg]C) as determined by the test method described at 16 CFR 
1500.43a, except that:
    (1) Any product having one component or more with a flashpoint at 
or above 100 [deg]F (37.8 [deg]C) that comprises at least 99 percent of 
the total volume of the product is not considered to be flammable; and
    (2) Any product containing 24 percent or less of water miscible 
alcohols, by volume, in aqueous solution is not considered to be 
flammable if the product does not present a significant flammability 
hazard when used by consumers.
    (h) Combustible. The term ``combustible'' applies to any product 
having a flashpoint at or above 100 [deg]F (37.8 [deg]C) to and 
including 150 [deg]F (65.6 [deg]C) as determined by the test method 
described at 16 CFR 1500.43a, except that:
    (1) Any product having one component or more with a flashpoint 
higher than 150 [deg]F (65.6 [deg]C) that comprises at least 99 percent 
of the total volume of the product is not considered to be combustible; 
and
    (2) Any product containing 24 percent or less of water miscible 
alcohols, by volume, in aqueous solution is not considered to be 
combustible if the product does not present a significant flammability 
hazard when used by consumers.
0
13. Add Sec.  352.5 to subpart A to read as follows:


Sec.  352.5  Sun protection factor related conditions.

    (a) The product has a determined SPF value of at least 2 but no 
greater than 80.
    (b) If the product has a determined SPF value of at least 15, it 
also passes

[[Page 6274]]

the broad spectrum test in Sec.  201.327(j) of this chapter.
0
14. Revise Sec.  352.10 to read as follows:


Sec.  352.10  Sunscreen active ingredients.

    The active ingredient of the product consists of any of the 
following, under the conditions specified, including being within the 
concentration specified for each ingredient:
    (a) through (o) [Reserved]
    (p) Titanium dioxide up to 25 percent
    (q) [Reserved]
    (r) Zinc oxide up to 25 percent.
0
15. Revise Sec.  352.20 to read as follows:


Sec.  352.20  Permitted combinations of active ingredients.

    The determined SPF of any product containing a sunscreen active 
ingredient is measured by the testing procedures established in Sec.  
201.327(i) of this chapter.
    (a) Combinations of sunscreen active ingredients. Two or more 
sunscreen active ingredients identified in Sec.  352.10 may be combined 
with each other in a single sunscreen product if all of the following 
conditions are met:
    (1) Each sunscreen active ingredient in the product must satisfy 
the conditions established for its use in Sec.  352.10.
    (2) The concentration of each sunscreen active ingredient must be 
sufficient to contribute a minimum determined SPF of not less than 2 to 
the finished product.
    (3) The finished product must have a minimum determined SPF of not 
less than the number of sunscreen active ingredients used in the 
product multiplied by 2.
    (b) Combinations of sunscreen and skin protectant active 
ingredients. Any single sunscreen active ingredient identified in Sec.  
352.10 or any combination of sunscreen active ingredients permitted 
under paragraph (a) of this section may be combined with one or more 
skin protectant active ingredients identified in Sec. Sec.  347.10(a), 
(d), (e), (g), (h), (i), (k), (l), (m), and (r) of this chapter when 
all of the following conditions are met:
    (1) Each sunscreen active ingredient in the product must satisfy 
the conditions established for its use in Sec.  352.10.
    (2) The concentration of each sunscreen active ingredient must be 
sufficient to contribute a minimum determined SPF of not less than 2 to 
the finished product.
    (3) The finished product must have a minimum determined SPF of not 
less than the number of sunscreen active ingredients used in the 
product multiplied by 2.
    (4) The product must be labeled according to Sec.  201.327(h) of 
this chapter and Sec.  352.60.
    (c) [Reserved]
0
16. Add Sec.  352.30 to subpart B to read as follows:


Sec.  352.30   Route of administration.

    The product is intended for topical administration.
0
17. Add Sec.  352.40 to subpart B to read as follows:


Sec.  352.40  Dosage forms.

    The product is in one of the following dosage forms and meets any 
additional conditions specified:
    (a) Oil.
    (b) Lotion.
    (c) Cream.
    (d) Gel.
    (e) Butter.
    (f) Paste.
    (g) Ointment.
    (h) Stick.
    (i) Spray, provided that all of the following conditions are 
satisfied:
    (1) Size of particles as dispensed from the consumer container:
    (i) No more than 10 percent of the particles dispensed from the 
consumer container are smaller than 10 micrometers; and
    (ii) None of the particles dispensed from the consumer container 
are smaller than 5 micrometers.
    (2) The product does not meet the definition of the term 
``extremely flammable'' as defined in Sec.  352.3(f).
    (3) If the product meets the definition of either the term 
``flammable'' or the term ``combustible'' as defined at Sec. Sec.  
352.3(g) or (h), as applicable, when tested in accordance with 16 CFR 
1500.43a, the product also has a measured drying time of less than 10 
minutes.
    (4) The product is labeled as required by Sec. Sec.  201.327(d) and 
(e)(5) of this chapter.
    (5) Testing in accordance with part 211 of this chapter must 
confirm that the product meets the conditions for particle size, 
flammability, and drying time as required by this section and reflected 
in the product labeling.
    (i) Testing of each lot of product for size of particles dispensed 
from the consumer container must be conducted in accordance with 
adequate written specifications.
    (ii) Flammability testing for each batch of product must be 
conducted in accordance with the specifications set forth in 16 CFR 
1500.43a.
    (iii) If the product meets the definition of either the term 
``flammable'' or ``combustible'' as defined at Sec.  352(g) or (h), as 
applicable, when tested accordance with 16 CFR 1500.43a, drying time 
for each lot of product must be conducted in accordance with adequate 
written specifications.
0
18. Revise Sec.  352.50 to read as follows:


Sec.  352.50  Principal display panel of all sunscreen drug products.

    The principal display panel labeling must comply with Sec.  
201.327(b) of this chapter.
0
19. Revise Sec.  352.52 to read as follows:


Sec.  352.52  Labeling of products containing one or more sunscreen 
active ingredients.

    (a) Statement of identity. The labeling of the product contains the 
statement of identity, in accordance with Sec.  201.327(b) of this 
chapter.
    (b) Indications. The labeling of the product contains the 
indication statements identified in Sec.  201.327(c) of this chapter, 
as appropriate, and subject to the conditions stated therein.
    (c) Warnings. The labeling of the product contains the warnings in 
Sec.  201.327(d) of this chapter, as applicable, under the heading 
``Warnings:''
    (d) Directions. The labeling of the product contains the statements 
in Sec.  201.327(e) of this chapter, as applicable, under the heading 
``Directions.''
    (e) Other information. The labeling of the product contains the 
statement in Sec.  201.327(f) of this chapter under the heading ``Other 
information.''
    (f) False or misleading claims. The labeling of the product must 
not contain any claims that would be false and/or misleading on 
sunscreen products, as outlined in Sec.  201.327(g) of this chapter.
0
20. Revise Sec.  352.60 to read as follows:


Sec.  352.60  Labeling of products containing a combination of 
sunscreen and skin protectant active ingredients.

    Statements of identity, indications, warnings, and directions for 
use, respectively, applicable to each ingredient in the product may be 
combined to eliminate duplicative words or phrases so that the 
resulting information is clear and understandable. Labeling provisions 
in Sec.  347.50(e) of this chapter shall not apply to these products.
    (a) Statement of identity. The labeling of the product bears the 
statement of identity, as set forth in Sec.  201.327(h)(1) of this 
chapter.
    (b) Indications. The labeling of the product states, under the 
heading ``Uses,'' the applicable indication statements, as set forth in 
Sec.  201.327(h)(2) of this chapter.
    (c) Warnings. The labeling of the product states, under the heading

[[Page 6275]]

``Warnings,'' the applicable warning statements, as set forth in Sec.  
201.327(h)(3) of this chapter.
    (d) Directions. The labeling of the product states, under the 
heading ``Directions,'' the applicable direction statements, as set 
forth in Sec.  201.327(h)(4) of this chapter.
0
21. Revise subpart D to read as follows:
Subpart D--Final Formulation Testing
Sec.
352.70 SPF testing.
352.80 Broad spectrum testing.

Subpart D--Final Formulation Testing


Sec.  352.70  SPF testing.

    The product is tested in accordance with Sec.  201.327(i) of this 
chapter.


Sec.  352.80  Broad spectrum testing.

    If the product's determined SPF value is at least 15, the product 
is tested and shown to pass the broad spectrum test in Sec.  201.327(j) 
of this chapter.

    Dated: February 14, 2019.
Scott Gottlieb,
Commissioner of Food and Drugs.
[FR Doc. 2019-03019 Filed 2-21-19; 8:45 am]
 BILLING CODE 4164-01-P
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