Difenoconazole; Pesticide Tolerances, 32482-32488 [2017-14105]
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Federal Register / Vol. 82, No. 134 / Friday, July 14, 2017 / Rules and Regulations
report containing this action and other
required information to the U.S. Senate,
the U.S. House of Representatives, and
the Comptroller General of the United
States prior to publication of the rule in
the Federal Register. A major rule
cannot take effect until 60 days after it
is published in the Federal Register.
This action is not a ‘‘major rule’’ as
defined by 5 U.S.C. 804(2).
Under section 307(b)(1) of the Clean
Air Act, petitions for judicial review of
this action must be filed in the United
States Court of Appeals for the
appropriate circuit by September 12,
2017. Filing a petition for
reconsideration by the Administrator of
this final rule does not affect the finality
of this action for the purposes of judicial
review nor does it extend the time
within which a petition for judicial
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postpone the effectiveness of such rule
or action. This action may not be
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Authority: 42 U.S.C. 7401 et seq.
enforce its requirements. (See section
307(b)(2).)
Subpart U—Maine
List of Subjects in 40 CFR Part 52
Environmental protection, Air
pollution control, Carbon monoxide,
Incorporation by reference,
Intergovernmental relations, Lead,
Nitrogen dioxide, Ozone, Particulate
matter, Reporting and recordkeeping
requirements, Sulfur oxides, Volatile
organic compounds.
2. In § 52.1020:
a. In paragraph (c), the table titled
‘‘EPA-Approved Maine Regulations’’ is
amended by revising the entry for
‘‘Chapter 118.’’
■ b. In paragraph (e), the table titled
‘‘Maine Non Regulatory’’ is amended by
adding an entry for ‘‘Demonstration of
Compliance with the Comparable
Measures Requirement of CAA section
184(b)(2)’’ at the end of the table.
The revision and addition read as
follows:
■
■
Dated: June 26, 2017.
Deborah A. Szaro,
Acting Regional Administrator, EPA New
England.
Part 52 of chapter I, title 40 of the
Code of Federal Regulations is amended
as follows:
§ 52.1020
*
PART 52—APPROVAL AND
PROMULGATION OF
IMPLEMENTATION PLANS
Identification of plan.
*
*
(c) * * *
*
*
1. The authority citation for part 52
continues to read as follows:
■
EPA-APPROVED MAINE REGULATIONS
State citation
State effective
date
Title/subject
*
*
*
Chapter 118 ......................... Gasoline Dispensing Facilities Vapor Control.
*
*
*
1/1/2012
*
EPA approval date EPA
approval date and citation 1
*
7/14/2017, [Insert Federal
Register citation].
*
Explanations
*
*
Includes decommissioning of Stage
II vapor recovery systems.
*
*
*
1 In
order to determine the EPA effective date for a specific provision listed in this table, consult the Federal Register notice cited in this column for the particular provision.
*
*
*
*
*
(e) * * *
MAINE NON REGULATORY
Name of non regulatory SIP
provision
Applicable geographic or
nonattainment area
State submittal
date/effective
date
*
*
*
Demonstration of CompliYork, Cumberland, and
ance with the Comparable
Sagadahoc Counties.
Measures Requirement of
CAA section 184(b)(2).
*
4/13/2016
EPA approved date 3
Explanations
*
7/14/2017, [Insert Federal
Register citation].
*
*
Emission calculations and narrative
associated with Stage II Decommissioning SIP revision.
3 In order to determine the EPA effective date for a specific provision listed in this table, consult the Federal Register notice cited in this column for the particular provision.
[FR Doc. 2017–14735 Filed 7–13–17; 8:45 am]
BILLING CODE 6560–50–P
ENVIRONMENTAL PROTECTION
AGENCY
ACTION:
Final rule.
This regulation establishes
tolerances for residues of
difenoconazole in or on cottonseed
subgroup 20C; rice, grain; and rice,
wild, grain. It also amends the existing
tolerance for cotton, gin byproducts, and
removes the tolerance for cotton,
undelinted seed. Syngenta Crop
Protection, LLC requested these
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SUMMARY:
40 CFR Part 180
[EPA–HQ–OPP–2016–0254; FRL–9962–05]
Difenoconazole; Pesticide Tolerances
Environmental Protection
Agency (EPA).
AGENCY:
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Federal Register / Vol. 82, No. 134 / Friday, July 14, 2017 / Rules and Regulations
tolerances under the Federal Food,
Drug, and Cosmetic Act (FFDCA).
DATES: This regulation is effective July
14, 2017. Objections and requests for
hearings must be received on or before
September 12, 2017, and must be filed
in accordance with the instructions
provided in 40 CFR part 178 (see also
Unit I.C. of the SUPPLEMENTARY
INFORMATION).
The docket for this action,
identified by docket identification (ID)
number EPA–HQ–OPP–2016–0254, is
available at https://www.regulations.gov
or at the Office of Pesticide Programs
Regulatory Public Docket (OPP Docket)
in the Environmental Protection Agency
Docket Center (EPA/DC), West William
Jefferson Clinton Bldg., Rm. 3334, 1301
Constitution Ave. NW., Washington, DC
20460–0001. The Public Reading Room
is open from 8:30 a.m. to 4:30 p.m.,
Monday through Friday, excluding legal
holidays. The telephone number for the
Public Reading Room is (202) 566–1744,
and the telephone number for the OPP
Docket is (703) 305–5805. Please review
the visitor instructions and additional
information about the docket available
at https://www.epa.gov/dockets.
FOR FURTHER INFORMATION CONTACT:
Michael Goodis, Registration Division
(7505P), Office of Pesticide Programs,
Environmental Protection Agency, 1200
Pennsylvania Ave. NW., Washington,
DC 20460–0001; main telephone
number: (703) 305–7090; email address:
RDFRNotices@epa.gov.
SUPPLEMENTARY INFORMATION:
ADDRESSES:
I. General Information
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A. Does this action apply to me?
You may be potentially affected by
this action if you are an agricultural
producer, food manufacturer, or
pesticide manufacturer. The following
list of North American Industrial
Classification System (NAICS) codes is
not intended to be exhaustive, but rather
provides a guide to help readers
determine whether this document
applies to them. Potentially affected
entities may include:
• Crop production (NAICS code 111).
• Animal production (NAICS code
112).
• Food manufacturing (NAICS code
311).
• Pesticide manufacturing (NAICS
code 32532).
B. How can I get electronic access to
other related information?
You may access a frequently updated
electronic version of EPA’s tolerance
regulations at 40 CFR part 180 through
the Government Printing Office’s e-CFR
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site at https://www.ecfr.gov/cgi-bin/textidx?&c=ecfr&tpl=/ecfrbrowse/Title40/
40tab_02.tpl.
C. How can I file an objection or hearing
request?
Under FFDCA section 408(g), 21
U.S.C. 346a, any person may file an
objection to any aspect of this regulation
and may also request a hearing on those
objections. You must file your objection
or request a hearing on this regulation
in accordance with the instructions
provided in 40 CFR part 178. To ensure
proper receipt by EPA, you must
identify docket ID number EPA–HQ–
OPP–2016–0254 in the subject line on
the first page of your submission. All
objections and requests for a hearing
must be in writing, and must be
received by the Hearing Clerk on or
before September 12, 2017. Addresses
for mail and hand delivery of objections
and hearing requests are provided in 40
CFR 178.25(b).
In addition to filing an objection or
hearing request with the Hearing Clerk
as described in 40 CFR part 178, please
submit a copy of the filing (excluding
any Confidential Business Information
(CBI)) for inclusion in the public docket.
Information not marked confidential
pursuant to 40 CFR part 2 may be
disclosed publicly by EPA without prior
notice. Submit the non-CBI copy of your
objection or hearing request, identified
by docket ID number EPA–HQ–OPP–
2016–0254, by one of the following
methods:
• Federal eRulemaking Portal: https://
www.regulations.gov. Follow the online
instructions for submitting comments.
Do not submit electronically any
information you consider to be CBI or
other information whose disclosure is
restricted by statute.
• Mail: OPP Docket, Environmental
Protection Agency Docket Center (EPA/
DC), (28221T), 1200 Pennsylvania Ave.
NW., Washington, DC 20460–0001.
• Hand Delivery: To make special
arrangements for hand delivery or
delivery of boxed information, please
follow the instructions at https://
www.epa.gov/dockets/contacts.html.
Additional instructions on
commenting or visiting the docket,
along with more information about
dockets generally, is available at https://
www.epa.gov/dockets.
II. Summary of Petitioned-For
Tolerance
In the Federal Register of February 7,
2017 (82 FR 9555) (FRL–9956–86), EPA
issued a document pursuant to FFDCA
section 408(d)(3), 21 U.S.C. 346a(d)(3),
announcing the filing of a pesticide
petition (PP 6F8445) by Syngenta Crop
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Protection, LLC, P.O. Box 18300,
Greensboro, NC 27419. The petition
requested that 40 CFR 180.475 be
amended by establishing tolerances for
residues of the fungicide
difenoconazole, 1-[2-[2-chloro-4-(4chlorophenoxy)phenyl]-4-methyl-1,3dioxolan-2-ylmethyl]-1H-1,2,4-triazole,
in or on cottonseed subgroup 20C at
0.40 parts per million (ppm); rice, grain
at 7 ppm; and rice, wild, grain at 7 ppm.
In addition, the petition requested that
the existing tolerance for cotton, gin
byproducts be increased from 0.05 ppm
to 15 ppm; and requested the tolerance
in/on cotton, undelinted seed at 0.05
ppm as a seed treatment be removed
from 40 CFR 180.475 because the
proposed new tolerance in/on
cottonseed subgroup 20C reflecting
foliar uses will be adequate to support
the seed treatment uses. That document
referenced a summary of the petition
prepared by Syngenta Crop Protection,
LLC, the registrant, which is available in
the docket, https://www.regulations.gov.
There were no comments received in
response to the notice of filing.
III. Aggregate Risk Assessment and
Determination of Safety
Section 408(b)(2)(A)(i) of FFDCA
allows EPA to establish a tolerance (the
legal limit for a pesticide chemical
residue in or on a food) only if EPA
determines that the tolerance is ‘‘safe.’’
Section 408(b)(2)(A)(ii) of FFDCA
defines ‘‘safe’’ to mean that ‘‘there is a
reasonable certainty that no harm will
result from aggregate exposure to the
pesticide chemical residue, including
all anticipated dietary exposures and all
other exposures for which there is
reliable information.’’ This includes
exposure through drinking water and in
residential settings, but does not include
occupational exposure. Section
408(b)(2)(C) of FFDCA requires EPA to
give special consideration to exposure
of infants and children to the pesticide
chemical residue in establishing a
tolerance and to ‘‘ensure that there is a
reasonable certainty that no harm will
result to infants and children from
aggregate exposure to the pesticide
chemical residue. . . .’’
Consistent with FFDCA section
408(b)(2)(D), and the factors specified in
FFDCA section 408(b)(2)(D), EPA has
reviewed the available scientific data
and other relevant information in
support of this action. EPA has
sufficient data to assess the hazards of
and to make a determination on
aggregate exposure for difenoconazole
including exposure resulting from the
tolerances established by this action.
EPA’s assessment of exposures and risks
associated with difenoconazole follows.
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A. Toxicological Profile
EPA has evaluated the available
toxicity data and considered its validity,
completeness, and reliability as well as
the relationship of the results of the
studies to human risk. EPA has also
considered available information
concerning the variability of the
sensitivities of major identifiable
subgroups of consumers, including
infants and children.
Subchronic and chronic studies with
difenoconazole in mice and rats showed
decreased body weights, decreased body
weight gains and effects on the liver
(e.g. hepatocellular hypertrophy, liver
necrosis, fatty changes in the liver). No
systemic toxicity was observed at the
limit dose in the most recently
submitted rat dermal toxicity study.
The available toxicity studies
indicated no increased susceptibility of
rats or rabbits from in utero or postnatal
exposure to difenoconazole. In prenatal
developmental toxicity studies in rats
and rabbits and in the 2-generation
reproduction study in rats, fetal and
offspring toxicity, when observed,
occurred at equivalent or higher doses
than in the maternal and parental
animals.
In a rat developmental toxicity study,
developmental effects were observed at
doses higher than those which caused
maternal toxicity. Developmental effects
in the rat included increased incidence
of ossification of the thoracic vertebrae
and thyroid, decreased number of
sternal centers of ossification, increased
number of ribs and thoracic vertebrae,
and decreased number of lumbar
vertebrae. In the rabbit study,
developmental effects (increases in postimplantation loss and resorptions and
decreases in fetal body weight) were
also seen at maternally toxic doses
(decreased body weight gain and food
consumption). Since the developmental
effects are more severe than the
maternal effects, qualitative
susceptibility is indicated in the rabbit
developmental study; however, the
selected POD is protective of this effect.
In the 2-generation reproduction study
in rats, toxicity to the fetuses and
offspring, when observed, occurred at
equivalent or higher doses than in the
maternal and parental animals.
In an acute neurotoxicity study in
rats, reduced fore-limb grip strength was
observed on day one in males at the
lowest-observed-adverse-effect-level
(LOAEL), and clinical signs of
neurotoxicity were observed in females
only at the highest dose tested. In a
subchronic neurotoxicity study in rats,
decreased hind limb strength was
observed in males only at the mid- and
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high-doses. The effects observed in
acute and subchronic neurotoxicity
studies were considered transient.
Although there is some evidence that
difenoconazole affects antibody levels at
doses that cause systemic toxicity, there
are no indications in the available
studies that organs associated with
immune function, such as the thymus
and spleen, are affected by
difenoconazole.
Difenoconazole is not mutagenic, and
no evidence of carcinogenicity was seen
in rats. Evidence for carcinogenicity was
seen in mice (liver tumors), but
statistically significant carcinoma
tumors were only induced at
excessively-high doses. Adenomas
(benign tumors) and liver necrosis only
were seen at 300 ppm (46 and 58
milligram/kilogram/day (mg/kg/day) in
males and females, respectively); the
NOAEL in that study was 30 ppm. EPA
has concluded that the chronic point of
departure (POD) for assessing chronic
risk (0.96 mg/kg/day) will be protective
of any cancer effects for the following
reasons: (1) Tumors were seen in only
one species; (2) carcinoma tumors were
observed only at the two highest doses
(2,500 and 4,500 ppm) in the mouse
carcinogenicity study; (3) benign tumors
and necrosis were observed at the middose (300 ppm) ; (4) the absence of
tumors at the study’s lower doses (30
ppm); (5) the absence of genotoxic or
mutagenic effects. The cRfD of 0.96 mg/
kg/day is well below the no-observedadverse-effect-level (NOAEL) of the
mouse carcinogenicity study of 30 ppm
(4.7 and 5.6 mg/kg/day in males and
females, respectively), at which no
effects on the biological endpoints
relevant to tumor development (i.e.,
hepatocellular hypertrophy, liver
necrosis, fatty changes in the liver and
bile stasis) were seen. As a result, EPA
has concluded that a nonlinear RfD
approach is appropriate for assessing
cancer risk to difenoconazole and a
separate quantitative cancer exposure
assessment is unnecessary.
Specific information on the studies
received and the nature of the adverse
effects caused by difenoconazole as well
as the no-observed-adverse-effect-level
(NOAEL) and the lowest-observedadverse-effect-level (LOAEL) from the
toxicity studies can be found at https://
www.regulations.gov in document
‘‘Difenoconazole: Human Health Risk
Assessment for Proposed New Foliar
Uses on Cotton, Rice and Wild Rice’’ at
pp. 20–21 in docket ID number EPA–
HQ–OPP–2016–0254.
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B. Toxicological Points of Departure/
Levels of Concern
Once a pesticide’s toxicological
profile is determined, EPA identifies
toxicological points of departure (POD)
and levels of concern to use in
evaluating the risk posed by human
exposure to the pesticide. For hazards
that have a threshold below which there
is no appreciable risk, the toxicological
POD is used as the basis for derivation
of reference values for risk assessment.
PODs are developed based on a careful
analysis of the doses in each
toxicological study to determine the
dose at which no adverse effects are
observed (the NOAEL) and the lowest
dose at which adverse effects of concern
are identified (the LOAEL). Uncertainty/
safety factors are used in conjunction
with the POD to calculate a safe
exposure level—generally referred to as
a population-adjusted dose (PAD) or a
reference dose (RfD)—and a safe margin
of exposure (MOE). For non-threshold
risks, the Agency assumes that any
amount of exposure will lead to some
degree of risk. Thus, the Agency
estimates risk in terms of the probability
of an occurrence of the adverse effect
expected in a lifetime. For more
information on the general principles
EPA uses in risk characterization and a
complete description of the risk
assessment process, see https://
www2.epa.gov/pesticide-science-andassessing-pesticide-risks/assessinghuman-health-risk-pesticides.
A summary of the toxicological
endpoints for difenoconazole used for
human risk assessment is discussed in
Unit III.B. of the final rule published in
the Federal Register of April 2, 2015 (80
FR 17697) (FRL–9923–82).
C. Exposure Assessment
1. Dietary exposure from food and
feed uses. In evaluating dietary
exposure to difenoconazole, EPA
considered exposure under the
petitioned-for tolerances as well as all
existing difenoconazole tolerances in 40
CFR 180.475. EPA assessed dietary
exposures from difenoconazole in food
as follows:
i. Acute exposure. Quantitative acute
dietary exposure and risk assessments
are performed for a food-use pesticide,
if a toxicological study has indicated the
possibility of an effect of concern
occurring as a result of a 1-day or single
exposure.
Such effects were identified for
difenoconazole. In estimating acute
dietary exposure, EPA used food
consumption information from the
United States Department of Agriculture
(USDA) National Health and Nutrition
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Examination Survey, What We Eat in
America, (NHANES/WWEIA). This
dietary survey was conducted from 2003
to 2008. As to residue levels in food,
EPA assumed tolerance-level residues,
100 percent crop treated (PCT), and
available empirical or DEEM (ver. 7.81)
default processing factors.
ii. Chronic exposure. In conducting
the chronic dietary exposure assessment
EPA used the food consumption data
from the USDA National Health and
Nutrition Examination Survey, What We
Eat in America, (NHANES/WWEIA).
This dietary survey was conducted from
2003 to 2008. As to residue levels in
food, EPA used tolerance-level residues
for some commodities, average field
trial residues and USDA Pesticide Data
Program monitoring samples for the
remaining commodities, available
empirical or DEEM (ver.7.81) default
processing factors, and average PCT
assumptions for some commodities.
iii. Cancer. Based on the data
summarized in Unit III.A., EPA has
concluded that a nonlinear RfD
approach is appropriate for assessing
cancer risk to difenoconazole.
Therefore, a separate quantitative cancer
exposure assessment is unnecessary
since the chronic dietary risk estimate
will be protective of potential cancer
risk.
iv. Anticipated residue and percent
crop treated (PCT) information. Section
408(b)(2)(E) of FFDCA authorizes EPA
to use available data and information on
the anticipated residue levels of
pesticide residues in food and the actual
levels of pesticide residues that have
been measured in food. If EPA relies on
such information, EPA must require
pursuant to FFDCA section 408(f)(1)
that data be provided 5 years after the
tolerance is established, modified, or
left in effect, demonstrating that the
levels in food are not above the levels
anticipated. For the present action, EPA
will issue such data call-ins as are
required by FFDCA section 408(b)(2)(E)
and authorized under FFDCA section
408(f)(1). Data will be required to be
submitted no later than 5 years from the
date of issuance of these tolerances.
Section 408(b)(2)(F) of FFDCA states
that the Agency may use data on the
actual percent of food treated for
assessing chronic dietary risk only if:
• Condition a: The data used are
reliable and provide a valid basis to
show what percentage of the food
derived from such crop is likely to
contain the pesticide residue.
• Condition b: The exposure estimate
does not underestimate exposure for any
significant subpopulation group.
• Condition c: Data are available on
pesticide use and food consumption in
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a particular area, the exposure estimate
does not understate exposure for the
population in such area.
In addition, the Agency must provide
for periodic evaluation of any estimates
used. To provide for the periodic
evaluation of the estimate of PCT as
required by FFDCA section 408(b)(2)(F),
EPA may require registrants to submit
data on PCT.
For the chronic dietary exposure
assessment, the Agency used average
PCT estimates for existing uses as
follows: Almond 10%, apple 20%,
apricot 10%, broccoli 2.5%, Brussels
sprouts 2.5%, cabbage 5%, cantaloupe
2.5%, carrot 5%, cauliflower 2.5%,
cherry 2.5%, cucumber 5%, garlic 5%,
grape 10%, grapefruit 2.5%, hazelnut
1%, nectarine 2.5%, onions 5%, orange
2.5%, peach 2.5%, pear 10%, pecan
2.5%, pepper 5%, pistachio 5%, plum/
prune 10%, potato 20%, pumpkin 2.5%,
soybean 2.5%, squash 5%, strawberry
2.5%, sugar beet 15%, tangerine 2.5%,
tomato 25%, walnut 1%, watermelon
5%, and wheat (seed treatment) 10%.
In most cases, EPA uses available data
from United States Department of
Agriculture/National Agricultural
Statistics Service (USDA/NASS),
proprietary market surveys, and the
National Pesticide Use Database for the
chemical/crop combination for the most
recent 6–7 years. EPA uses an average
PCT value for chronic dietary risk
analysis. The average PCT value for
each existing use is derived by
combining available public and private
market survey data for that use and
averaged across all observations and is
rounded up to the nearest multiple of
5%, for use in the analysis unless the
average PCT value is estimated at less
than 2.5% or 1%, in which case the
Agency uses 2.5% or 1%, respectively,
as the average PCT value in the analysis.
EPA uses a maximum PCT value for
acute dietary risk analysis. The
maximum PCT value is the highest
observed maximum value reported
within the recent 6 years of available
public and private market survey data
for the existing use and rounded up to
the nearest multiple of 5% for use in the
analysis, unless the maximum PCT
value is estimated at less than 2.5%, in
which case the Agency uses 2.5% as the
maximum PCT value in the analysis.
The Agency believes that the three
conditions discussed in Unit III.C.1.iv.
have been met. With respect to
Condition a, PCT estimates are derived
from Federal and private market survey
data, which are reliable and have a valid
basis. The Agency is reasonably certain
that the percentage of the food treated
is not likely to be an underestimation.
As to Conditions b and c, regional
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consumption information and
consumption information for significant
subpopulations is taken into account
through EPA’s computer-based model
for evaluating the exposure of
significant subpopulations including
several regional groups. Use of this
consumption information in EPA’s risk
assessment process ensures that EPA’s
exposure estimate does not understate
exposure for any significant
subpopulation group and allows the
Agency to be reasonably certain that no
regional population is exposed to
residue levels higher than those
estimated by the Agency. Other than the
data available through national food
consumption surveys, EPA does not
have available reliable information on
the regional consumption of food to
which difenoconazole may be applied
in a particular area.
2. Dietary exposure from drinking
water. The drinking water assessment
was performed using a total toxic
residue method, which considers both
parent difenoconazole and its major
metabolite, CGA 205375, in surface and
groundwater. Therefore, the Agency
used screening-level water exposure
models in the dietary exposure analysis
and risk assessment for difenoconazole
and its major metabolite in drinking
water. These simulation models take
into account data on the physical,
chemical, and fate/transport
characteristics of difenoconazole and
CGA 205375. Further information
regarding EPA drinking water models
used in pesticide exposure assessment
can be found at https://www2.epa.gov/
pesticide-science-and-assessingpesticide-risks/about-water-exposuremodels-used-pesticide.
Based on the Tier II Pesticide in Water
Calculator, the Revised Tier 1 Rice
Model, the Surface Water Concentration
Calculator, and Pesticide Root Zone
Model Ground Water (PRZM GW), the
estimated drinking water concentrations
(EDWCs) of total toxic residues of
difenoconazole for acute exposures are
estimated to be 33.4 parts per billion
(ppb) for surface water and 2.0 ppb for
ground water. For chronic exposures
estimated drinking water concentrations
(EDWCs) of total toxic residues of
difenoconazole for non-cancer
assessments are estimated to be 27.8
ppb for surface water and 0.60 ppb for
ground water.
Modeled estimates of drinking water
concentrations were directly entered
into the dietary exposure model. For
acute dietary risk assessment, the water
concentration value of 33.4 ppb was
used to assess the contribution to
drinking water. For chronic dietary risk
assessment, the water concentration of
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value 27.8 ppb was used to assess the
contribution to drinking water.
3. From non-dietary exposure. The
term ‘‘residential exposure’’ is used in
this document to refer to nonoccupational, non-dietary exposure
(e.g., for lawn and garden pest control,
indoor pest control, termiticides, and
flea and tick control on pets).
Difenoconazole is currently registered
for the following uses that could result
in residential exposures: Treatment of
ornamental plants in commercial and
residential landscapes and interior
plantscapes. EPA assessed residential
exposure using the following
assumptions: For residential handlers,
adult short-term dermal and inhalation
exposure is expected from mixing,
loading, and applying difenoconazole
on ornamentals (gardens and trees). For
residential post-application exposures,
short-term dermal exposure is expected
for both adults and children from postapplication activities in treated
residential landscapes.
The scenarios used in the aggregate
assessment were those that resulted in
the highest exposures. The highest
exposures consist of the short-term
dermal exposure to adults from postapplication activities in treated gardens
and short-term dermal exposure to
children 6 to 11 years old from postapplication activities in treated gardens.
Further information regarding EPA
standard assumptions and generic
inputs for residential exposures may be
found at https://www2.epa.gov/pesticidescience-and-assessing-pesticide-risks/
standard-operating-proceduresresidential-pesticide.
4. Cumulative effects from substances
with a common mechanism of toxicity.
Section 408(b)(2)(D)(v) of FFDCA
requires that, when considering whether
to establish, modify, or revoke a
tolerance, the Agency consider
‘‘available information’’ concerning the
cumulative effects of a particular
pesticide’s residues and ‘‘other
substances that have a common
mechanism of toxicity.’’
Difenoconazole is a member of the
conazole class of fungicides containing
the 1,2,4-triazole moiety. Although
conazoles act similarly in plants (fungi)
by inhibiting ergosterol biosynthesis,
there is not necessarily a relationship
between their pesticidal activity and
their mechanism of toxicity in
mammals. Structural similarities do not
constitute a common mechanism of
toxicity. Evidence is needed to establish
that the chemicals operate by the same,
or essentially the same, sequence of
major biochemical events (EPA, 2002).
In the case of conazoles, however, a
variable pattern of toxicological
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responses is found; some are
hepatotoxic and hepatocarcinogenic in
mice. Some induce thyroid tumors in
rats. Some induce developmental,
reproductive, and neurological effects in
rodents. Furthermore, the conazoles
produce a diverse range of biochemical
events including altered cholesterol
levels, stress responses, and altered
DNA methylation. It is not clearly
understood whether these biochemical
events are directly connected to their
toxicological outcomes. Thus, there is
currently no evidence to indicate that
difenoconazole shares a common
mechanism of toxicity with any other
conazole pesticide, and EPA is not
following a cumulative risk approach
for this tolerance action. For
information regarding EPA’s procedures
for cumulating effects from substances
found to have a common mechanism of
toxicity, see EPA’s Web site at https://
www2.epa.gov/pesticide-science-andassessing-pesticide-risks/cumulativeassessment-risk-pesticides.
This class of compounds can form the
common metabolite 1,2,4-triazole and
two triazole conjugates (triazolylalanine
and triazolylacetic acid). To support
existing tolerances and to establish new
tolerances for triazole-containing
pesticides, including difenoconazole,
EPA conducted a human health risk
assessment for exposure to 1,2,4triazole, triazolylalanine, and
triazolylacetic acid resulting from the
use of all current and pending uses of
any triazole-containing fungicide. The
risk assessment is a highly conservative,
screening-level evaluation in terms of
hazards associated with common
metabolites (e.g., use of a maximum
combination of uncertainty factors) and
potential dietary and non-dietary
exposures (i.e., high end estimates of
both dietary and non-dietary exposures).
The Agency retained a 3X for the
LOAEL to NOAEL safety factor when
the reproduction study was used. In
addition, the Agency retained a 10X for
the lack of studies including a
developmental neurotoxicity (DNT)
study. The assessment includes
evaluations of risks for various
subgroups, including those comprised
of infants and children. The Agency’s
complete risk assessment is found in the
propiconazole reregistration docket at
https://www.regulations.gov, Docket ID
Number EPA–HQ–OPP–2005–0497.
The Agency’s latest updated aggregate
risk assessment for the triazolecontaining metabolites was finalized on
November 15, 2016 and includes the
new uses in this rule. It is titled,
‘‘Common Triazole Metabolites:
Updated Aggregate Human Health Risk
Assessment to Address the New Section
PO 00000
Frm 00040
Fmt 4700
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3 Registrations for Use of
Difenoconazole on Rice and Cotton.’’
Aggregate risk estimates associated with
1,2,4-triazole (T) and the conjugated
triazole metabolites (i.e., combined
residues of triazolylalanine (TA) and
triazolylacetic acid (TAA)), are below
the Agency’s level of concern. There are
no human health risk issues for these
metabolites that would preclude the
new uses of difenoconazole. The
assessment may be found at https://
www.regulations.gov in document in
docket ID number EPA–HQ–OPP–2016–
0254.
D. Safety Factor for Infants and
Children
1. In general. Section 408(b)(2)(C) of
FFDCA provides that EPA shall apply
an additional tenfold (10X) margin of
safety for infants and children in the
case of threshold effects to account for
prenatal and postnatal toxicity and the
completeness of the database on toxicity
and exposure unless EPA determines
based on reliable data that a different
margin of safety will be safe for infants
and children. This additional margin of
safety is commonly referred to as the
FQPA Safety Factor (SF). In applying
this provision, EPA either retains the
default value of 10X, or uses a different
additional safety factor when reliable
data available to EPA support the choice
of a different factor.
2. Prenatal and postnatal sensitivity.
The prenatal and postnatal toxicology
database for difenoconazole includes rat
and rabbit prenatal developmental
toxicity studies and a 2-generation
reproduction toxicity study in rats. The
available Agency guideline studies
indicated no increased qualitative or
quantitative susceptibility of rats to in
utero and/or postnatal exposure to
difenoconazole. In the prenatal
developmental toxicity studies in rats
and rabbits and the 2-generation
reproduction study in rats, toxicity to
the fetuses/offspring, when observed,
occurred at equivalent or higher doses
than in the maternal/parental animals.
In a rat developmental toxicity study
developmental effects were observed at
doses higher than those which caused
maternal toxicity. In the rabbit study,
developmental effects (increases in postimplantation loss and resorptions and
decreases in fetal body weight) were
also seen at maternally toxic doses
(decreased body weight gain and food
consumption). Since the developmental
effects are more severe than the
maternal effects, qualitative
susceptibility is indicated in the rabbit
developmental study; however, the
selected POD is protective of this effect.
In the 2-generation reproduction study
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in rats, toxicity to the fetuses/offspring,
when observed, occurred at equivalent
or higher doses than in the maternal/
parental animals.
3. Conclusion. EPA has determined
that reliable data show the safety of
infants and children would be
adequately protected if the FQPA SF
were reduced to 1X. That decision is
based on the following findings:
i. The toxicity database for
difenoconazole is complete.
ii. There are no clear signs of
neurotoxicity following acute,
subchronic or chronic dosing in
multiple species in the difenoconazole
database. The effects observed in acute
and subchronic neurotoxicity studies
are transient and showed in one sex
(males as reduced fore-limb grip
strength with no histologic findings),
and the selected endpoints of toxicity
for risk assessment are protective of any
potential neurotoxicity. Based on the
toxicity profile, and lack of concern for
neurotoxicity, there is no need for a
developmental neurotoxicity study or
additional uncertainty factors (UFs) to
account for neurotoxicity.
iii. There is no evidence that
difenoconazole results in increased
susceptibility in in utero rats or rabbits
in the prenatal developmental studies or
in young rats in the 2-generation
reproduction study. The qualitative
susceptibility seen in the rabbit
developmental study is adequately
protected by the selected POD.
iv. There are no residual uncertainties
identified in the exposure databases.
The dietary risk assessment utilized
tolerance-level residues and 100 PCT for
the acute assessment; the chronic
assessment was refined by using USDA
PDP monitoring data, average field-trial
residues for some commodities,
tolerance-level residues for remaining
commodities, and average PCT for some
commodities. These assumptions will
not underestimate dietary exposure to
difenoconazole. EPA made conservative
(protective) assumptions in the ground
and surface water modeling used to
assess exposure to difenoconazole in
drinking water. EPA used similarly
conservative assumptions to assess
postapplication exposure of children.
These assessments will not
underestimate the exposure and risks
posed by difenoconazole.
E. Aggregate Risks and Determination of
Safety
EPA determines whether acute and
chronic dietary pesticide exposures are
safe by comparing aggregate exposure
estimates to the acute PAD (aPAD) and
chronic PAD (cPAD). For linear cancer
risks, EPA calculates the lifetime
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probability of acquiring cancer given the
estimated aggregate exposure. Short-,
intermediate-, and chronic-term risks
are evaluated by comparing the
estimated aggregate food, water, and
residential exposure to the appropriate
PODs to ensure that an adequate MOE
exists.
1. Acute risk. Using the exposure
assumptions discussed in this unit for
acute exposure, the acute dietary
exposure from food and water to
difenoconazole will occupy 53% of the
aPAD for all infants less than 1 year old,
the population group receiving the
greatest exposure.
2. Chronic risk. Using the exposure
assumptions described in this unit for
chronic exposure, EPA has concluded
that chronic exposure to difenoconazole
from food and water will utilize 50% of
the cPAD for all infants less than 1 year
old the population group receiving the
greatest exposure. Based on the
explanation in Unit III.C.3., regarding
residential use patterns, chronic
residential exposure to residues of
difenoconazole is not expected.
3. Short-term risk. Short-term
aggregate exposure takes into account
short-term residential exposure plus
chronic exposure to food and water
(considered to be a background
exposure level). Difenoconazole is
currently registered for uses that could
result in short-term residential
exposure, and the Agency has
determined that it is appropriate to
aggregate chronic exposure through food
and water with short-term residential
exposures to difenoconazole.
Using the exposure assumptions
described in this unit for short-term
exposures, EPA has concluded the
combined short-term food, water, and
residential exposures result in aggregate
MOEs of 250 for children and 180 for
adults. Because EPA’s level of concern
for difenoconazole is a MOE of 100 or
below, these MOEs are not of concern.
4. Intermediate-term risk.
Intermediate-term aggregate exposure
takes into account intermediate-term
residential exposure plus chronic
exposure to food and water (considered
to be a background exposure level). An
intermediate-term adverse effect was
identified; however, difenoconazole is
not registered for any use patterns that
would result in intermediate-term
residential exposure. Intermediate-term
risk is assessed based on intermediateterm residential exposure plus chronic
dietary exposure. Because there is no
intermediate-term residential exposure
and chronic dietary exposure has
already been assessed under the
appropriately protective cPAD (which is
at least as protective as the POD used to
PO 00000
Frm 00041
Fmt 4700
Sfmt 4700
32487
assess intermediate-term risk), no
further assessment of intermediate-term
risk is necessary, and EPA relies on the
chronic dietary risk assessment for
evaluating intermediate-term risk for
difenoconazole.
5. Aggregate cancer risk for U.S.
population. Based on the data
summarized in Unit III.A., the chronic
dietary risk assessment is protective of
any potential cancer effects. Based on
the results of that assessment, EPA
concludes that difenoconazole is not
expected to pose a cancer risk to
humans.
6. Determination of safety. Based on
these risk assessments, EPA concludes
that there is a reasonable certainty that
no harm will result to the general
population, or to infants and children
from aggregate exposure to
difenoconazole residues.
IV. Other Considerations
A. Analytical Enforcement Methodology
Adequate enforcement methodology
(gas chromatography with nitrogen
phosphorus detection (GC/NPD) method
AG–575B) is available for the
determination of residues of
difenoconazole in or on plant
commodities. Liquid chromatography
with tandem mass spectrometry (LC/
MS/MS) method REM 147.07b is
available for the determination of
residues of difenoconazole and CGA–
205375 in livestock commodities.
Adequate confirmatory methods are also
available.
The method may be requested from:
Chief, Analytical Chemistry Branch,
Environmental Science Center, 701
Mapes Rd., Ft. Meade, MD 20755–5350;
telephone number: (410) 305–2905;
email address: residuemethods@
epa.gov.
B. International Residue Limits
In making its tolerance decisions, EPA
seeks to harmonize U.S. tolerances with
international standards whenever
possible, consistent with U.S. food
safety standards and agricultural
practices. EPA considers the
international maximum residue limits
(MRLs) established by the Codex
Alimentarius Commission (Codex), as
required by FFDCA section 408(b)(4).
The Codex Alimentarius is a joint
United Nations Food and Agriculture
Organization/World Health
Organization food standards program,
and it is recognized as an international
food safety standards-setting
organization in trade agreements to
which the United States is a party. EPA
may establish a tolerance that is
different from a Codex MRL; however,
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FFDCA section 408(b)(4) requires that
EPA explain the reasons for departing
from the Codex level.
The Codex has not established a MRL
for difenoconazole in or on cottonseed
subgroup 20C; cotton gin byproducts;
rice, grain; and rice, wild, grain.
V. Conclusion
Therefore, tolerances are established
for residues of difenoconazole, 1-[2-[2chloro-4-(4-chlorophenoxy)phenyl]-4methyl-1,3-dioxolan-2-ylmethyl]-1H–
1,2,4-triazole, in or on cottonseed
subgroup 20C at 0.40 ppm; rice, grain at
7.0 ppm; and rice, wild, grain at 7.0
ppm. Additionally, this regulation
amends the current tolerance for cotton,
gin byproducts from 0.05 ppm to 15
ppm. Finally, EPA is removing the
established tolerance for residues of
difenoconazole in or on cotton,
undelinted seed at 0.05 ppm because
residues on cotton, undelinted seed are
covered by the new tolerance for
cottonseed subgroup 20C.
mstockstill on DSK30JT082PROD with RULES
VI. Statutory and Executive Order
Reviews
This action establishes tolerances
under FFDCA section 408(d) in
response to a petition submitted to the
Agency. The Office of Management and
Budget (OMB) has exempted these types
of actions from review under Executive
Order 12866, entitled ‘‘Regulatory
Planning and Review’’ (58 FR 51735,
October 4, 1993). Because this action
has been exempted from review under
Executive Order 12866, this action is
not subject to Executive Order 13211,
entitled ‘‘Actions Concerning
Regulations That Significantly Affect
Energy Supply, Distribution, or Use’’ (66
FR 28355, May 22, 2001) or Executive
Order 13045, entitled ‘‘Protection of
Children from Environmental Health
Risks and Safety Risks’’ (62 FR 19885,
April 23, 1997). This action does not
contain any information collections
subject to OMB approval under the
Paperwork Reduction Act (PRA) (44
U.S.C. 3501 et seq.), nor does it require
any special considerations under
Executive Order 12898, entitled
‘‘Federal Actions to Address
Environmental Justice in Minority
Populations and Low-Income
Populations’’ (59 FR 7629, February 16,
1994).
Since tolerances and exemptions that
are established on the basis of a petition
under FFDCA section 408(d), such as
the tolerance in this final rule, do not
require the issuance of a proposed rule,
the requirements of the Regulatory
Flexibility Act (RFA) (5 U.S.C. 601 et
seq.), do not apply.
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This action directly regulates growers,
food processors, food handlers, and food
retailers, not States or tribes, nor does
this action alter the relationships or
distribution of power and
responsibilities established by Congress
in the preemption provisions of FFDCA
section 408(n)(4). As such, the Agency
has determined that this action will not
have a substantial direct effect on States
or tribal governments, on the
relationship between the national
government and the States or tribal
governments, or on the distribution of
power and responsibilities among the
various levels of government or between
the Federal Government and Indian
tribes. Thus, the Agency has determined
that Executive Order 13132, entitled
‘‘Federalism’’ (64 FR 43255, August 10,
1999) and Executive Order 13175,
entitled ‘‘Consultation and Coordination
with Indian Tribal Governments’’ (65 FR
67249, November 9, 2000) do not apply
to this action. In addition, this action
does not impose any enforceable duty or
contain any unfunded mandate as
described under Title II of the Unfunded
Mandates Reform Act (UMRA) (2 U.S.C.
1501 et seq.).
This action does not involve any
technical standards that would require
Agency consideration of voluntary
consensus standards pursuant to section
12(d) of the National Technology
Transfer and Advancement Act
(NTTAA) (15 U.S.C. 272 note).
VII. Congressional Review Act
Pursuant to the Congressional Review
Act (5 U.S.C. 801 et seq.), EPA will
submit a report containing this rule and
other required information to the U.S.
Senate, the U.S. House of
Representatives, and the Comptroller
General of the United States prior to
publication of the rule in the Federal
Register. This action is not a ‘‘major
rule’’ as defined by 5 U.S.C. 804(2).
List of Subjects in 40 CFR Part 180
Environmental protection,
Administrative practice and procedure,
Agricultural commodities, Pesticides
and pests, Reporting and recordkeeping
requirements.
Dated: June 1, 2017.
Michael L. Goodis,
Director, Registration Division, Office of
Pesticide Programs.
Therefore, 40 CFR chapter I is
amended as follows:
■
PART 180—[AMENDED]
1. The authority citation for part 180
continues to read as follows:
■
PO 00000
Authority: 21 U.S.C. 321(q), 346a and 371.
Frm 00042
Fmt 4700
Sfmt 4700
2. In § 180.475:
i. Remove the entry ‘‘Cotton,
undelinted seed’’;
■ ii. Revise the entry for ‘‘Cotton, gin
byproducts’’; and
■ iii. Add alphabetically the entries
‘‘Cottonseed subgroup 20C’’, ‘‘Rice,
grain’’, and ‘‘Rice, wild, grain’’ to the
table in paragraph (a)(1) to read as
follows:
■
■
§ 180.475 Difenoconazole; tolerances for
residues.
(a) * * * (1) * * *
Parts per
million
Commodity
*
*
*
*
Cotton, gin byproducts .........
Cottonseed subgroup 20C ...
*
*
*
*
15
0.40
*
*
Rice, grain ............................
Rice, wild, grain ....................
*
*
*
*
*
*
*
7.0
7.0
*
*
*
[FR Doc. 2017–14105 Filed 7–13–17; 8:45 am]
BILLING CODE 6560–50–P
DEPARTMENT OF HOMELAND
SECURITY
Coast Guard
46 CFR Chapter I
[Docket No. USCG–2016–0669]
Marine Safety Manual, Volume III, Parts
B and C, Change–2
Coast Guard, DHS.
Availability of updated Marine
Safety Manual.
AGENCY:
ACTION:
The Coast Guard announces
the availability of Change–2 to the
Marine Safety Manual (MSM), Volume
III, Marine Industry Personnel, and the
corresponding Commandant Change
Notice that highlights the changes made
to that manual. MSM Volume III
provides information and
interpretations on international
conventions and U.S. statutory and
regulatory issues relating to marine
industry personnel. This Commandant
Change Notice discusses the substantive
changes to Parts B and C of MSM
Volume III. All changes are underlined
in the final version and each changed
page is annotated with CH–2 in the
footer. The date of each change since
SUMMARY:
E:\FR\FM\14JYR1.SGM
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Agencies
[Federal Register Volume 82, Number 134 (Friday, July 14, 2017)]
[Rules and Regulations]
[Pages 32482-32488]
From the Federal Register Online via the Government Publishing Office [www.gpo.gov]
[FR Doc No: 2017-14105]
-----------------------------------------------------------------------
ENVIRONMENTAL PROTECTION AGENCY
40 CFR Part 180
[EPA-HQ-OPP-2016-0254; FRL-9962-05]
Difenoconazole; Pesticide Tolerances
AGENCY: Environmental Protection Agency (EPA).
ACTION: Final rule.
-----------------------------------------------------------------------
SUMMARY: This regulation establishes tolerances for residues of
difenoconazole in or on cottonseed subgroup 20C; rice, grain; and rice,
wild, grain. It also amends the existing tolerance for cotton, gin
byproducts, and removes the tolerance for cotton, undelinted seed.
Syngenta Crop Protection, LLC requested these
[[Page 32483]]
tolerances under the Federal Food, Drug, and Cosmetic Act (FFDCA).
DATES: This regulation is effective July 14, 2017. Objections and
requests for hearings must be received on or before September 12, 2017,
and must be filed in accordance with the instructions provided in 40
CFR part 178 (see also Unit I.C. of the SUPPLEMENTARY INFORMATION).
ADDRESSES: The docket for this action, identified by docket
identification (ID) number EPA-HQ-OPP-2016-0254, is available at https://www.regulations.gov or at the Office of Pesticide Programs Regulatory
Public Docket (OPP Docket) in the Environmental Protection Agency
Docket Center (EPA/DC), West William Jefferson Clinton Bldg., Rm. 3334,
1301 Constitution Ave. NW., Washington, DC 20460-0001. The Public
Reading Room is open from 8:30 a.m. to 4:30 p.m., Monday through
Friday, excluding legal holidays. The telephone number for the Public
Reading Room is (202) 566-1744, and the telephone number for the OPP
Docket is (703) 305-5805. Please review the visitor instructions and
additional information about the docket available at https://www.epa.gov/dockets.
FOR FURTHER INFORMATION CONTACT: Michael Goodis, Registration Division
(7505P), Office of Pesticide Programs, Environmental Protection Agency,
1200 Pennsylvania Ave. NW., Washington, DC 20460-0001; main telephone
number: (703) 305-7090; email address: RDFRNotices@epa.gov.
SUPPLEMENTARY INFORMATION:
I. General Information
A. Does this action apply to me?
You may be potentially affected by this action if you are an
agricultural producer, food manufacturer, or pesticide manufacturer.
The following list of North American Industrial Classification System
(NAICS) codes is not intended to be exhaustive, but rather provides a
guide to help readers determine whether this document applies to them.
Potentially affected entities may include:
Crop production (NAICS code 111).
Animal production (NAICS code 112).
Food manufacturing (NAICS code 311).
Pesticide manufacturing (NAICS code 32532).
B. How can I get electronic access to other related information?
You may access a frequently updated electronic version of EPA's
tolerance regulations at 40 CFR part 180 through the Government
Printing Office's e-CFR site at https://www.ecfr.gov/cgi-bin/text-idx?&c=ecfr&tpl=/ecfrbrowse/Title40/40tab_02.tpl.
C. How can I file an objection or hearing request?
Under FFDCA section 408(g), 21 U.S.C. 346a, any person may file an
objection to any aspect of this regulation and may also request a
hearing on those objections. You must file your objection or request a
hearing on this regulation in accordance with the instructions provided
in 40 CFR part 178. To ensure proper receipt by EPA, you must identify
docket ID number EPA-HQ-OPP-2016-0254 in the subject line on the first
page of your submission. All objections and requests for a hearing must
be in writing, and must be received by the Hearing Clerk on or before
September 12, 2017. Addresses for mail and hand delivery of objections
and hearing requests are provided in 40 CFR 178.25(b).
In addition to filing an objection or hearing request with the
Hearing Clerk as described in 40 CFR part 178, please submit a copy of
the filing (excluding any Confidential Business Information (CBI)) for
inclusion in the public docket. Information not marked confidential
pursuant to 40 CFR part 2 may be disclosed publicly by EPA without
prior notice. Submit the non-CBI copy of your objection or hearing
request, identified by docket ID number EPA-HQ-OPP-2016-0254, by one of
the following methods:
Federal eRulemaking Portal: https://www.regulations.gov.
Follow the online instructions for submitting comments. Do not submit
electronically any information you consider to be CBI or other
information whose disclosure is restricted by statute.
Mail: OPP Docket, Environmental Protection Agency Docket
Center (EPA/DC), (28221T), 1200 Pennsylvania Ave. NW., Washington, DC
20460-0001.
Hand Delivery: To make special arrangements for hand
delivery or delivery of boxed information, please follow the
instructions at https://www.epa.gov/dockets/contacts.html.
Additional instructions on commenting or visiting the docket, along
with more information about dockets generally, is available at https://www.epa.gov/dockets.
II. Summary of Petitioned-For Tolerance
In the Federal Register of February 7, 2017 (82 FR 9555) (FRL-9956-
86), EPA issued a document pursuant to FFDCA section 408(d)(3), 21
U.S.C. 346a(d)(3), announcing the filing of a pesticide petition (PP
6F8445) by Syngenta Crop Protection, LLC, P.O. Box 18300, Greensboro,
NC 27419. The petition requested that 40 CFR 180.475 be amended by
establishing tolerances for residues of the fungicide difenoconazole,
1-[2-[2-chloro-4-(4-chlorophenoxy)phenyl]-4-methyl-1,3-dioxolan-2-
ylmethyl]-1H-1,2,4-triazole, in or on cottonseed subgroup 20C at 0.40
parts per million (ppm); rice, grain at 7 ppm; and rice, wild, grain at
7 ppm. In addition, the petition requested that the existing tolerance
for cotton, gin byproducts be increased from 0.05 ppm to 15 ppm; and
requested the tolerance in/on cotton, undelinted seed at 0.05 ppm as a
seed treatment be removed from 40 CFR 180.475 because the proposed new
tolerance in/on cottonseed subgroup 20C reflecting foliar uses will be
adequate to support the seed treatment uses. That document referenced a
summary of the petition prepared by Syngenta Crop Protection, LLC, the
registrant, which is available in the docket, https://www.regulations.gov. There were no comments received in response to the
notice of filing.
III. Aggregate Risk Assessment and Determination of Safety
Section 408(b)(2)(A)(i) of FFDCA allows EPA to establish a
tolerance (the legal limit for a pesticide chemical residue in or on a
food) only if EPA determines that the tolerance is ``safe.'' Section
408(b)(2)(A)(ii) of FFDCA defines ``safe'' to mean that ``there is a
reasonable certainty that no harm will result from aggregate exposure
to the pesticide chemical residue, including all anticipated dietary
exposures and all other exposures for which there is reliable
information.'' This includes exposure through drinking water and in
residential settings, but does not include occupational exposure.
Section 408(b)(2)(C) of FFDCA requires EPA to give special
consideration to exposure of infants and children to the pesticide
chemical residue in establishing a tolerance and to ``ensure that there
is a reasonable certainty that no harm will result to infants and
children from aggregate exposure to the pesticide chemical residue. . .
.''
Consistent with FFDCA section 408(b)(2)(D), and the factors
specified in FFDCA section 408(b)(2)(D), EPA has reviewed the available
scientific data and other relevant information in support of this
action. EPA has sufficient data to assess the hazards of and to make a
determination on aggregate exposure for difenoconazole including
exposure resulting from the tolerances established by this action.
EPA's assessment of exposures and risks associated with difenoconazole
follows.
[[Page 32484]]
A. Toxicological Profile
EPA has evaluated the available toxicity data and considered its
validity, completeness, and reliability as well as the relationship of
the results of the studies to human risk. EPA has also considered
available information concerning the variability of the sensitivities
of major identifiable subgroups of consumers, including infants and
children.
Subchronic and chronic studies with difenoconazole in mice and rats
showed decreased body weights, decreased body weight gains and effects
on the liver (e.g. hepatocellular hypertrophy, liver necrosis, fatty
changes in the liver). No systemic toxicity was observed at the limit
dose in the most recently submitted rat dermal toxicity study.
The available toxicity studies indicated no increased
susceptibility of rats or rabbits from in utero or postnatal exposure
to difenoconazole. In prenatal developmental toxicity studies in rats
and rabbits and in the 2-generation reproduction study in rats, fetal
and offspring toxicity, when observed, occurred at equivalent or higher
doses than in the maternal and parental animals.
In a rat developmental toxicity study, developmental effects were
observed at doses higher than those which caused maternal toxicity.
Developmental effects in the rat included increased incidence of
ossification of the thoracic vertebrae and thyroid, decreased number of
sternal centers of ossification, increased number of ribs and thoracic
vertebrae, and decreased number of lumbar vertebrae. In the rabbit
study, developmental effects (increases in post-implantation loss and
resorptions and decreases in fetal body weight) were also seen at
maternally toxic doses (decreased body weight gain and food
consumption). Since the developmental effects are more severe than the
maternal effects, qualitative susceptibility is indicated in the rabbit
developmental study; however, the selected POD is protective of this
effect. In the 2-generation reproduction study in rats, toxicity to the
fetuses and offspring, when observed, occurred at equivalent or higher
doses than in the maternal and parental animals.
In an acute neurotoxicity study in rats, reduced fore-limb grip
strength was observed on day one in males at the lowest-observed-
adverse-effect-level (LOAEL), and clinical signs of neurotoxicity were
observed in females only at the highest dose tested. In a subchronic
neurotoxicity study in rats, decreased hind limb strength was observed
in males only at the mid- and high-doses. The effects observed in acute
and subchronic neurotoxicity studies were considered transient.
Although there is some evidence that difenoconazole affects
antibody levels at doses that cause systemic toxicity, there are no
indications in the available studies that organs associated with immune
function, such as the thymus and spleen, are affected by
difenoconazole.
Difenoconazole is not mutagenic, and no evidence of carcinogenicity
was seen in rats. Evidence for carcinogenicity was seen in mice (liver
tumors), but statistically significant carcinoma tumors were only
induced at excessively-high doses. Adenomas (benign tumors) and liver
necrosis only were seen at 300 ppm (46 and 58 milligram/kilogram/day
(mg/kg/day) in males and females, respectively); the NOAEL in that
study was 30 ppm. EPA has concluded that the chronic point of departure
(POD) for assessing chronic risk (0.96 mg/kg/day) will be protective of
any cancer effects for the following reasons: (1) Tumors were seen in
only one species; (2) carcinoma tumors were observed only at the two
highest doses (2,500 and 4,500 ppm) in the mouse carcinogenicity study;
(3) benign tumors and necrosis were observed at the mid-dose (300 ppm)
; (4) the absence of tumors at the study's lower doses (30 ppm); (5)
the absence of genotoxic or mutagenic effects. The cRfD of 0.96 mg/kg/
day is well below the no-observed-adverse-effect-level (NOAEL) of the
mouse carcinogenicity study of 30 ppm (4.7 and 5.6 mg/kg/day in males
and females, respectively), at which no effects on the biological
endpoints relevant to tumor development (i.e., hepatocellular
hypertrophy, liver necrosis, fatty changes in the liver and bile
stasis) were seen. As a result, EPA has concluded that a nonlinear RfD
approach is appropriate for assessing cancer risk to difenoconazole and
a separate quantitative cancer exposure assessment is unnecessary.
Specific information on the studies received and the nature of the
adverse effects caused by difenoconazole as well as the no-observed-
adverse-effect-level (NOAEL) and the lowest-observed-adverse-effect-
level (LOAEL) from the toxicity studies can be found at https://www.regulations.gov in document ``Difenoconazole: Human Health Risk
Assessment for Proposed New Foliar Uses on Cotton, Rice and Wild Rice''
at pp. 20-21 in docket ID number EPA-HQ-OPP-2016-0254.
B. Toxicological Points of Departure/Levels of Concern
Once a pesticide's toxicological profile is determined, EPA
identifies toxicological points of departure (POD) and levels of
concern to use in evaluating the risk posed by human exposure to the
pesticide. For hazards that have a threshold below which there is no
appreciable risk, the toxicological POD is used as the basis for
derivation of reference values for risk assessment. PODs are developed
based on a careful analysis of the doses in each toxicological study to
determine the dose at which no adverse effects are observed (the NOAEL)
and the lowest dose at which adverse effects of concern are identified
(the LOAEL). Uncertainty/safety factors are used in conjunction with
the POD to calculate a safe exposure level--generally referred to as a
population-adjusted dose (PAD) or a reference dose (RfD)--and a safe
margin of exposure (MOE). For non-threshold risks, the Agency assumes
that any amount of exposure will lead to some degree of risk. Thus, the
Agency estimates risk in terms of the probability of an occurrence of
the adverse effect expected in a lifetime. For more information on the
general principles EPA uses in risk characterization and a complete
description of the risk assessment process, see https://www2.epa.gov/pesticide-science-and-assessing-pesticide-risks/assessing-human-health-risk-pesticides.
A summary of the toxicological endpoints for difenoconazole used
for human risk assessment is discussed in Unit III.B. of the final rule
published in the Federal Register of April 2, 2015 (80 FR 17697) (FRL-
9923-82).
C. Exposure Assessment
1. Dietary exposure from food and feed uses. In evaluating dietary
exposure to difenoconazole, EPA considered exposure under the
petitioned-for tolerances as well as all existing difenoconazole
tolerances in 40 CFR 180.475. EPA assessed dietary exposures from
difenoconazole in food as follows:
i. Acute exposure. Quantitative acute dietary exposure and risk
assessments are performed for a food-use pesticide, if a toxicological
study has indicated the possibility of an effect of concern occurring
as a result of a 1-day or single exposure.
Such effects were identified for difenoconazole. In estimating
acute dietary exposure, EPA used food consumption information from the
United States Department of Agriculture (USDA) National Health and
Nutrition
[[Page 32485]]
Examination Survey, What We Eat in America, (NHANES/WWEIA). This
dietary survey was conducted from 2003 to 2008. As to residue levels in
food, EPA assumed tolerance-level residues, 100 percent crop treated
(PCT), and available empirical or DEEM (ver. 7.81) default processing
factors.
ii. Chronic exposure. In conducting the chronic dietary exposure
assessment EPA used the food consumption data from the USDA National
Health and Nutrition Examination Survey, What We Eat in America,
(NHANES/WWEIA). This dietary survey was conducted from 2003 to 2008. As
to residue levels in food, EPA used tolerance-level residues for some
commodities, average field trial residues and USDA Pesticide Data
Program monitoring samples for the remaining commodities, available
empirical or DEEM (ver.7.81) default processing factors, and average
PCT assumptions for some commodities.
iii. Cancer. Based on the data summarized in Unit III.A., EPA has
concluded that a nonlinear RfD approach is appropriate for assessing
cancer risk to difenoconazole. Therefore, a separate quantitative
cancer exposure assessment is unnecessary since the chronic dietary
risk estimate will be protective of potential cancer risk.
iv. Anticipated residue and percent crop treated (PCT) information.
Section 408(b)(2)(E) of FFDCA authorizes EPA to use available data and
information on the anticipated residue levels of pesticide residues in
food and the actual levels of pesticide residues that have been
measured in food. If EPA relies on such information, EPA must require
pursuant to FFDCA section 408(f)(1) that data be provided 5 years after
the tolerance is established, modified, or left in effect,
demonstrating that the levels in food are not above the levels
anticipated. For the present action, EPA will issue such data call-ins
as are required by FFDCA section 408(b)(2)(E) and authorized under
FFDCA section 408(f)(1). Data will be required to be submitted no later
than 5 years from the date of issuance of these tolerances.
Section 408(b)(2)(F) of FFDCA states that the Agency may use data
on the actual percent of food treated for assessing chronic dietary
risk only if:
Condition a: The data used are reliable and provide a
valid basis to show what percentage of the food derived from such crop
is likely to contain the pesticide residue.
Condition b: The exposure estimate does not underestimate
exposure for any significant subpopulation group.
Condition c: Data are available on pesticide use and food
consumption in a particular area, the exposure estimate does not
understate exposure for the population in such area.
In addition, the Agency must provide for periodic evaluation of any
estimates used. To provide for the periodic evaluation of the estimate
of PCT as required by FFDCA section 408(b)(2)(F), EPA may require
registrants to submit data on PCT.
For the chronic dietary exposure assessment, the Agency used
average PCT estimates for existing uses as follows: Almond 10%, apple
20%, apricot 10%, broccoli 2.5%, Brussels sprouts 2.5%, cabbage 5%,
cantaloupe 2.5%, carrot 5%, cauliflower 2.5%, cherry 2.5%, cucumber 5%,
garlic 5%, grape 10%, grapefruit 2.5%, hazelnut 1%, nectarine 2.5%,
onions 5%, orange 2.5%, peach 2.5%, pear 10%, pecan 2.5%, pepper 5%,
pistachio 5%, plum/prune 10%, potato 20%, pumpkin 2.5%, soybean 2.5%,
squash 5%, strawberry 2.5%, sugar beet 15%, tangerine 2.5%, tomato 25%,
walnut 1%, watermelon 5%, and wheat (seed treatment) 10%.
In most cases, EPA uses available data from United States
Department of Agriculture/National Agricultural Statistics Service
(USDA/NASS), proprietary market surveys, and the National Pesticide Use
Database for the chemical/crop combination for the most recent 6-7
years. EPA uses an average PCT value for chronic dietary risk analysis.
The average PCT value for each existing use is derived by combining
available public and private market survey data for that use and
averaged across all observations and is rounded up to the nearest
multiple of 5%, for use in the analysis unless the average PCT value is
estimated at less than 2.5% or 1%, in which case the Agency uses 2.5%
or 1%, respectively, as the average PCT value in the analysis. EPA uses
a maximum PCT value for acute dietary risk analysis. The maximum PCT
value is the highest observed maximum value reported within the recent
6 years of available public and private market survey data for the
existing use and rounded up to the nearest multiple of 5% for use in
the analysis, unless the maximum PCT value is estimated at less than
2.5%, in which case the Agency uses 2.5% as the maximum PCT value in
the analysis.
The Agency believes that the three conditions discussed in Unit
III.C.1.iv. have been met. With respect to Condition a, PCT estimates
are derived from Federal and private market survey data, which are
reliable and have a valid basis. The Agency is reasonably certain that
the percentage of the food treated is not likely to be an
underestimation. As to Conditions b and c, regional consumption
information and consumption information for significant subpopulations
is taken into account through EPA's computer-based model for evaluating
the exposure of significant subpopulations including several regional
groups. Use of this consumption information in EPA's risk assessment
process ensures that EPA's exposure estimate does not understate
exposure for any significant subpopulation group and allows the Agency
to be reasonably certain that no regional population is exposed to
residue levels higher than those estimated by the Agency. Other than
the data available through national food consumption surveys, EPA does
not have available reliable information on the regional consumption of
food to which difenoconazole may be applied in a particular area.
2. Dietary exposure from drinking water. The drinking water
assessment was performed using a total toxic residue method, which
considers both parent difenoconazole and its major metabolite, CGA
205375, in surface and groundwater. Therefore, the Agency used
screening-level water exposure models in the dietary exposure analysis
and risk assessment for difenoconazole and its major metabolite in
drinking water. These simulation models take into account data on the
physical, chemical, and fate/transport characteristics of
difenoconazole and CGA 205375. Further information regarding EPA
drinking water models used in pesticide exposure assessment can be
found at https://www2.epa.gov/pesticide-science-and-assessing-pesticide-risks/about-water-exposure-models-used-pesticide.
Based on the Tier II Pesticide in Water Calculator, the Revised
Tier 1 Rice Model, the Surface Water Concentration Calculator, and
Pesticide Root Zone Model Ground Water (PRZM GW), the estimated
drinking water concentrations (EDWCs) of total toxic residues of
difenoconazole for acute exposures are estimated to be 33.4 parts per
billion (ppb) for surface water and 2.0 ppb for ground water. For
chronic exposures estimated drinking water concentrations (EDWCs) of
total toxic residues of difenoconazole for non-cancer assessments are
estimated to be 27.8 ppb for surface water and 0.60 ppb for ground
water.
Modeled estimates of drinking water concentrations were directly
entered into the dietary exposure model. For acute dietary risk
assessment, the water concentration value of 33.4 ppb was used to
assess the contribution to drinking water. For chronic dietary risk
assessment, the water concentration of
[[Page 32486]]
value 27.8 ppb was used to assess the contribution to drinking water.
3. From non-dietary exposure. The term ``residential exposure'' is
used in this document to refer to non-occupational, non-dietary
exposure (e.g., for lawn and garden pest control, indoor pest control,
termiticides, and flea and tick control on pets).
Difenoconazole is currently registered for the following uses that
could result in residential exposures: Treatment of ornamental plants
in commercial and residential landscapes and interior plantscapes. EPA
assessed residential exposure using the following assumptions: For
residential handlers, adult short-term dermal and inhalation exposure
is expected from mixing, loading, and applying difenoconazole on
ornamentals (gardens and trees). For residential post-application
exposures, short-term dermal exposure is expected for both adults and
children from post-application activities in treated residential
landscapes.
The scenarios used in the aggregate assessment were those that
resulted in the highest exposures. The highest exposures consist of the
short-term dermal exposure to adults from post-application activities
in treated gardens and short-term dermal exposure to children 6 to 11
years old from post-application activities in treated gardens. Further
information regarding EPA standard assumptions and generic inputs for
residential exposures may be found at https://www2.epa.gov/pesticide-science-and-assessing-pesticide-risks/standard-operating-procedures-residential-pesticide.
4. Cumulative effects from substances with a common mechanism of
toxicity. Section 408(b)(2)(D)(v) of FFDCA requires that, when
considering whether to establish, modify, or revoke a tolerance, the
Agency consider ``available information'' concerning the cumulative
effects of a particular pesticide's residues and ``other substances
that have a common mechanism of toxicity.''
Difenoconazole is a member of the conazole class of fungicides
containing the 1,2,4-triazole moiety. Although conazoles act similarly
in plants (fungi) by inhibiting ergosterol biosynthesis, there is not
necessarily a relationship between their pesticidal activity and their
mechanism of toxicity in mammals. Structural similarities do not
constitute a common mechanism of toxicity. Evidence is needed to
establish that the chemicals operate by the same, or essentially the
same, sequence of major biochemical events (EPA, 2002).
In the case of conazoles, however, a variable pattern of
toxicological responses is found; some are hepatotoxic and
hepatocarcinogenic in mice. Some induce thyroid tumors in rats. Some
induce developmental, reproductive, and neurological effects in
rodents. Furthermore, the conazoles produce a diverse range of
biochemical events including altered cholesterol levels, stress
responses, and altered DNA methylation. It is not clearly understood
whether these biochemical events are directly connected to their
toxicological outcomes. Thus, there is currently no evidence to
indicate that difenoconazole shares a common mechanism of toxicity with
any other conazole pesticide, and EPA is not following a cumulative
risk approach for this tolerance action. For information regarding
EPA's procedures for cumulating effects from substances found to have a
common mechanism of toxicity, see EPA's Web site at https://www2.epa.gov/pesticide-science-and-assessing-pesticide-risks/cumulative-assessment-risk-pesticides.
This class of compounds can form the common metabolite 1,2,4-
triazole and two triazole conjugates (triazolylalanine and
triazolylacetic acid). To support existing tolerances and to establish
new tolerances for triazole-containing pesticides, including
difenoconazole, EPA conducted a human health risk assessment for
exposure to 1,2,4-triazole, triazolylalanine, and triazolylacetic acid
resulting from the use of all current and pending uses of any triazole-
containing fungicide. The risk assessment is a highly conservative,
screening-level evaluation in terms of hazards associated with common
metabolites (e.g., use of a maximum combination of uncertainty factors)
and potential dietary and non-dietary exposures (i.e., high end
estimates of both dietary and non-dietary exposures). The Agency
retained a 3X for the LOAEL to NOAEL safety factor when the
reproduction study was used. In addition, the Agency retained a 10X for
the lack of studies including a developmental neurotoxicity (DNT)
study. The assessment includes evaluations of risks for various
subgroups, including those comprised of infants and children. The
Agency's complete risk assessment is found in the propiconazole
reregistration docket at https://www.regulations.gov, Docket ID Number
EPA-HQ-OPP-2005-0497.
The Agency's latest updated aggregate risk assessment for the
triazole-containing metabolites was finalized on November 15, 2016 and
includes the new uses in this rule. It is titled, ``Common Triazole
Metabolites: Updated Aggregate Human Health Risk Assessment to Address
the New Section 3 Registrations for Use of Difenoconazole on Rice and
Cotton.'' Aggregate risk estimates associated with 1,2,4-triazole (T)
and the conjugated triazole metabolites (i.e., combined residues of
triazolylalanine (TA) and triazolylacetic acid (TAA)), are below the
Agency's level of concern. There are no human health risk issues for
these metabolites that would preclude the new uses of difenoconazole.
The assessment may be found at https://www.regulations.gov in document
in docket ID number EPA-HQ-OPP-2016-0254.
D. Safety Factor for Infants and Children
1. In general. Section 408(b)(2)(C) of FFDCA provides that EPA
shall apply an additional tenfold (10X) margin of safety for infants
and children in the case of threshold effects to account for prenatal
and postnatal toxicity and the completeness of the database on toxicity
and exposure unless EPA determines based on reliable data that a
different margin of safety will be safe for infants and children. This
additional margin of safety is commonly referred to as the FQPA Safety
Factor (SF). In applying this provision, EPA either retains the default
value of 10X, or uses a different additional safety factor when
reliable data available to EPA support the choice of a different
factor.
2. Prenatal and postnatal sensitivity. The prenatal and postnatal
toxicology database for difenoconazole includes rat and rabbit prenatal
developmental toxicity studies and a 2-generation reproduction toxicity
study in rats. The available Agency guideline studies indicated no
increased qualitative or quantitative susceptibility of rats to in
utero and/or postnatal exposure to difenoconazole. In the prenatal
developmental toxicity studies in rats and rabbits and the 2-generation
reproduction study in rats, toxicity to the fetuses/offspring, when
observed, occurred at equivalent or higher doses than in the maternal/
parental animals. In a rat developmental toxicity study developmental
effects were observed at doses higher than those which caused maternal
toxicity. In the rabbit study, developmental effects (increases in
post-implantation loss and resorptions and decreases in fetal body
weight) were also seen at maternally toxic doses (decreased body weight
gain and food consumption). Since the developmental effects are more
severe than the maternal effects, qualitative susceptibility is
indicated in the rabbit developmental study; however, the selected POD
is protective of this effect. In the 2-generation reproduction study
[[Page 32487]]
in rats, toxicity to the fetuses/offspring, when observed, occurred at
equivalent or higher doses than in the maternal/parental animals.
3. Conclusion. EPA has determined that reliable data show the
safety of infants and children would be adequately protected if the
FQPA SF were reduced to 1X. That decision is based on the following
findings:
i. The toxicity database for difenoconazole is complete.
ii. There are no clear signs of neurotoxicity following acute,
subchronic or chronic dosing in multiple species in the difenoconazole
database. The effects observed in acute and subchronic neurotoxicity
studies are transient and showed in one sex (males as reduced fore-limb
grip strength with no histologic findings), and the selected endpoints
of toxicity for risk assessment are protective of any potential
neurotoxicity. Based on the toxicity profile, and lack of concern for
neurotoxicity, there is no need for a developmental neurotoxicity study
or additional uncertainty factors (UFs) to account for neurotoxicity.
iii. There is no evidence that difenoconazole results in increased
susceptibility in in utero rats or rabbits in the prenatal
developmental studies or in young rats in the 2-generation reproduction
study. The qualitative susceptibility seen in the rabbit developmental
study is adequately protected by the selected POD.
iv. There are no residual uncertainties identified in the exposure
databases. The dietary risk assessment utilized tolerance-level
residues and 100 PCT for the acute assessment; the chronic assessment
was refined by using USDA PDP monitoring data, average field-trial
residues for some commodities, tolerance-level residues for remaining
commodities, and average PCT for some commodities. These assumptions
will not underestimate dietary exposure to difenoconazole. EPA made
conservative (protective) assumptions in the ground and surface water
modeling used to assess exposure to difenoconazole in drinking water.
EPA used similarly conservative assumptions to assess postapplication
exposure of children. These assessments will not underestimate the
exposure and risks posed by difenoconazole.
E. Aggregate Risks and Determination of Safety
EPA determines whether acute and chronic dietary pesticide
exposures are safe by comparing aggregate exposure estimates to the
acute PAD (aPAD) and chronic PAD (cPAD). For linear cancer risks, EPA
calculates the lifetime probability of acquiring cancer given the
estimated aggregate exposure. Short-, intermediate-, and chronic-term
risks are evaluated by comparing the estimated aggregate food, water,
and residential exposure to the appropriate PODs to ensure that an
adequate MOE exists.
1. Acute risk. Using the exposure assumptions discussed in this
unit for acute exposure, the acute dietary exposure from food and water
to difenoconazole will occupy 53% of the aPAD for all infants less than
1 year old, the population group receiving the greatest exposure.
2. Chronic risk. Using the exposure assumptions described in this
unit for chronic exposure, EPA has concluded that chronic exposure to
difenoconazole from food and water will utilize 50% of the cPAD for all
infants less than 1 year old the population group receiving the
greatest exposure. Based on the explanation in Unit III.C.3., regarding
residential use patterns, chronic residential exposure to residues of
difenoconazole is not expected.
3. Short-term risk. Short-term aggregate exposure takes into
account short-term residential exposure plus chronic exposure to food
and water (considered to be a background exposure level).
Difenoconazole is currently registered for uses that could result in
short-term residential exposure, and the Agency has determined that it
is appropriate to aggregate chronic exposure through food and water
with short-term residential exposures to difenoconazole.
Using the exposure assumptions described in this unit for short-
term exposures, EPA has concluded the combined short-term food, water,
and residential exposures result in aggregate MOEs of 250 for children
and 180 for adults. Because EPA's level of concern for difenoconazole
is a MOE of 100 or below, these MOEs are not of concern.
4. Intermediate-term risk. Intermediate-term aggregate exposure
takes into account intermediate-term residential exposure plus chronic
exposure to food and water (considered to be a background exposure
level). An intermediate-term adverse effect was identified; however,
difenoconazole is not registered for any use patterns that would result
in intermediate-term residential exposure. Intermediate-term risk is
assessed based on intermediate-term residential exposure plus chronic
dietary exposure. Because there is no intermediate-term residential
exposure and chronic dietary exposure has already been assessed under
the appropriately protective cPAD (which is at least as protective as
the POD used to assess intermediate-term risk), no further assessment
of intermediate-term risk is necessary, and EPA relies on the chronic
dietary risk assessment for evaluating intermediate-term risk for
difenoconazole.
5. Aggregate cancer risk for U.S. population. Based on the data
summarized in Unit III.A., the chronic dietary risk assessment is
protective of any potential cancer effects. Based on the results of
that assessment, EPA concludes that difenoconazole is not expected to
pose a cancer risk to humans.
6. Determination of safety. Based on these risk assessments, EPA
concludes that there is a reasonable certainty that no harm will result
to the general population, or to infants and children from aggregate
exposure to difenoconazole residues.
IV. Other Considerations
A. Analytical Enforcement Methodology
Adequate enforcement methodology (gas chromatography with nitrogen
phosphorus detection (GC/NPD) method AG-575B) is available for the
determination of residues of difenoconazole in or on plant commodities.
Liquid chromatography with tandem mass spectrometry (LC/MS/MS) method
REM 147.07b is available for the determination of residues of
difenoconazole and CGA-205375 in livestock commodities. Adequate
confirmatory methods are also available.
The method may be requested from: Chief, Analytical Chemistry
Branch, Environmental Science Center, 701 Mapes Rd., Ft. Meade, MD
20755-5350; telephone number: (410) 305-2905; email address:
residuemethods@epa.gov.
B. International Residue Limits
In making its tolerance decisions, EPA seeks to harmonize U.S.
tolerances with international standards whenever possible, consistent
with U.S. food safety standards and agricultural practices. EPA
considers the international maximum residue limits (MRLs) established
by the Codex Alimentarius Commission (Codex), as required by FFDCA
section 408(b)(4). The Codex Alimentarius is a joint United Nations
Food and Agriculture Organization/World Health Organization food
standards program, and it is recognized as an international food safety
standards-setting organization in trade agreements to which the United
States is a party. EPA may establish a tolerance that is different from
a Codex MRL; however,
[[Page 32488]]
FFDCA section 408(b)(4) requires that EPA explain the reasons for
departing from the Codex level.
The Codex has not established a MRL for difenoconazole in or on
cottonseed subgroup 20C; cotton gin byproducts; rice, grain; and rice,
wild, grain.
V. Conclusion
Therefore, tolerances are established for residues of
difenoconazole, 1-[2-[2-chloro-4-(4-chlorophenoxy)phenyl]-4-methyl-1,3-
dioxolan-2-ylmethyl]-1H-1,2,4-triazole, in or on cottonseed subgroup
20C at 0.40 ppm; rice, grain at 7.0 ppm; and rice, wild, grain at 7.0
ppm. Additionally, this regulation amends the current tolerance for
cotton, gin byproducts from 0.05 ppm to 15 ppm. Finally, EPA is
removing the established tolerance for residues of difenoconazole in or
on cotton, undelinted seed at 0.05 ppm because residues on cotton,
undelinted seed are covered by the new tolerance for cottonseed
subgroup 20C.
VI. Statutory and Executive Order Reviews
This action establishes tolerances under FFDCA section 408(d) in
response to a petition submitted to the Agency. The Office of
Management and Budget (OMB) has exempted these types of actions from
review under Executive Order 12866, entitled ``Regulatory Planning and
Review'' (58 FR 51735, October 4, 1993). Because this action has been
exempted from review under Executive Order 12866, this action is not
subject to Executive Order 13211, entitled ``Actions Concerning
Regulations That Significantly Affect Energy Supply, Distribution, or
Use'' (66 FR 28355, May 22, 2001) or Executive Order 13045, entitled
``Protection of Children from Environmental Health Risks and Safety
Risks'' (62 FR 19885, April 23, 1997). This action does not contain any
information collections subject to OMB approval under the Paperwork
Reduction Act (PRA) (44 U.S.C. 3501 et seq.), nor does it require any
special considerations under Executive Order 12898, entitled ``Federal
Actions to Address Environmental Justice in Minority Populations and
Low-Income Populations'' (59 FR 7629, February 16, 1994).
Since tolerances and exemptions that are established on the basis
of a petition under FFDCA section 408(d), such as the tolerance in this
final rule, do not require the issuance of a proposed rule, the
requirements of the Regulatory Flexibility Act (RFA) (5 U.S.C. 601 et
seq.), do not apply.
This action directly regulates growers, food processors, food
handlers, and food retailers, not States or tribes, nor does this
action alter the relationships or distribution of power and
responsibilities established by Congress in the preemption provisions
of FFDCA section 408(n)(4). As such, the Agency has determined that
this action will not have a substantial direct effect on States or
tribal governments, on the relationship between the national government
and the States or tribal governments, or on the distribution of power
and responsibilities among the various levels of government or between
the Federal Government and Indian tribes. Thus, the Agency has
determined that Executive Order 13132, entitled ``Federalism'' (64 FR
43255, August 10, 1999) and Executive Order 13175, entitled
``Consultation and Coordination with Indian Tribal Governments'' (65 FR
67249, November 9, 2000) do not apply to this action. In addition, this
action does not impose any enforceable duty or contain any unfunded
mandate as described under Title II of the Unfunded Mandates Reform Act
(UMRA) (2 U.S.C. 1501 et seq.).
This action does not involve any technical standards that would
require Agency consideration of voluntary consensus standards pursuant
to section 12(d) of the National Technology Transfer and Advancement
Act (NTTAA) (15 U.S.C. 272 note).
VII. Congressional Review Act
Pursuant to the Congressional Review Act (5 U.S.C. 801 et seq.),
EPA will submit a report containing this rule and other required
information to the U.S. Senate, the U.S. House of Representatives, and
the Comptroller General of the United States prior to publication of
the rule in the Federal Register. This action is not a ``major rule''
as defined by 5 U.S.C. 804(2).
List of Subjects in 40 CFR Part 180
Environmental protection, Administrative practice and procedure,
Agricultural commodities, Pesticides and pests, Reporting and
recordkeeping requirements.
Dated: June 1, 2017.
Michael L. Goodis,
Director, Registration Division, Office of Pesticide Programs.
0
Therefore, 40 CFR chapter I is amended as follows:
PART 180--[AMENDED]
0
1. The authority citation for part 180 continues to read as follows:
Authority: 21 U.S.C. 321(q), 346a and 371.
0
2. In Sec. 180.475:
0
i. Remove the entry ``Cotton, undelinted seed'';
0
ii. Revise the entry for ``Cotton, gin byproducts''; and
0
iii. Add alphabetically the entries ``Cottonseed subgroup 20C'',
``Rice, grain'', and ``Rice, wild, grain'' to the table in paragraph
(a)(1) to read as follows:
Sec. 180.475 Difenoconazole; tolerances for residues.
(a) * * * (1) * * *
------------------------------------------------------------------------
Parts per
Commodity million
------------------------------------------------------------------------
* * * * *
------------------------------------------------------------------------
Cotton, gin byproducts.................................. 15
Cottonseed subgroup 20C................................. 0.40
------------------------------------------------------------------------
* * * * *
------------------------------------------------------------------------
Rice, grain............................................. 7.0
Rice, wild, grain....................................... 7.0
------------------------------------------------------------------------
* * * * *
------------------------------------------------------------------------
* * * * *
[FR Doc. 2017-14105 Filed 7-13-17; 8:45 am]
BILLING CODE 6560-50-P