National Ambient Air Quality Standards for Carbon Monoxide, 8158-8220 [2011-2404]
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Federal Register / Vol. 76, No. 29 / Friday, February 11, 2011 / Proposed Rules
ENVIRONMENTAL PROTECTION
AGENCY
40 CFR Parts 50, 53 and 58
[EPA–HQ–OAR–2008–0015; FRL–9261–4;
2060–AI43]
National Ambient Air Quality
Standards for Carbon Monoxide
Environmental Protection
Agency (EPA).
ACTION: Proposed rule.
AGENCY:
Based on its review of the air
quality criteria and the national ambient
air quality standards (NAAQS) for
carbon monoxide (CO), EPA is
proposing to retain the current
standards. EPA is also proposing
changes to the ambient air monitoring
requirements for CO including those
related to network design.
DATES: Comments must be received on
or before April 12, 2011.
Public Hearings: If, by February 18,
2011, EPA receives a request from a
member of the public to speak at a
public hearing concerning the proposed
regulation, we will hold a public
hearing on February 28, 2011 in
Arlington, Virginia.
ADDRESSES: Submit your comments,
identified by Docket ID No. EPA–HQ–
OAR–2008–0015 by one of the following
methods:
• https://www.regulations.gov: Follow
the on-line instructions for submitting
comments.
• E-mail: a-and-r-Docket@epa.gov.
• Fax: 202–566–9744.
• Mail: Docket No. EPA–HQ–OAR–
2008–0015, Environmental Protection
Agency, Mail code 6102T, 1200
Pennsylvania Ave., NW., Washington,
DC 20460. Please include a total of two
copies.
• Hand Delivery: Docket No. EPA–
HQ–OAR–2008–0015, Environmental
Protection Agency, EPA West, Room
3334, 1301 Constitution Ave., NW.,
Washington, DC. Such deliveries are
only accepted during the Docket’s
normal hours of operation, and special
arrangements should be made for
deliveries of boxed information.
Instructions: Direct your comments to
Docket ID No. EPA–HQ–OAR–2008–
0015. EPA’s policy is that all comments
received will be included in the public
docket without change and may be
made available online at https://
www.regulations.gov, including any
personal information provided, unless
the comment includes information
claimed to be Confidential Business
Information (CBI) or other information
whose disclosure is restricted by statute.
Do not submit information that you
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consider to be CBI or otherwise
protected through https://
www.regulations.gov or e-mail. The
https://www.regulations.gov Web site is
an ‘‘anonymous access’’ system, which
means EPA will not know your identity
or contact information unless you
provide it in the body of your comment.
If you send an e-mail comment directly
to EPA without going through
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address will be automatically captured
and included as part of the comment
that is placed in the public docket and
made available on the Internet. If you
submit an electronic comment, EPA
recommends that you include your
name and other contact information in
the body of your comment and with any
disk or CD–ROM you submit. If EPA
cannot read your comment due to
technical difficulties and cannot contact
you for clarification, EPA may not be
able to consider your comment.
Electronic files should avoid the use of
special characters, any form of
encryption, and be free of any defects or
viruses. For additional information
about EPA’s public docket visit the EPA
Docket Center homepage at https://
www.epa.gov/epahome/dockets.htm.
Public Hearing. If a public hearing is
held, it will be held at the U.S.
Environmental Protection Agency
Conference Center, First Floor
Conference Center South, One Potomac
Yard, 2777 S. Crystal Drive, Arlington,
VA 22202. All visitors will need to go
through security and present a valid
photo identification, such as a driver’s
license. To request a public hearing or
information pertaining to a public
hearing, contact Ms. Jan King, Health
and Environmental Impacts Division,
Office of Air Quality Planning and
Standards (C504–02), Environmental
Protection Agency, Research Triangle
Park, North Carolina 27711; telephone
number (919) 541– 5665; fax number
(919) 541–2664; e-mail address:
king.jan@epa.gov. See the
SUPPLEMENTARY INFORMATION for further
information about a possible public
hearing.
Docket: All documents in the docket
are listed in the https://
www.regulations.gov index. Although
listed in the index, some information is
not publicly available, e.g., CBI or other
information whose disclosure is
restricted by statute. Certain other
material, such as copyrighted material,
will be publicly available only in hard
copy. Publicly available docket
materials are available either
electronically in https://
www.regulations.gov or in hard copy at
the Air and Radiation Docket and
Information Center, EPA/DC, EPA West,
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Room 3334, 1301 Constitution Ave.,
NW., Washington, DC. 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 Air and Radiation
Docket and Information Center is (202)
566–1742.
FOR FURTHER INFORMATION CONTACT: Dr.
Deirdre Murphy, Health and
Environmental Impacts Division, Office
of Air Quality Planning and Standards,
U.S. Environmental Protection Agency,
Mail code C504–06, Research Triangle
Park, NC 27711; telephone: 919–541–
0729; fax: 919–541–0237; e-mail:
murphy.deirdre@epa.gov. For further
information specifically with regard to
section IV of this notice, contact Mr.
Nealson Watkins, Air Quality Analysis
Division, Office of Air Quality Planning
and Standards, U.S. Environmental
Protection Agency, Mail code C304–06,
Research Triangle Park, NC 27711;
telephone: 919–541–5522; fax: 919–
541–1903; e-mail:
watkins.nealson@epa.gov. To request a
public hearing or information pertaining
to a public hearing, contact Ms. Jan
King, Health and Environmental
Impacts Division, Office of Air Quality
Planning and Standards (C504–02),
Environmental Protection Agency,
Research Triangle Park, North Carolina
27711; telephone number (919) 541–
5665; fax number (919) 541–2664; email address: king.jan@epa.gov.
SUPPLEMENTARY INFORMATION:
General Information
What should I consider as I prepare my
comments for EPA?
1. Submitting CBI. Do not submit this
information to EPA through https://
www.regulations.gov or e-mail. Clearly
mark the part or all of the information
that you claim to be CBI. For CBI
information in a disk or CD ROM that
you mail to EPA, mark the outside of the
disk or CD ROM as CBI and then
identify electronically within the disk or
CD ROM the specific information that is
claimed as CBI. In addition to one
complete version of the comment that
includes information claimed as CBI, a
copy of the comment that does not
contain the information claimed as CBI
must be submitted for inclusion in the
public docket. Information so marked
will not be disclosed except in
accordance with procedures set forth in
40 CFR part 2.
2. Tips for Preparing Your Comments.
When submitting comments, remember
to:
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• Identify the rulemaking by docket
number and other identifying
information (subject heading, Federal
Register date and page number).
• Follow directions—the agency may
ask you to respond to specific questions
or organize comments by referencing a
Code of Federal Regulations (CFR) part
or section number.
• Explain why you agree or disagree,
suggest alternatives, and substitute
language for your requested changes.
• Describe any assumptions and
provide any technical information and/
or data that you used.
• Provide specific examples to
illustrate your concerns, and suggest
alternatives.
• Explain your views as clearly as
possible, avoiding the use of profanity
or personal threats.
• Make sure to submit your
comments by the comment period
deadline identified.
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Availability of Related Information
A number of the documents that are
relevant to this rulemaking are available
through EPA’s Office of Air Quality
Planning and Standards (OAQPS)
Technology Transfer Network (TTN)
Web site at https://www.epa.gov/ttn/
naaqs/standards/co/s_co_index.html.
These documents include the Plan for
Review of the National Ambient Air
Quality Standards for Carbon Monoxide
(Integrated Review Plan or IRP, USEPA,
2008), available at https://www.epa.gov/
ttn/naaqs/standards/co/
s_co_cr_pd.html, the Integrated Science
Assessment for Carbon Monoxide
(USEPA, 2010a), available at https://
www.epa.gov/ttn/naaqs/standards/co/
s_co_cr_isa.html, the Quantitative Risk
and Exposure Assessment for Carbon
Monoxide—Amended (USEPA, 2010b),
available at https://www.epa.gov/ttn/
naaqs/standards/co/s_co_cr_rea.html,
and the Policy Assessment for the
Review of the Carbon Monoxide
National Ambient Air Quality
Standards (USEPA, 2010c), available at
https://www.epa.gov/ttn/naaqs/
standards/co/s_co_cr_pa.html. These
and other related documents are also
available for inspection and copying in
the EPA docket identified above.
How can I find information about a
possible public hearing?
To request a public hearing or
information pertaining to a public
hearing on this document, contact Ms.
Jan King, Health and Environmental
Impacts Division, Office of Air Quality
Planning and Standards (C504–02),
Environmental Protection Agency,
Research Triangle Park, North Carolina
27711; telephone number (919) 541–
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5665; fax number (919) 541–2664; email address: king.jan@epa.gov. If a
request for a public hearing is received
by February 18, 2011, information about
the hearing will be posted prior to the
hearing on EPA’s Web site for carbon
monoxide regulatory actions at https://
www.epa.gov/airquality/urbanair/co/.
Table of Contents
The following topics are discussed in this
preamble:
I. Background
A. Legislative Requirements
B. Related Carbon Monoxide Control
Programs
C. Review of the Air Quality Criteria and
Standards for Carbon Monoxide
II. Rationale for Proposed Decisions on the
Primary Standards
A. Air Quality Information
1. Anthropogenic Sources and Emissions of
Carbon Monoxide
2. Ambient Concentrations
B. Health Effects Information
1. Carboxyhemoglobin as Biomarker and
Mechanism of Toxicity
2. Nature of Effects
3. At-Risk Populations
4. Potential Impacts on Public Health
C. Human Exposure and Dose Assessment
1. Summary of Design Aspects
2. Key Limitations and Uncertainties
D. Conclusions on Adequacy of the Current
Standards
1. Approach
2. Evidence-Based and Exposure/DoseBased Considerations in the Policy
Assessment
3. CASAC Advice
4. Administrator’s Proposed Conclusions
Concerning Adequacy
E. Summary of Proposed Decisions on
Primary Standards
III. Consideration of a Secondary Standard
A. Background and Considerations in
Previous Reviews
B. Evidence-Based Considerations in the
Policy Assessment
C. CASAC Advice
D. Administrator’s Proposed Conclusions
Concerning a Secondary Standard
IV. Proposed Amendments to Ambient
Monitoring Requirements
A. Monitoring Methods
1. Proposed Changes to Part 50, Appendix
C
2. Proposed Changes to Part 53
3. Implications for Air Monitoring
Networks
B. Network Design
1. Background
2. On-Road Mobile Sources
3. Near-Road Environment
4. Urban Downtown Areas and Urban
Street Canyons
5. Meteorological and Topographical
Influences
6. Proposed Changes
7. Microscale Carbon Monoxide Monitor
Siting Criteria
V. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory
Planning and Review
B. Paperwork Reduction Act
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C. Regulatory Flexibility Act
D. Unfunded Mandates Reform Act
E. Executive Order 13132: Federalism
F. Executive Order 13175: Consultation
and Coordination with Indian Tribal
Governments
G. Executive Order 13045: Protection of
Children from Environmental Health and
Safety Risks
H. Executive Order 13211: Actions that
Significantly Affect Energy Supply,
Distribution or Use
I. National Technology Transfer and
Advancement Act
J. Executive Order 12898: Federal Actions
to Address Environmental Justice in
Minority Populations and Low-Income
Populations References
I. Background
A. Legislative Requirements
Two sections of the Clean Air Act
(CAA) govern the establishment and
revision of the NAAQS. Section 108 (42
U.S.C. 7408) directs the Administrator
to identify and list ‘‘air pollutant[s]’’ that
in her ‘‘judgment, cause or contribute to
air pollution which may reasonably be
anticipated to endanger public health or
welfare’’ and satisfy two other criteria,
including ‘‘whose presence * * * in the
ambient air results from numerous or
diverse mobile or stationary sources’’
and to issue air quality criteria for those
that are listed. Air quality criteria are
intended to ‘‘accurately reflect the latest
scientific knowledge useful in
indicating the kind and extent of all
identifiable effects on public health or
welfare which may be expected from the
presence of [a] pollutant in the ambient
air * * * .’’
Section 109 (42 U.S.C. 7409) directs
the Administrator to propose and
promulgate ‘‘primary’’ and ‘‘secondary’’
NAAQS for pollutants for which air
quality criteria are issued. Section
109(b)(1) defines a primary standard as
one ‘‘the attainment and maintenance of
which in the judgment of the
Administrator, based on such criteria
and allowing an adequate margin of
safety, are requisite to protect the public
health.’’ 1 A secondary standard, as
defined in section 109(b)(2), must
‘‘specify a level of air quality the
attainment and maintenance of which,
in the judgment of the Administrator,
based on such criteria, is requisite to
protect the public welfare from any
known or anticipated adverse effects
1 The legislative history of section 109 indicates
that a primary standard is to be set at ‘‘the
maximum permissible ambient air level * * *
which will protect the health of any [sensitive]
group of the population,’’ and that for this purpose
‘‘reference should be made to a representative
sample of persons comprising the sensitive group
rather than to a single person in such a group’’ [S.
Rep. No. 91–1196, 91st Cong., 2d Sess. 10 (1970)].
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associated with the presence of such air
pollutant in the ambient air.’’ 2
The requirement that primary
standards include an adequate margin of
safety was intended to address
uncertainties associated with
inconclusive scientific and technical
information available at the time of
standard setting. It was also intended to
provide a reasonable degree of
protection against hazards that research
has not yet identified. Lead Industries
Association v. EPA, 647 F.2d 1130, 1154
(DC Cir 1980), cert. denied, 449 U.S.
1042 (1980); American Petroleum
Institute v. Costle, 665 F.2d 1176, 1186
(DC Cir. 1981), cert. denied, 455 U.S.
1034 (1982). Both kinds of uncertainties
are components of the risk associated
with pollution at levels below those at
which human health effects can be said
to occur with reasonable scientific
certainty. Thus, in selecting primary
standards that include an adequate
margin of safety, the Administrator is
seeking not only to prevent pollution
levels that have been demonstrated to be
harmful but also to prevent lower
pollution levels that may pose an
unacceptable risk of harm, even if the
risk is not precisely identified as to
nature or degree. The CAA does not
require the Administrator to establish a
primary NAAQS at a zero-risk level or
at background concentration levels, see
Lead Industries Association v. EPA, 647
F.2d at 1156 n. 51, but rather at a level
that reduces risk sufficiently so as to
protect public health with an adequate
margin of safety.
In addressing the requirement for an
adequate margin of safety, EPA
considers such factors as the nature and
severity of the health effects involved,
the size of the population(s) at risk, and
the kind and degree of the uncertainties
that must be addressed. The selection of
any particular approach to providing an
adequate margin of safety is a policy
choice left specifically to the
Administrator’s judgment. Lead
Industries Association v. EPA, 647 F.2d
at 1161–62; Whitman v. American
Trucking Associations, 531 U.S. 457,
495 (2001).
In setting standards that are
‘‘requisite’’ to protect public health and
welfare, as provided in section 109(b),
EPA’s task is to establish standards that
are neither more nor less stringent than
necessary for these purposes. Whitman
2 Welfare effects as defined in section 302(h) (42
U.S.C. 7602(h)) include, but are not limited to,
‘‘effects on soils, water, crops, vegetation, man-made
materials, animals, wildlife, weather, visibility, and
climate, damage to and deterioration of property,
and hazards to transportation, as well as effects on
economic values and on personal comfort and wellbeing.’’
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v. American Trucking Associations, 531
U.S. 457, 473. In establishing ‘‘requisite’’
primary and secondary standards, EPA
may not consider the costs of
implementing the standards. Id. at 471.
Section 109(d)(1) of the CAA requires
that ‘‘[n]ot later than December 31, 1980,
and at 5-year intervals thereafter, the
Administrator shall complete a
thorough review of the criteria
published under section 108 and the
national ambient air quality standards
* * * and shall make such revisions in
such criteria and standards and
promulgate such new standards as may
be appropriate * * *’’ Section 109(d)(2)
requires that an independent scientific
review committee ‘‘shall complete a
review of the criteria * * * and the
national primary and secondary ambient
air quality standards * * * and shall
recommend to the Administrator any
new * * * standards and revisions of
existing criteria and standards as may be
appropriate. * * *’’ This independent
review function is performed by the
Clean Air Scientific Advisory
Committee (CASAC).
B. Related Carbon Monoxide Control
Programs
States are primarily responsible for
ensuring attainment and maintenance of
ambient air quality standards once EPA
has established them. Under section 110
of the Act, and related provisions, States
are to submit, for EPA approval, State
implementation plans (SIPs) that
provide for the attainment and
maintenance of such standards through
control programs directed to sources of
the pollutants involved. The States, in
conjunction with EPA, also administer
the prevention of significant
deterioration program. See CAA
sections 160–169. In addition, Federal
programs provide for nationwide
reductions in emissions of these and
other air pollutants through the Federal
motor vehicle and motor vehicle fuel
control program under title II of the Act,
(CAA sections 202–250) which involves
controls for emissions from moving
sources and controls for the fuels used
by these sources; new source
performance standards under section
111; and title IV of the Act (CAA
sections 402–416), which specifically
provides for major reductions in CO
emissions.
C. Review of the Air Quality Criteria and
Standards for Carbon Monoxide
EPA initially established NAAQS for
CO on April 30, 1971. The primary
standards were established to protect
against the occurrence of
carboxyhemoglobin levels in human
blood associated with health effects of
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concern. The standards were set at
9 parts per million (ppm), as an 8-hour
average and 35 ppm, as a 1-hour
average, neither to be exceeded more
than once per year (36 FR 8186). In the
1971 decision, the Administrator judged
that attainment of these standards
would provide the requisite protection
of public health with an adequate
margin of safety and would also provide
requisite protection against known and
anticipated adverse effects on public
welfare, and accordingly set the
secondary (welfare-based) standards
identical to the primary (health-based)
standards.
In 1985, EPA concluded its first
periodic review of the criteria and
standards for CO (50 FR 37484). In that
review, EPA updated the scientific
criteria upon which the initial CO
standards were based through the
publication of the 1979 Air Quality
Criteria Document for Carbon Monoxide
(AQCD; USEPA, 1979a) and prepared a
Staff Paper (USEPA, 1979b), which,
along with the 1979 AQCD, served as
the basis for the development of the
notice of proposed rulemaking which
was published on August 18, 1980 (45
FR 55066). Delays due to uncertainties
regarding the scientific basis for the
final decision resulted in EPA’s
announcing a second public comment
period (47 FR 26407). Following
substantial reexamination of the
scientific data, EPA prepared an
Addendum to the 1979 AQCD (USEPA,
1984a) and an updated Staff Paper
(USEPA, 1984b). Following review by
CASAC (Lippmann, 1984), EPA
announced its decision not to revise the
existing primary standard and to revoke
the secondary standard for CO on
September 13, 1985, due to a lack of
evidence of effects on public welfare at
ambient concentrations (50 FR 37484).
On August 1, 1994, EPA concluded its
second periodic review of the criteria
and standards for CO by deciding that
revisions to the CO NAAQS were not
warranted at that time (59 FR 38906).
This decision reflected EPA’s review of
relevant scientific information
assembled since the last review, as
contained in the 1991 AQCD (USEPA,
1991) and the 1992 Staff Paper (USEPA,
1992). Thus, the primary standards were
retained at 9 ppm with an 8-hour
averaging time, and 35 ppm with a
1-hour averaging time, neither to be
exceeded more than once per year (59
FR 38906).
EPA initiated the next periodic review
in 1997 and the final 2000 AQCD (U.S.
EPA, 2000) was released in August
2000. After release of the AQCD,
Congress requested that the National
Research Council (NRC) review the
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impact of meteorology and topography
on ambient CO concentrations in high
altitude and extreme cold regions of the
U.S. The NRC convened the Committee
on Carbon Monoxide Episodes in
Meteorological and Topographical
Problem Areas, which focused on
Fairbanks, Alaska as a case-study.
A final report, ‘‘Managing Carbon
Monoxide Pollution in Meteorological
and Topographical Problem Areas,’’ was
published in 2003 (NRC, 2003) and
offered a wide range of
recommendations regarding
management of CO air pollution, cold
start emissions standards, oxygenated
fuels, and CO monitoring. Following
completion of the NRC report, EPA did
not conduct rulemaking to complete the
review.
On September 13, 2007, EPA issued a
call for information from the public (72
FR 52369) requesting the submission of
recent scientific information on
specified topics. A workshop was held
on January 28–29, 2008 (73 FR 2490) to
discuss policy-relevant scientific and
technical information to inform EPA’s
planning for the CO NAAQS review.
Following the workshop, a draft
Integrated Review Plan (IRP) (USEPA,
2008a) was made available in March
2008 for public comment and was
discussed by the CASAC via a publicly
accessible teleconference consultation
on April 8, 2008 (73 FR 12998;
Henderson, 2008). EPA made the final
IRP available in August 2008 (USEPA,
2008b).
In preparing the Integrated Science
Assessment for Carbon Monoxide (ISA
or Integrated Science Assessment), EPA
held an authors’ teleconference in
November 2008 with invited scientific
experts to discuss preliminary draft
materials prepared as part of the
ongoing development of the CO ISA and
its supplementary annexes. The first
draft ISA (USEPA, 2009a) was made
available for public review on March 12,
2009 (74 FR 10734) and reviewed by
CASAC at a meeting held on May 12–
13, 2009 (74 FR 15265). A second draft
ISA (USEPA, 2009b) was released for
CASAC and public review on
September 23, 2009 (74 FR 48536), and
it was reviewed by CASAC at a meeting
held on November 16–17, 2009 (74 FR
54042). The final ISA was released in
January 2010 (USEPA, 2010a).
In May 2009, OAQPS released a draft
planning document, the draft Scope and
Methods Plan (USEPA, 2009c), for
consultation with CASAC and public
review at the CASAC meeting held on
May 12–13, 2009. Taking into
consideration comments on the draft
Plan from CASAC (Brain, 2009) and the
public, OAQPS staff developed and
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released for CASAC review and public
comment a first draft Risk and Exposure
Assessment (REA) (USEPA, 2009d),
which was reviewed at the CASAC
meeting held on November 16–17, 2009.
Subsequent to that meeting and taking
into consideration comments from
CASAC (Brain and Samet, 2010a) and
public comments on the first draft REA,
a second draft REA (USEPA, 2010d) was
released for CASAC review and public
comment in February 2010, and
reviewed at a CASAC meeting held on
March 22–23, 2010. Drawing from
information in the final CO ISA and the
second draft REA, EPA released a draft
Policy Assessment (PA) (USEPA, 2010e)
in early March, 2010 for CASAC review
and public comment at the same
meeting. Taking into consideration
comments on the second draft REA and
the draft PA from CASAC (Brain and
Samet, 2010b, 2010c) and the public,
staff completed the quantitative
assessments which are presented in the
final REA (USEPA, 2010b). Staff
additionally took into consideration
those comments and the final REA
analyses in completing the final Policy
Assessment (USEPA, 2010c) which was
released in October, 2010.
The schedule for completion of this
review is governed by a court order
resolving a lawsuit filed in March 2003
by a group of plaintiffs who alleged that
EPA had failed to perform its mandatory
duty, under section 109(d)(1), to
complete a review of the CO NAAQS
within the period provided by statute.
The court order that governs this
review, entered by the court on
November 14, 2008 and amended on
August 30, 2010, provides that EPA will
sign, for publication, notices of
proposed and final rulemaking
concerning its review of the CO NAAQS
no later than January 28, 2011 and
August 12, 2011, respectively.
This action presents the
Administrator’s proposed decisions on
the current CO standards. Throughout
this preamble a number of conclusions,
findings, and determinations proposed
by the Administrator are noted.
Although they identify the reasoning
that supports this proposal, they are not
intended to be final or conclusive in
nature. The EPA invites general,
specific, and technical comments on all
issues involved with this proposal,
including all such proposed judgments,
conclusions, findings, and
determinations.
II. Rationale for Proposed Decisions on
the Primary Standards
This section presents the rationale for
the Administrator’s proposed decision
to retain the existing CO primary
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standards.3 As discussed more fully
below, this rationale is based on a
thorough review, in the Integrated
Science Assessment, of the latest
scientific information, published
through mid-2009, on human health
effects associated with the presence of
CO in the ambient air. This proposal
also takes into account: (1) Staff
assessments of the most policy-relevant
information in the ISA and staff
analyses of air quality, human exposure
and health risks presented in the REA
and the Policy Assessment, upon which
staff conclusions regarding appropriate
considerations in this review are based;
(2) CASAC advice and
recommendations, as reflected in
discussions of drafts of the ISA, REA
and PA at public meetings, in separate
written comments, and in CASAC’s
letters to the Administrator; and (3)
public comments received during the
development of these documents, either
in connection with CASAC meetings or
separately.
In presenting the rationale and its
foundations, this section begins with a
summary of current air quality
information in section II.A. Section II.B
summarizes the body of evidence
supporting this rationale, including key
health endpoints associated with
exposure to ambient CO. This rationale
also draws upon the results of the
quantitative exposure and risk
assessments, discussed below in section
II.C. Evidence- and exposure/dose-based
considerations that form the basis for
the Administrator’s proposed decisions
on the adequacy of the current standard
are discussed in section II.D.2.a and
II.D.2.b, respectively. CASAC advice is
summarized in section II.D.3. The
Administrator’s proposed conclusions
are presented in section II.D.4.
A. Air Quality Information
This section provides a general
overview of the current air quality
conditions to provide context for this
consideration of the current standards
for carbon monoxide. A more
comprehensive discussion of air quality
information is provided in the ISA (ISA,
sections 3.2 and 3.4) and summarized in
the Policy Assessment, and a more
detailed discussion of aspects
particularly relevant to the exposure
assessment is provided in the REA
(REA, chapter 3).
3 As explained below in section IV.A, EPA is
proposing to repromulgate the Federal reference
method for CO, as set forth in Appendix C of 40
CFR part 50. Consistent with EPA’s proposed
decision to retain the standards, the recodification
clarifies and updates the text of the FRM, but does
not make substantive changes to it.
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1. Anthropogenic Sources and
Emissions of Carbon Monoxide
Carbon monoxide in ambient air is
formed primarily by the incomplete
combustion of carbon-containing fuels
and by photochemical reactions in the
atmosphere. As a result of the
combustion conditions, CO emissions
from large fossil-fueled power plants are
typically very low because optimized
fuel consumption conditions make
boiler combustion highly efficient. In
contrast, internal combustion engines
used in many mobile sources have
widely varying operating conditions.
Therefore, higher and more varying CO
formation results from the operation of
these mobile sources (ISA, section 3.2).
As with previous reviews of the CO
NAAQS, mobile sources continue to be
a significant source sector for CO in
ambient air, as indicated by national
emissions estimates from on-road
vehicles, which accounted for
approximately half of the total CO
emissions by individual source sectors
in 2002 (ISA, Figure 3–1).4 Nationalscale anthropogenic CO emissions have
decreased by approximately 45%
between 1990 and 2005, with nearly all
of this national-scale reduction coming
from reductions in on-road vehicle
emissions (ISA, Figure 3–2; PA, Figure
1–1; 2005 NEI 5). The role of mobile
source emissions is evident in the
spatial and temporal patterns of ambient
CO concentrations, which are heavily
influenced by the patterns associated
with mobile source emissions (ISA,
chapter 3). In some metropolitan areas
of the U.S., due to their greater motor
vehicle density relative to rural areas,
on-road mobile source contribution to
all ambient CO emissions was estimated
to be as high as approximately 75%,
based on the 2002 National Emissions
4 EPA compiles CO emissions estimates for the
U.S. in the National Emissions Inventory (NEI).
Estimates come from various sources and different
data sources use different data collection methods,
most of which are based on engineering
calculations and estimates rather than
measurements. Although these estimates are
generated using well-established approaches,
uncertainties are inherent in the emission factors
and models used to represent sources for which
emissions have not been directly measured.
Uncertainties vary by source category, season and
region (ISA, section 3.2.1). At the time of the ISA
development, the 2002 NEI was providing the most
recent publicly available CO emissions estimates for
the U.S. that meet EPA’s data quality assurance
objectives. Such estimates are now available from
the 2005 NEI.
5 The emissions trends information in this
statement is drawn from recently available 2005
National Emissions Inventory estimates (https://
www.epa.gov/ttn/chief/net/2005inventory.html,
Tier Summaries) and 1990 and other estimates,
available at https://www.epa.gov/ttn/chief/net/
critsummary.html Figure 3–2 from the ISA provides
estimates through 2002.
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Inventory (ISA, p. 3–2). However, the
mobile source contribution can vary
widely in specific areas. As an example,
2002 NEI estimates of on-road mobile
source emissions in urban Denver
County, Colorado are about 74% of total
CO emissions and emissions from all
mobile sources (on-road and non-road
combined) are estimated to contribute
about 98% (ISA, section 3.2.1). In
contrast, 2002 NEI estimates of on-road
CO emissions were just 20% of the total
for rural Garfield County, Colorado6
(ISA, chapter 3, Figure 3–6).
2. Ambient Concentrations
As described in section II.A.1 above,
mobile source emissions are major
contributors to CO emissions in urban
areas, with corresponding influence on
ambient CO concentrations and
associated concentration gradients, with
highest ambient concentrations
occurring on or nearest roadways,
particularly highly travelled roadways,
and lowest concentrations in more
distant locations (ISA, section 3.5.1.3;
REA, section 3.1.3). For example, as
described in the ISA CO concentrations
measured within 20 meters of an
interstate highway can range from 2 to
10 times greater than CO concentrations
measured as far as 300 meters from a
major road, possibly influenced by wind
direction and on-road vehicle density
(ISA, section 3.5.1.3, Figures 3–29 and
3–30; Zhu et al., 2002; Baldauf et al.,
2008a,b). Additionally, the role of motor
vehicles in influencing ambient
concentrations contributes to the
occurrence of diurnal variation in
concentrations reflecting rush hour
patterns (ISA, 3.5.2.2; REA, p. 3–8). The
influence of motor vehicle emissions on
ambient concentrations contributes to
the important role of in-vehicle
microenvironments in influencing
short-term ambient CO exposures, as
described in more detail in the REA and
summarized in sections II.C.1 and II.D.2
below.
In 2009, approximately 350 ambient
monitoring stations across the U.S.
reported continuous hourly averages of
CO concentrations to EPA’s Air Quality
System.7 For the most recent period for
which air quality status relative to the
CO NAAQS has been analyzed (2009),
all areas of the U.S. meet both CO
6 The 2002 National Emissions Inventory estimate
for on-road emissions in Garfield County is 20,000
tons, and the total emissions from all sources is
estimated to be 98,831 (99K) tons. Thus, in this
example the on-road vehicles accounts for 20.2% of
the total emissions (ISA, section 3, figure 3–6). In
contrast, the 2002 Denver County on-road emissions
account for 74% of the total for the county which
is estimated at approximately 180,000 tons.
7 https://www.epa.gov/ttn/airs/airsaqs/.
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NAAQS.8 As of September 27, 2010,
there are no areas designated as
nonattainment for the CO NAAQS (75
FR 59090). Since 2005, one area
(Jefferson County, Alabama) has failed
to meet the 8-hour standard during
some periods. Large CO emissions
sources in this area are associated with
an integrated iron and steel facility. As
described in section 1.3.3 of the Policy
Assessment, 2009 concentrations of CO
at most currently operating monitors are
well below the current standards, with
just a few locations having
concentrations near the controlling 8hour standard of 9 ppm as a second
maximum 8-hour average.9 Of the
counties with monitoring sites in 2009,
sites in 3 counties reported second
maximum 8-hour average
concentrations at or above 6.4 ppm (PA,
Figure 1–2).
The current levels of ambient CO
across the U.S. reflect the steady
declines in ambient concentrations that
have occurred over the past several
years. Both the second highest 1-hour
and 8-hour concentrations have
significantly declined since the last
review. At the set of sites across the U.S.
that have been continuously monitored
since 1990 the average second highest 8hour and 1-hour concentrations have
declined by nearly 70% (PA, section
1.3.3).
B. Health Effects Information
1. Carboxyhemoglobin as Biomarker and
Mechanism of Toxicity
As discussed in the Integrated Science
Assessment, in this review, as in the
past (e.g., USEPA, 2000; USEPA, 1991),
the best characterized mechanism of
action of CO is tissue hypoxia caused by
binding of CO to hemoglobin to form
carboxyhemoglobin (COHb).
Accordingly, COHb level in blood
continues to be well recognized as an
important internal dose metric and the
one most commonly used in evaluating
CO exposure and the potential for
health effects (ISA, p. 2–4, sections 4.1,
4.2, 5.1.1; 1991 AQCD, 2000 AQCD,
2010 ISA).
Increasing levels of COHb with
subsequent decrease in oxygen
availability for organs and tissues are of
8 The air quality status in areas monitored relative
to the CO NAAQS is provided at https://
www.epa.gov/air/airtrends/values.html.
9 As the form of the CO 8-hour standard is notto-be-exceeded more than once per year, the second
highest 8-hour average in a year is the design value
for this standard. Based on the current rounding
convention, the standard is met if the CO
concentrations over a year result in a design value
at or below 9.4 ppm. Additional information is
available at https://www.epa.gov/airtrends/
values.html.
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concern in people with pre-existing
heart disease who have compromised
compensatory mechanisms (e.g., lack of
capacity to increase blood flow in
response to increased CO). The
integrative review of health effects of
CO indicates that ‘‘the clearest evidence
indicates that individuals with
[coronary artery disease] are most
susceptible to an increase in COinduced health effects’’ (ISA, section
5.7.8) and the evidence continues to
support levels of COHb in the blood as
the most useful indicator of CO
exposure that is related to the health
effects of CO of major concern.
Carboxyhemoglobin occurs in the
blood due to endogenous CO production
from biochemical reactions associated
with normal breakdown of heme
proteins, as well as in response to
inhaled (exogenous) CO exposures (ISA,
section 4.5). The production of
endogenous CO and levels of
endogenous COHb vary with several
physiological characteristics (e.g.,
slower COHb elimination with
increasing age), as well as some disease
states, which can lead to higher
endogenous levels in some individuals
(ISA, section 4.5). The amount of COHb
formed in response to exogenous CO is
dependent on the CO concentration and
duration of exposure, exercise (which
increases the amount of air removed and
replaced per unit of time for gas
exchange), the pulmonary diffusing
capacity for CO, ambient pressure,
health status, and the specific
metabolism of the exposed individual
(ISA, chapter 4; 2000 AQCD, chapter 5).
The formation of COHb is a reversible
process, but the high affinity of CO for
hemoglobin, which affects the
elimination half-time for COHb, can
lead to increased COHb levels in some
circumstances.
As discussed in the REA, exposure to
CO in ambient air can occur outdoors as
well as through infiltration of ambient
air into indoor locations (REA, section
2.3). Additionally, indoor sources such
as gas stoves and tobacco smoke can,
where present, be important
contributors to total CO exposure and
can result in much greater CO exposures
and associated COHb levels than those
associated with ambient sources (ISA,
section 3.6.5.2).10 For example, indoor
10 A significant source of nonambient CO long
recognized as contributing to elevated COHb levels
is tobacco smoking (e.g., ISA, Figure 4–12). Further,
baseline COHb levels in active smokers have been
estimated to range from 3 to 8% for one- to twopack-per-day smokers. As a result of their higher
baseline COHb levels, smokers may exhale more CO
into the air than they inhale from the ambient
environment when not smoking. Tobacco smoking
can also contribute to increased CO exposures and
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source-related exposures, such as faulty
furnaces or other combustion
appliances, have been estimated in the
past to lead to COHb levels on the order
of twice as high as those short-term
exposures to ambient CO considered
more likely to be encountered by the
general public (2000 AQCD, p. 7–4).
Further, some assessments performed
for previous reviews have included
modeling simulations both without and
with indoor sources (gas stoves and
tobacco smoke) to provide context for
the assessment of ambient CO exposure
and dose (e.g., U.S. EPA, 1992; Johnson
et al., 2000), and these assessments have
found that nonambient sources have a
substantially greater impact on the
highest total exposures experienced by
the simulated population than do
ambient sources (Johnson et al., 2000;
REA, sections 1.2 and 6.3).11. However,
the focus of this REA, conducted to
inform the current review of the CO
NAAQS, is on sources of ambient CO.
While recognizing this information
regarding the potential for indoor
sources, where present, to play a role in
CO exposures and COHb levels, the
exposure modeling in the current
review (described in section II.C below)
did not include indoor CO sources in
order to focus on the impact of ambient
CO sources on population COHb levels.
Apart from the impaired oxygen
delivery to tissues related to COHb
formation, the evidence also indicates
alternative mechanisms of CO-induced
effects independent of limited oxygen
availability (2000 AQCD, section 5.9;
ISA, section 5.1.3). These mechanisms
are primarily associated with CO’s
ability to bind heme-containing proteins
other than hemoglobin and myoglobin,
and involve a wide range of molecular
targets and CO concentrations, as
described in the 2000 AQCD (USEPA,
2000, section 5.6) and in the ISA (ISA,
section 5.1.3). Older toxicological
studies demonstrated that exposure to
high concentrations of CO resulted in
altered functions of heme proteins other
than myoglobin and hemoglobin,
potentially interfering with basic cell
and molecular processes and leading to
dysfunction and/or disease. More recent
toxicological in vitro and in vivo studies
have provided evidence of alteration of
nitric oxide signaling, inhibition of
cytochrome C oxidase, heme loss from
protein, disruption of iron homeostasis
and alteration of cellular reductionoxidation status (ISA, section 5.1.3.2).
associated COHb levels in nonsmokers (2000
AQCD, p. 7–4).
11 As has been recognized in previous CO NAAQS
reviews, such sources cannot be effectively
mitigated by setting more stringent ambient air
quality standards (59 FR 38914).
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The ISA notes that these mechanisms
may be interrelated. The evidence for
these alternative mechanisms and the
role they may play in CO-induced
health effects at concentrations relevant
to the current NAAQS is not clear.
As noted in the ISA, ‘‘CO may be
responsible for a continuum of effects
from cell signaling to adaptive
responses to cellular injury, depending
on intracellular concentrations of CO,
heme proteins and molecules which
modulate CO binding to heme proteins’’
(ISA, section 5.1.3.3). However, as noted
in the Policy Assessment, new research
based on this evidence for pathways
other than those related to impaired
oxygen delivery to tissues is needed to
further understand these pathways and
their linkage to CO-induced effects in
susceptible populations. Thus, the
evidence indicates that COHb continues
to be the most useful and wellsupported indicator of CO exposures
and the best biomarker to characterize
the potential for health effects
associated with exposures to ambient
CO at this time (PA, section 2.2.1).
2. Nature of Effects
As observed in the Policy Assessment,
the long-standing body of evidence that
has established many aspects of the
biological effects of CO continues to
contribute to our understanding of the
health effects of ambient CO (PA,
section 2.2.1). Binding to heme proteins
and the alteration of their function is the
common mechanism underlying
biological responses to CO. Upon
inhalation, CO diffuses through the
respiratory zone (alveoli) to the blood
where it binds to hemoglobin, forming
COHb. Accordingly, inhaled CO elicits
various health effects through binding
to, and associated alteration of the
function of, a number of hemecontaining molecules, mainly
hemoglobin (see e.g., ISA, section 4.1).
The best characterized health effect
associated with CO levels of concern is
hypoxia (reduced oxygen availability)
induced by increased COHb levels in
blood and decreased oxygen availability
to critical tissues and organs,
specifically the heart (ISA, section
5.1.2). Consistent with this, medical
conditions that affect the biological
mechanisms to compensate for this
effect (e.g., vasodilation and increased
coronary blood flow with increased
oxygen delivery to the myocardium) can
contribute to a reduced amount of
oxygen available to key body tissues,
potentially affecting organ system
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function and limiting exercise capacity
(2000 AQCD, section 7.1).12
The body of health effects evidence
for CO has grown considerably since the
review completed in 1994 with the
addition of numerous epidemiological
and toxicological studies (ISA; 2000
AQCD). This evidence provides
additional detail and support to our
prior understanding of CO effects and
population susceptibility. Most notably,
the current evidence includes much
expanded epidemiological evidence that
is consistent with previous conclusions
regarding cardiovascular disease-related
susceptibility (ISA, section 5.7; 2000
AQCD, section 7.7). In this review, the
clearest evidence for ambient CO-related
effects is available for cardiovascular
effects. Using an established framework
to characterize the evidence as to
likelihood of causal relationships
between exposure to ambient CO and
specific health effects (ISA, chapter 1)
the ISA states that ‘‘Given the consistent
and coherent evidence from
epidemiologic and human clinical
studies, along with biological
plausibility provided by CO’s role in
limiting oxygen availability, it is
concluded that a causal relationship is
likely to exist between relevant 13 shortterm CO exposures and cardiovascular
morbidity’’ (ISA, p. 2–6, section 2.5.1).
Additionally, as mentioned above, the
ISA judges the evidence to be suggestive
of causal relationships between relevant
short- and long-term CO exposures and
CNS effects, birth outcomes and
developmental effects following longterm exposure, respiratory morbidity
following short-term exposure, and
mortality following short-term exposure
(ISA, section 2.5, Table 2–1).
Similar to the previous review, results
from controlled human exposure studies
of individuals with coronary artery
disease (CAD) 14 (Adams et al., 1988;
12 For example, people with peripheral vascular
diseases and heart disease patients often have
markedly reduced circulatory capacity and reduced
ability to compensate for increased circulatory
demands during exercise and other stress (2000
AQCD, p. 7–7).
13 Relevant CO exposures are defined in the ISA
as ‘‘generally within one or two orders of magnitude
of ambient CO concentrations’’ (ISA, section 2.5).
14 Coronary artery disease (CAD), often also called
coronary heart disease or ischemic heart disease is
a category of cardiovascular disease associated with
narrowed heart arteries. Individuals with this
disease may have myocardial ischemia, which
occurs when the heart muscle receives insufficient
oxygen delivered by the blood. Exercise-induced
angina pectoris (chest pain) occurs in many of
them. Among all patients with diagnosed CAD, the
predominant type of ischemia, as identified by ST
segment depression, is asymptomatic (i.e., silent).
Patients who experience angina typically have
additional ischemic episodes that are asymptomatic
(2000 AQCD, section 7.7.2.1). In addition to such
chronic conditions, CAD can lead to sudden
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Allred et al., 1989a, 1989b, 1991;
Anderson et al., 1973; Kleinman et al.,
1989, 1998; Sheps et al., 1987 15) are the
‘‘most compelling evidence of COinduced effects on the cardiovascular
system’’ (ISA, section 5.2). Additionally,
the use of an internal dose metric,
COHb, adds to the strength of the
findings in these controlled exposure
studies. As a group, these studies
demonstrate the role of short-term CO
exposures in increasing the
susceptibility of people with CAD to
incidents of exercise-associated
myocardial ischemia. Toxicological
studies described in the current review
provide evidence of CO effects on the
cardiovascular system, including
electrocardiographic effects of 1-hour
exposures to 35 ppm CO in a rat strain
developed as an animal model of
cardiac susceptibility (ISA, section
5.2.5.3).
Among the controlled human
exposure studies, the ISA places
principal emphasis on the study of CAD
patients by Allred et al. (1989a, 1989b,
1991) 16 (which was also considered in
the previous review) for the following
reasons: (1) Dose-response relationships
were observed; (2) effects were observed
at the lowest COHb levels tested (mean
of 2–2.4% COHb 17 following
experimental CO exposure), with no
evidence of a threshold; (3) objective
measures of myocardial ischemia (STsegment depression) 18 were assessed, as
episodes, such as myocardial infarction (ISA, p. 5–
24).
15 Statistical analyses of the data from Sheps et
al., (1987) by Bissette et al (1986) indicate a
significant decrease in time to onset of angina at
4.1% COHb if subjects that did not experience
exercise-induced angina during air exposure are
also included in the analyses.
16 Other controlled human exposure studies of
CAD patients (listed in Table 2–2 of the PA, and
discussed in more detail in the 1991 and 2000
AQCDs) similarly provide evidence of reduced time
to exercise-induced angina associated with elevated
COHb resulting from controlled short-duration
exposure to increased concentrations of CO.
17 These levels and other COHb levels described
for this study below are based on GC analysis
unless otherwise specified. Matched measurements
available for CO-oximetry (CO–Ox) and gas
chromatography (GC) in this study indicate CO–Ox
measurements of 2.65% (post-exercise mean) and
3.21% (post-exposure mean) corresponding to the
GC measurement levels of 2.00% (post-exercise
mean) to 2.38% (post-exposure mean) for the lower
exposure level assessed in this study (Allred et al.,
1991).
18 The ST-segment is a portion of the
electrocardiogram, depression of which is an
indication of insufficient oxygen supply to the heart
muscle tissue (myocardial ischemia). Myocardial
ischemia can result in chest pain (angina pectoris)
or such characteristic changes in ECGs or both. In
individuals with coronary artery disease, it tends to
occur at specific levels of exercise. The duration of
exercise required to demonstrate chest pain and/or
a 1-mm change in the ST segment of the ECG were
key measurements in the multicenter study by
Allred et al (1989a, 1989b, 1991).
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well as the subjective measure of
decreased time to induction of angina;
(4) measurements were taken both by
CO-oximetry (CO–Ox) and by gas
chromatography (GC), which provides a
more accurate measurement of COHb
blood levels 19; (5) a large number of
study subjects were used; (6) a strict
protocol for selection of study subjects
was employed to include only CAD
patients with reproducible exerciseinduced angina; and (7) the study was
conducted at multiple laboratories
around the U.S. This study evaluated
changes in time to exercise-induced
onset of markers of myocardial ischemia
resulting from two short (approximately
1-hour) CO exposures targeted to result
in mean study subject COHb levels of
2% and 4%, respectively (ISA, section
5.2.4). In this study, subjects (n=63) on
three separate occasions underwent an
initial graded exercise treadmill test,
followed by 50 to 70-minute exposures
under resting conditions to room air CO
concentrations or CO concentrations
targeted for each subject to achieve
blood COHb levels of 2% and 4%. The
exposures were to average CO
concentrations of 0.7 ppm (room air
concentration range 0–2 ppm), 117 ppm
(range 42–202 ppm) and 253 ppm (range
143–357 ppm). After the 50- to 70minute exposures, subjects underwent a
second graded exercise treadmill test,
and the percent change in time to onset
of angina and time to ST endpoint
between the first and second exercise
tests was determined. For the two CO
exposures, the average post-exposure
COHb concentrations were reported as
2.4% and 4.7%, and the subsequent
post-exercise average COHb
concentrations were reported as 2.0%
and 3.9%.20
19 As stated in the ISA, the gas chromatographic
technique for measuring COHb levels ‘‘is known to
be more accurate than spectrophotometric
measurements, particularly for samples containing
COHb concentrations < 5%’’ (ISA, p. 5–41). COoximetry is a spectrophotometric method
commonly used to rapidly provide approximate
concentrations of COHb during controlled
exposures (ISA, p. 5–41). At the low concentrations
of COHb (<5%) more relevant to ambient CO
exposures, co-oximeters are reported to
overestimate COHb levels compared to GC
measurements, while at higher concentrations, this
method is reported to produce underestimates (ISA,
p.4–18).
20 While the COHb blood level for each subject
during the exercise tests was intermediate between
the post-exposure and subsequent post-exercise
measurements (e.g., mean 2.4–2.0% and 4.7–3.9%),
the study authors noted that the measurements at
the end of the exercise test represented the COHb
concentrations at the approximate time of onset of
myocardial ischemia as indicated by angina and ST
segment changes. The corresponding ranges of CO–
Ox measurements for the two exposures were 2.7–
3.2% and 4.7–5.6%. In this document, we refer to
the GC-measured mean of 2.0% or 2.0–2.4% for the
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Across all subjects, the mean time to
angina onset for control (‘‘room’’ air)
exposures was approximately 8.5
minutes, and the mean time to ST
endpoint was approximately 9.5
minutes (Allred et al., 1989b). Relative
to room-air exposure that resulted in a
mean COHb level of 0.6% (postexercise), exposure to CO resulting in
post-exercise mean COHb
concentrations of 2.0% and 3.9% were
observed to decrease the exercise time
required to induce ST-segment
depression by 5.1% (p=0.01) and 12.1%
(p<0.001), respectively. These changes
were well correlated with the onset of
exercise-induced angina, the time to
which was shortened by 4.2% (p=0.027)
and 7.1% (p=0.002), respectively, for
the two experimental CO exposures
(Allred et al., 1989a, 1989b, 1991).21 As
at the time of the last review, while STsegment depression is recognized as an
indicator of myocardial ischemia, the
exact physiological significance of the
observed changes among those with
CAD is unclear (ISA, p. 5–48).
No controlled human exposure
studies have been specifically designed
to evaluate the effect of controlled shortterm exposures to CO resulting in COHb
levels lower than a study mean of 2%
(ISA, section 5.2.6). However, an
important finding of the multilaboratory study was the dose-response
relationship observed between COHb
and the markers of myocardial ischemia,
with effects observed at the lowest
increases in COHb tested, without
evidence of a measurable threshold
effect. As reported by the authors, the
results comparing ‘‘the effects of
increasing COHb from baseline levels
(0.6%) to 2 and 3.9% COHb showed that
each produced further changes in
objective ECG measures of ischemia’’
implying that ‘‘small increments in
COHb could adversely affect myocardial
function and produce ischemia’’ (Allred
et al., 1989b, 1991).
The epidemiological evidence has
expanded considerably since the last
review including numerous additional
studies that are coherent with the
evidence on markers of myocardial
COHb levels resulting from the lower experimental
CO exposure.
21 Another indicator measured in the study was
the combination of heart rate and systolic blood
pressure which provides a clinical index of the
work of the heart and myocardial oxygen
consumption, since heart rate and blood pressure
are major determinants of myocardial oxygen
consumption (Allred et al., 1991). A decrease in
oxygen to the myocardium would be expected to be
paralleled by ischemia at lower heart rate and
systolic blood pressure. This heart rate-systolic
blood pressure indicator at the time to ST-endpoint
was decreased by 4.4% at the 3.9% COHb dose
level and by a nonstatistically-significant, smaller
amount at the 2.0% COHb dose level.
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ischemia from controlled human
exposure studies of CAD patients (ISA,
section 2.7). The most recent set of
epidemiological studies in the U.S. have
evaluated the associations between
ambient concentrations of multiple
pollutants (i.e. fine particles or PM2.5,
nitrogen dioxide, sulfur dioxide, ozone,
and CO) at fixed-site ambient monitors
and increases in emergency department
visits and hospital admissions for
specific cardiovascular health outcomes
including ischemic heart disease (IHD),
myocardial infarction (MI), congestive
heart failure (CHF), and cardiovascular
diseases (CVD) as a whole (Bell et al.,
2009; Koken et al., 2003; Linn et al.,
2000; Mann et al., 2002; Metzger et al.,
2004; Symons et al., 2006; Tolbert et al.,
2007; Wellenius et al., 2005). Findings
of positive associations for these
outcomes with metrics of ambient CO
concentrations are coherent with the
evidence from controlled human
exposure studies of myocardial
ischemia-related effects resulting from
elevated CO exposures (ISA, section
2.5.1; ISA, Figure 2–1). In these studies,
the ambient CO concentration averaging
time for which health outcomes were
analyzed varied from 1 hour to 24
hours, with the air quality metrics based
on either a selected central-site monitor
for the area or an average for multiple
monitors in the area of interest. The
study areas for which positive
associations of these metrics were
reported with IHD, MI and CVD
outcomes include: the Atlanta, Georgia
metropolitan statistical area; the greater
Los Angeles, California area; and a
group of 126 urban counties. Together
the individual study periods spanned
the years from 1988 through 2005. The
risk estimates from these studies
indicate statistically significant positive
associations were observed with
ambient CO concentrations based on air
quality for the day of hospital admission
or based on the average of the selected
ambient CO concentration metric across
that day and 2 or 3 days previous (ISA,
Figures 5–2 and 5–5). Many of the
studies for these outcomes include same
day or next day lag periods, which, as
noted in the ISA ‘‘are consistent with the
proposed mechanism and biological
plausibility of these CVD outcomes’’
(ISA, p. 5–40).22
Additionally, there are U.S. studies
reporting associations with hospital
admissions for CHF, a condition that
affects an individual’s ability to
22 Of the studies for which risk estimates are
based on multi-day averages (the Atlanta studies
and the California study by Mann et al., 2002), the
California study by Mann et al., (2002) also
observed a significant positive association with
same day CO concentration.
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compensate for reduced oxygen
availability. These include one in
southern California which reported a
significant association for ambient CO
with hospital admissions for CHF (Linn
et al., 2000), as well as studies in
Allegheny County (Pittsburgh) for
1987–1999 study period (Wellenius et
al., 2005), and Denver for the months of
July-August during 1993–1997 (Koken
et al., 2003; ISA, pp. 5–31 to 5–33). Risk
estimates for all three of these studies
are based on the 24-hour CO
concentration, with the California and
Allegheny County studies’ association
with same-day air quality, while the
association shown for the Denver study
was with ambient CO concentration
three days prior to health outcome (PA,
Table 2–1).
As noted by the ISA, ‘‘[s]tudies of
hospital admissions and ED visits for
IHD provide the strongest
[epidemiological] evidence of ambient
CO being associated with adverse CVD
outcomes’’ (ISA, p. 5–40, section 5.2.3).
With regard to studies for other
measures of cardiovascular morbidity,
the ISA notes that ‘‘[t]hough not as
consistent as the IHD effects, the effects
for all CVD hospital admissions (which
include IHD admissions) and CHF
hospital admissions also provide
evidence for an association of
cardiovascular outcomes and ambient
CO concentrations’’ (ISA, section 5.2.3).
While noting the difficulty in
determining the extent to which CO is
independently associated with CVD
outcomes in this group of studies as
compared to CO as a marker for the
effects of another traffic-related
pollutant or mix of pollutants, the ISA
concludes that the epidemiological
evidence, particularly when considering
the copollutant analyses, provides
support to the clinical evidence for a
direct effect of short-term ambient CO
exposure on CVD morbidity (ISA, pp.
5–40 to 5–41).
As discussed in detail in the ISA,
additional epidemiological studies have
evaluated associations of ambient CO
with other cardiovascular effects since
the last review. For example,
preliminary evidence of a link between
exposure to CO and alteration of blood
markers of coagulation and
inflammation in individuals with CAD
or CVD has been provided by a few well
conducted and informative studies (ISA,
Table 5–6; Delfino et al., 2008; Liao et
al., 2005). As noted by the ISA,
however, further studies are warranted
to investigate the role of these markers
in prothrombotic events and their
possible contribution to the
pathophysiology of CO-induced
aggravation of ischemic heart disease
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(ISA, section 5.2.1.8). Other
epidemiological studies (including field
and panel studies) also provide some
evidence of a link between CO exposure
and heart rate and heart rate variability
(ISA, section 5.2.1.1). With regard to the
two of three studies reporting a positive
association with heart rate, the ISA
concluded that ‘‘further research is
warranted’’ to corroborate the results,
while the larger number of studies for
heart rate variability parameters is
characterized as having mixed
associations (ISA, p. 5–15).
Additionally, of the two studies of
electrocardiogram changes indicative of
ischemic events (ISA, section 5.2.1.2),
one found no association and, in the
other study, the association with CO did
not remain statistically significant in
multipollutant models, unlike the
association with black carbon in that
study (ISA, p. 5–16). A limited number
of epidemiological studies (Bell et al.,
2009; Linn et al., 2000) have
investigated hospital admissions for
stroke (including both hemorrhagic and
ischemic forms) and generally report
small or no associations with ambient
CO concentrations (ISA, section 5.2.1.9,
Table 5–8 and Figure 5–3).
At the time of the last review, there
was evidence for effects other than
cardiovascular morbidity, including
neurological, respiratory and
developmental effects. Evidence for
these effects includes the following.
• With regard to neurological effects,
acute exposures to CO have long been
known to induce CNS effects such as
those observed with CO poisoning,
although limited and equivocal
evidence available at the time of the last
review included indications of some
neurobehavioral effects to result from
CO exposures resulting in a range of
5–20% COHb (2000 AQCD, section
6.3.2). No additional clinical or
epidemiological studies are now
available that investigated such effects
of CO at ambient levels (ISA, section
5.3).
• With regard to potential effects of
CO on birth outcomes and
developmental effects, the potential
vulnerability of the fetus and very
young infant to CO was recognized
during the 1994 review and in the 2000
AQCD. The CO-specific evidence
available, however, included limited
epidemiological analyses focused
primarily on very high CO exposures
associated with maternal smoking, and
animal studies involving very high CO
exposures (USEPA, 1992; 2000 AQCD).
The 2000 AQCD concluded that typical
ambient CO levels were unlikely to
cause increased fetal risk (2000 AQCD,
p. 6–44). The current review includes
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additional epidemiological and animal
toxicological studies. The currently
available evidence includes limited but
suggestive epidemiologic evidence for a
CO-induced effect on preterm-birth,
birth defects, decrease in birth weight,
other measures of fetal growth, and
infant mortality (ISA, section 5.4.3). The
available animal toxicological studies
provide some support and coherence for
these birth and developmental outcomes
at higher than ambient exposures,23
although a clear understanding of the
mechanisms underlying potential
reproductive and developmental effects
is still lacking (ISA, section 2.5.3).
• With regard to respiratory effects,
the 2000 AQCD concluded it unlikely
that CO has direct effects on lung tissue,
except at extremely high concentrations
(2000 AQCD, p. 6–45). There is
currently limited, suggestive evidence of
an association between short-term
exposure to CO and respiratory-related
outcomes. Only preliminary evidence is
available, however, regarding a
mechanism that could provide
plausibility for
CO-induced effects (ISA, section
5.5.5.1).
Thus, while there is some additional
evidence on neurological, respiratory
and developmental effects, it remains
limited.
In summary, rather than altering
conclusions from the previous review,
the current evidence provides continued
support and some additional strength to
the previous conclusions regarding the
health effects associated with exposure
to CO and continues to indicate
cardiovascular effects, particularly
effects related to the role of CO in
limiting oxygen availability, as those of
greatest concern at low exposures.
3. At-Risk Populations
In identifying population groups or
life stages at greatest risk for health risk
from a specific pollutant, the terms
susceptibility, vulnerability, sensitivity,
and at-risk are commonly employed.
The definition for these terms
sometimes varies, but in most instances
‘‘susceptibility’’ refers to biological or
intrinsic factors (e.g., lifestage, gender)
while ‘‘vulnerability’’ refers to
nonbiological or extrinsic factors (e.g.,
visiting a high-altitude location,
medication use). Additionally, in some
cases, the terms ‘‘at-risk’’ and sensitive
have been used to encompass both of
these concepts. At times, however,
factors of ‘‘susceptibility’’ and
23 The lowest exposures eliciting an effect in the
animal studies were exposures of 22 hours per day
over about 14 prenatal days at a concentration of
12 ppm (ISA, Table 5–17).
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‘‘vulnerability’’ are intertwined and are
difficult to distinguish. In the ISA for
this review, the term susceptibility has
been used broadly to recognize
populations that have a greater
likelihood of experiencing effects
related to ambient CO exposure, such
that use of the term susceptible
populations in the ISA is defined as
follows (ISA, section 5.7, p. 5–115):
Populations that have a greater likelihood
of experiencing health effects related to
exposure to an air pollutant (e.g., CO) due to
a variety of factors including, but not limited
to: genetic or developmental factors, race,
gender, lifestage, lifestyle (e.g., smoking
status and nutrition) or preexisting disease,
as well as population-level factors that can
increase an individual’s exposure to an air
pollutant (e.g., CO) such as socioeconomic
status [SES], which encompasses reduced
access to health care, low educational
attainment, residential location, and other
factors
Thus, susceptible populations are at
greater risk of CO effects and are also
referred to as at-risk in the
corresponding discussion in the REA
and Policy Assessment and the
summary below.
The current evidence, while much
expanded in a number of ways,
continues to support the conclusions
from the previous review regarding
susceptible populations for exposure to
ambient CO. In the AQCD for the review
completed in 1994 and in the 2000
AQCD, the evidence best supported the
identification of patients with CAD as a
population at increased risk from low
levels of CO (USEPA, 1992; 2000
AQCD). Other groups were also
recognized as potentially susceptible in
the 2000 AQCD based on consideration
of the clinical evidence and theoretical
work, as well as laboratory animal
research (2000 AQCD, p. 7–6). These
include fetuses and young infants;
pregnant women; the elderly, especially
those with compromised cardiovascular
function; people with conditions
affecting oxygen absorption, blood flow,
oxygen carrying capacity or transport;
people using drugs with central nervous
system depressant properties or exposed
to chemical substances that increase
endogenous formation of CO; and
people who have not adapted to high
altitude and are exposed to a
combination of high altitude and CO.
For these potentially susceptible groups,
little empirical evidence was available
by which to specify health effects
associated with ambient or near-ambient
CO exposures (2000 AQCD, p. 7–6).
As summarized in the Policy
Assessment, based on the evidence from
controlled human exposure studies also
considered in the last review, and the
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now much-expanded epidemiological
evidence base which is coherent with
the evidence from these studies, the
population with pre-existing
cardiovascular disease associated with
limitation in oxygen availability
continues to be the best characterized
population at risk of adverse COinduced effects, with CAD recognized as
‘‘the most important susceptibility
characteristic for increased risk due to
CO exposure’’ (ISA, section 2.6.1). An
important factor determining the
increased susceptibility of this
population is their inability to
compensate for the reduction in oxygen
levels due to an already compromised
cardiovascular system. Individuals with
a healthy cardiovascular system (i.e.,
with healthy coronary arteries) have
operative physiologic compensatory
mechanisms (e.g., increased blood flow
and oxygen extraction) for CO-induced
hypoxia and are unlikely to be at
increased risk of CO-induced effects
(ISA, p. 2–10).24 In addition, the high
oxygen consumption of the heart,
together with the inability to
compensate for the hypoxic effects of
CO, make the cardiac muscle of a person
suffering with CAD a critical target for
the hypoxic effects of CO.
In the Integrated Science Assessment
for the current review, recognition of
susceptibility of the population with
pre-existing cardiovascular disease,
such as CAD, is supported by the
expanded epidemiological database,
which includes a number of studies
reporting significant increases in
hospital admissions for IHD, angina and
MI in relation to CO exposures (ISA,
section 2.7). Further support is provided
by epidemiologic studies (Mann et al.,
2002; and Peel et al., 2007) of increased
hospital admissions and emergency
department visits for IHD among
individuals with secondary diagnoses
for other cardiovascular outcomes
including arrhythmia and congestive
heart failure (ISA, section 5.7), and
toxicological studies reporting altered
cardiac outcomes in animal models of
cardiovascular disease (ISA, section
5.2.1.9).
Cardiovascular disease comprises
many types of medical disorders,
including heart disease, cerebrovascular
disease (e.g., stroke), hypertension (high
blood pressure), and peripheral vascular
24 The other well-studied individuals at the time
of the last review were healthy male adults that
experienced decreased exercise duration at similar
COHb levels during short term maximal exercise.
This population was of lesser concern since it
represented a smaller sensitive group, and
potentially limited to individuals that would engage
in vigorous exercise such as competing athletes
(1991 AQCD, section 10.3.2).
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diseases. Heart disease, in turn,
comprises several types of disorders,
including ischemic heart disease (CHD
or CAD, myocardial infarction, angina),
congestive heart failure, and
disturbances in cardiac rhythm (2000
AQCD, section 7.7.2.1). Types of
cardiovascular disease other than those
discussed above may also contribute to
increased susceptibility to the adverse
effects of low levels of CO (ISA, section
5.7.1.1). For example, some evidence
with regard to other types of
cardiovascular disease such as
congestive heart failure, arrhythmia, and
non-specific cardiovascular disease,
although more limited for peripheral
vascular and cerebrovascular disease,
indicates that ‘‘the continuous nature of
the progression of CAD and its close
relationship with other forms of
cardiovascular disease suggest that a
larger population than just those
individuals with a prior diagnosis of
CAD may be susceptible to health
effects from CO exposure’’ (ISA, p. 5–
117).
Although there were little
experimental data available at the time
of the last review to adequately
characterize specific health effects of CO
at ambient levels for other potentially
at-risk populations, several other
populations were identified as being
potentially more at risk of CO-induced
effects due to a number of factors. These
factors include pre-existing diseases that
could inherently decrease oxygen
availability to tissues, lifestage
vulnerabilities (e.g., fetuses, young
infants or newborns, the elderly),
gender, lifestyle, medications or
alterations in the physical environment
(e.g., increased altitude). This is
consistent with the ISA conclusions in
the current review which recognize
other populations that may be
potentially susceptible to the effects of
CO as including: Those with other preexisting diseases that may have already
limited oxygen availability or increased
COHb production or levels, such as
people with obstructive lung diseases,
diabetes and anemia; older adults;
fetuses during critical phases of
development and young infants or
newborns; those who spend a
substantial time on or near heavily
traveled roadways; visitors to highaltitude locations; and people ingesting
medications and other substances that
enhance endogenous or metabolic CO
formation (ISA, section 2.6.1). In
recognizing the potential susceptibility
of these populations, the Policy
Assessment also noted the lack of
information on specific COHb levels
that may be associated with health
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effects in these other groups and the
nature of those effects, as well as a way
to relate the specific evidence available
for the CAD population to these other
populations (PA, section 2.2.1).
The current evidence continues to
support the identification of people
with cardiovascular disease as having
susceptibility to CO-induced health
effects (ISA, 2–12), with those having
CAD as the population with the best
characterized susceptibility to COinduced health effects (ISA, sections
5.7.1.1 and 5.7.8).25 An important
susceptibility consideration for this
population is the inability to
compensate for CO-induced hypoxia
since individuals with CAD have an
already compromised cardiovascular
system. Included in this susceptible
population are those with angina
pectoris (cardiac chest pain), those who
have experienced a heart attack, and
those with silent ischemia or
undiagnosed IHD (AHA, 2003). People
with other cardiovascular diseases,
particularly heart diseases, are also at
risk of CO-induced health effects. We
also recognize other populations
potentially susceptible to CO-induced
effects, most particularly those with
other pre-existing diseases that cause
limited oxygen availability, increased
COHb levels, or increased endogenous
CO production, such as people with
obstructive lung diseases, diabetes and
anemia; however, information
characterizing susceptibility for this
population is limited.
4. Potential Impacts on Public Health
In light of the evidence described
above with regard to factors contributing
to greater susceptibility to health effects
of ambient CO, this section, drawing
from the Integrated Science Assessment
and discussion in the Policy
Assessment, discusses the health
significance of the effects occurring with
the lowest relevant (short-term)
exposures to ambient CO and the size of
the at-risk populations in the U.S. These
considerations are important elements
in the characterization of potential
public health impacts associated with
exposure to ambient CO.
We first consider the effects identified
by the evidence at the lowest studied
short-term exposures. As discussed in
section II.B.2 above, the study by Allred
et al., (1989a, 1989b, 1991) indicates
that increases in blood COHb in
response to 1-hour CO exposures
25 As recognized in the ISA, ‘‘Although the weight
of evidence varies depending on the factor being
evaluated, the clearest evidence indicates that
individuals with CAD are most susceptible to an
increase in CO-induced health effects’’ (ISA, p. 2–
12).
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produce evidence of myocardial
ischemia in CAD patients with
reproducible exercise-induced angina.
At a study group average COHb level of
2–2.4%, the statistically significant
reduction in the time to exerciseinduced markers of myocardial
ischemia in CAD patients was 4–5% on
average (approximately 30 seconds),
with larger reductions observed at the
higher studied COHb level. In
discussing public health implications of
the observed responses, the study
authors noted that the responses
observed at the studied COHb levels
were similar to those considered
clinically significant when evaluating
medications to treat angina from
coronary artery disease (Allred et al.,
1989a, 1991). The independent review
panel for the study further noted that
frequent encounters in ‘‘everyday life’’
with increased COHb levels on the order
of those tested in the study might be
expected to limit activity and affect
quality of life (Allred et al., 1989b, pp.
38, 92–94; 1991 AQCD, p. 10–35).
In the review completed in 1994, the
body of evidence that demonstrated
cardiovascular effects in CAD patients
exposed to CO was given primary
consideration, with the Administrator
judging that ‘‘cardiovascular effects, as
measured by decreased time to onset of
angina pain and by decreased time to
onset of significant ST-segment
depression, are the health effects of
greatest concern, which clearly have
been associated with CO exposures at
levels observed in the ambient air’’ (59
FR 38913). Additionally, as discussed in
section II.B.2 above, a dose-response
relationship has been documented for
COHb resulting from brief, elevated CO
exposures in persons with pre-existing
CAD, with no evidence of threshold (59
FR 38910; ISA, section 5.2.4; Allred et
al., 1989a, 1989b, 1991).
In the 1994 review decision (as
discussed in section II.D.1.a below), less
significance was ascribed to the effects
at the lower COHb level assessed in the
Allred et al., study (1989a, 1989b, 1991),
which were described to be of less
certain clinical importance, than effects
reported from short-term CO exposure
studies that assessed higher COHb
levels (59 FR 38913–38914). In the
current review of the evidence, the ISA
describes the physiological significance
of the changes at the lowest tested dose
level (e.g., 2% COHb from Allred et al.,
1989b) as unclear, additionally noting
that variability in severity of disease
among individuals with CAD is likely to
influence the critical level of COHb
which leads to adverse cardiovascular
effects (ISA, p. 2–6).
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In considering potential public health
impacts of CO in ambient air, we also
consider the size of the at-risk
populations. The population with CAD
is well recognized as susceptible to
increased risk of CO-induced health
effects (ISA, sections 5.7.1.1 and 5.7.8).
The 2007 estimate from the National
Health Interview Survey (NHIS)
performed by the U.S. Centers for
Disease Control of the size of the U.S.
population with coronary heart disease,
angina pectoris (cardiac chest pain) or
who have experienced a heart attack
(ISA, Table 5–26) is 13.7 million people
(ISA, pp. 5–117). Further, there are
estimated to be three to four million
additional people with silent ischemia
or undiagnosed IHD (AHA, 2003). In
combination, this represents a large
population that is more susceptible to
ambient CO exposure when compared
to the general population (ISA, section
5.7).
In addition to the population with
diagnosed and undiagnosed CAD, the
ISA notes the size of the larger
population of people with all types of
heart disease (HD), which may also be
at increased risk of CO-induced health
effects (ISA, section 2.6.1). Within this
broader group, implications of CO
exposures are more significant for those
persons for whom their disease state
affects their ability to compensate for
the hypoxia-related effects of CO (ISA,
section 4.4.4). The NHIS estimates for
2007 indicate there is a total of
approximately 25 million people with
heart disease of any type (ISA, Table 5–
26).
Other populations potentially
susceptible to the effects of CO include
people with chronic obstructive
pulmonary disease, diabetes and
anemia, as well as older adults and
fetuses during critical phases of
development (as discussed in section
II.B.3 above). In considering potential
impacts on such populations, we
recognize that the evidence is limited or
lacking with regard to effects of CO at
ambient levels, and associated
exposures and COHb levels, while
providing no indication of susceptibility
to ambient CO greater than that of CHD
and HD populations.
C. Human Exposure and Dose
Assessment
Our consideration of the scientific
evidence in the current review, as at the
time of the last review (summarized in
section II.D.1 below), is informed by
results from a quantitative analysis of
estimated population exposure and
resultant COHb levels. This analysis
provides estimates of the percentages of
simulated at-risk populations expected
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to experience daily maximum COHb
levels at or above a range of benchmark
levels under varying air quality
scenarios (e.g., just meeting the current
or alternative standards). The
benchmark COHb levels were identified
based on consideration of the evidence
discussed in section II.B above. The
following subsections summarize the
design and methods of the quantitative
assessment (section II.C.1) and the
important uncertainties associated with
these analyses (section II.C.2). The
results of the analyses, as they relate to
considerations of the adequacy of the
current standards, are discussed in
section II.D.2 below.
1. Summary of Design Aspects
In this section, we provide a summary
of key aspects of the assessment
conducted for this review, including the
study areas and air quality scenarios
investigated, modeling tools used, atrisk populations simulated, and COHb
benchmark levels of interest. The
assessment is described in detail in the
REA and summarized in the PA (section
2.2.2).
The assessment estimated CO
exposure and associated COHb levels in
simulated at-risk populations in two
urban study areas in Denver and Los
Angeles, in which current ambient CO
concentrations are below the current
standards. We selected these areas
because: (1) Areas of both cities have
been included in prior CO NAAQS
exposure assessments and thus serve as
an important connection with past
assessments; (2) historically, they have
generally had the highest ambient CO
concentrations among urban areas in the
U.S.; and (3) Denver is at high altitude
and represents an important risk
scenario due to the potential increased
susceptibility to CO exposure associated
with high altitudes. In addition, of 10
urban areas across the continental U.S.
selected for detailed air quality analysis
in the ISA and having ambient monitors
meeting a 75% completeness criterion,
the two study area locations were
ranked first (Los Angeles) and second
(Denver) regarding the percentage of
elderly population within 5, 10, and 15
km of monitor locations, and ranked
first (Los Angeles) and fifth (Denver)
regarding number of 1- and 8-hour daily
maximum CO concentration
measurements (ISA, section 3.5.1.1).
Estimates were developed for
exposures to ambient CO associated
with current ‘‘as is’’ conditions (2006 air
quality) and also for higher ambient CO
concentrations associated with air
quality conditions simulated to just
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meet the current 8-hour standard,26 as
well as for air quality conditions
simulated to just meet several
alternative standards. Although we
consider it unlikely that air
concentrations in many urban areas
across the U.S. that are currently well
below the current standards would
increase to just meet the 8-hour
standard, we recognize the potential for
CO concentrations in some areas
currently below the standard to increase
to just meet the standard. We
additionally recognize that this
simulation can provide useful
information in evaluating the current
standard. Accordingly, we simulated
conditions of increased CO
concentrations that just meet the current
8-hour standard in the two study areas.
In so doing, we recognize the
uncertainty associated with simulating
this hypothetical profile of higher CO
concentrations that just meet the current
8-hour standard. We note, however, that
an analysis of the ratios of 1-hour to 8hour design value metrics based on
2009 ambient CO concentrations in U.S.
locations indicates that the relationships
between design values for the two study
areas under the air quality conditions
simulated to just meet the current 8hour standard fall well within the 2009
national distribution of such ratios
(Policy Assessment, section 2.2.2).27
The exposure and dose modeling for
the assessment, presented in detail in
the REA, relied on version 4.3 of EPA’s
Air Pollutant Exposure model
(APEX4.3), which estimates human
exposure using a stochastic, event-based
microenvironmental approach (REA,
chapter 4). This model has a history of
application, evaluation, and progressive
model development in estimating
human exposure and dose for several
NAAQS reviews, including CO, ozone
(O3), nitrogen dioxide (NO2), and sulfur
dioxide (SO2). As described in section
II.D.1 below, the review of the CO
standards completed in 1994 relied on
population exposure and dose estimates
generated from the probabilistic NAAQS
exposure model (pNEM), a model that,
among other differences from the
current modeling approach with
APEX4.3, employed a cohort-based
approach (Johnson et al., 1992; U.S.
26 As noted elsewhere, the 8-hour standard is the
controlling standard for ambient CO concentrations.
27 More specifically, the ratio of the 1-hour design
value to the 8-hour design value for the Los Angeles
study area corresponds to approximately the 25th
percentile of U.S. counties in 2009 and the ratio for
the Denver study area corresponds to approximately
the 75th percentile of U.S. counties in 2009. Under
‘‘as is’’ conditions the ratios for these two study
areas correspond to approximately the 40th
percentile of the 2009 national distribution (Policy
Assessment, section 2.2.2).
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EPA, 1992).28 29 Each of the model
developments since the use of pNEM in
that review have been designed to allow
APEX to better represent human
behavior, human physiology, and
microenvironmental concentrations and
to more accurately estimate variability
in CO exposures and COHb levels (REA,
chapter 4).30
As used in the current assessment,
APEX probabilistically generates a
sample of hypothetical individuals from
an actual population database and
simulates each individual’s movements
through time and space (e.g., indoors at
home, inside vehicles) to estimate his or
her exposure to ambient CO (REA,
chapter 4). The individual’s movements
are simulated based on data available
from recent activity pattern surveys
(CHAD 31 now has about 34,000 persondays of data) and the most recent U.S.
census data on population
demographics and home-to-workplace
commutes. Based on exposure
concentrations, minute-by-minute
activity levels, and physiological
characteristics of the simulated
individuals (see REA, chapters 4 and 5),
APEX estimates the level of COHb in the
blood for each individual at the end of
each hour based on a nonlinear solution
to the Coburn-Forster-Kane equation
(REA, section 4.4.7). These results
across each simulated individual were
then summarized in the REA and
28 When using the cohort approach, each cohort
is assumed to contain persons with identical
exposures during the specified exposure period.
Thus, variability in exposure will be attributed to
differences in how the cohorts are defined, not
necessarily reflecting differences in how
individuals might be exposed in a population. In
the assessment for the review completed in 1994,
a total of 420 cohorts were used to estimate
population exposure based on selected
demographic information (11 groups using age,
gender, work status), residential location, work
location, and presence of indoor gas stoves
(Johnson, et al., 1992; USEPA, 1992).
29 The use of pNEM in the prior review also (1)
relied on a limited set of activity pattern data
(approximately 3,600 person-days), (2) used four
broadly defined categories to estimate breathing
rates, and (3) implemented a geodesic distance
range methodology to approximate workplace
commutes (Johnson et al., 1992; U.S. EPA, 1992).
Each of these approaches used by pNEM, while
appropriate given the data available at that time,
would tend to limit the ability to accurately model
expected variability in the population exposure and
dose distributions.
30 APEX4.3 includes new algorithms to (1)
simulate longitudinal activity sequences and
exposure profiles for individuals, (2) estimate
activity-specific minute-by-minute oxygen
consumption and breathing rates, (3) address spatial
variability in home and work-tract ambient
concentrations for commuters, and (4) estimate
event-based microenvironmental concentrations
(PA, section 2.2.2).
31 CHAD is EPA’s Comprehensive Human
Activity Database which provides input data for
APEX model simulations (REA, sections 4.3 and
4.4).
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discussed in the Policy Assessment in
terms of the percent of the simulated atrisk populations expected to experience
one or more occurrences of daily
maximum end-of-hour COHb levels of
interest.
As discussed in section II.B above,
people with cardiovascular disease are
the population of primary focus in this
review, and more specifically, as
described in the ISA, coronary artery
disease, also known as coronary heart
disease, is the ‘‘most important
susceptibility characteristic for
increased risk due to CO exposure’’
(ISA, p. 2–11). Controlled human
exposure studies have provided
quantitative COHb dose-response
information for this specific population
with regard to effects on markers of
myocardial ischemia. Accordingly,
based on the current evidence with
regard to quantitative information of
COHb levels and association with
specific health effects, the at-risk
populations simulated in the
quantitative assessment were (1) adults
with CHD (also known as ischemic heart
disease [IHD] or CAD), both diagnosed
and undiagnosed, and (2) adults with
any heart diseases, including
undiagnosed ischemia.32 Evidence
characterizing the nature of specific
health effects of CO in other populations
is limited and does not include specific
COHb levels related to health effects in
those groups. As a result, the
quantitative assessment does not
develop separate quantitative dose
estimates for populations other than
those with CHD or HD.
In representing the two at-risk
populations and their activity patterns,
individuals were simulated based on
age and gender distributions for CHD
and HD populations. These
distributions were developed by
augmenting the prevalence estimates
provided by the National Health
Interview Survey for adults with CAD
and adults with heart diseases of any
type (HD) with estimates of
undiagnosed ischemia (as described in
section 5.5.1 of the REA). The
undiagnosed ischemia estimates were
developed based on two assumptions:
(1) There are 3.5 million persons in U.S.
with undiagnosed IHD (AHA, 2003) and
(2) persons with undiagnosed IHD are
distributed within the population in the
same manner as persons with diagnosed
IHD (REA, section 5.5.1).
APEX simulations performed for this
review focused on exposures to ambient
32 As described in section 1.2 above, this is the
same population group that was the focus of the CO
NAAQS exposure/dose assessments conducted
previously (e.g., USEPA, 1992; Johnson et al., 2000).
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CO occurring in eight
microenvironments,33 absent any
contribution to microenvironment
concentrations from indoor
(nonambient) CO sources. As noted in
section II.B.1 above, however, where
present, indoor sources, including gas
stoves, attached garages and tobacco
smoke, can also be important
contributors to total CO exposure (ISA,
sections 3.6.1 and 3.6.5). Previous
assessments, that have included
modeling simulations both with and
without certain indoor sources,
indicated that the impact of such
sources can be substantial with regard to
the portion of the at-risk population
experiencing higher exposures and
COHb levels (Johnson et al., 2000).
While we are limited with regard to
information regarding CO emissions
from indoor sources today and how they
may differ from the time of the 2000
assessment, we note that ambient
contributions have notably declined,
and indoor source contributions from
some sources may also have declined.
Thus, as indicated in the Policy
Assessment, we have no firm basis to
conclude a different role for indoor
sources today with regard to
contribution to population CO exposure
and COHb levels.
The REA developed COHb estimates
for the simulated at-risk populations
with attention to both COHb in absolute
terms and in terms of the contribution
to absolute levels associated with
ambient CO exposures. Absolute COHb
refers to the REA estimates of COHb
levels resulting from endogenously
produced CO and exposure to ambient
CO (in the absence of any nonambient
sources). The additional REA estimates
of ambient CO exposure contribution to
COHb levels were calculated by
subtracting COHb estimates obtained in
the absence of CO exposure—i.e., that
due to endogenous CO production alone
(see REA, Appendix B.6)—from the
corresponding end-of-hour absolute
COHb estimates for each simulated
individual. Thus, the REA reports
estimates of the maximum end-of-hour
ambient contributions across the
simulated year, in addition to the
maximum absolute end-of hour COHb
levels.
As discussed in the Policy
Assessment (section 2.2.2), the absence
of indoor (nonambient) sources in the
REA simulations is expected to result in
33 The 8 microenvironments modeled in the REA
comprised a range of indoor and outdoor locations
including residences as well as motor vehiclerelated locations such as inside vehicles, and public
parking and fueling facilities, where the highest
exposures were estimated (REA, sections 5.9 and
6.1).
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simulated individuals with somewhat
higher estimates of the contribution of
short-duration increases in ambient CO
exposure to COHb levels (ambient
contribution) than would be expected
for individuals in situations where the
presence of nonambient sources
contributes to higher baseline COHb
levels (i.e., COHb prior to a shortduration exposure event). The amount
by which the ambient contribution
estimates might differ is influenced by
the magnitude of nonambient-source
exposures and associated baseline
COHb levels. One reason for this is that
in the presence of indoor sources,
baseline COHb levels will be higher for
a given population group than COHb
levels for that group arising solely from
endogenous CO in the absence of any
exposure, which is the ‘‘baseline’’ for the
REA estimates of ambient contribution
to COHb (REA, appendix B.6).34 As CO
uptake depends in part on the amount
of CO already present in the blood (and
the blood-air CO concentration
gradient), in general, a higher baseline
COHb, with all other variables
unchanged, will lead to relatively lesser
uptake of CO from short-duration
exposures (ISA, section 4.3; AQCD,
section 5.2). Additionally, as is
indicated by the REA estimates, the
attainment of a particular dose level is
driven largely by short-term (and often
high concentration) exposure events.
This is because of the relatively rapid
uptake of CO into a person’s blood, as
demonstrated by the pattern in the REA
time-series of ambient concentrations,
microenvironmental exposures, and
COHb levels (REA, Appendix B, Figure
B–2). For example the time lag for
response of an individual’s COHb levels
to variable ambient CO (and hence
exposure) concentrations may be only a
few hours (e.g., REA, Figure B–2).
In considering the REA dose estimates
in the Policy Assessment, as described
in section II.D.2 below, staff considered
estimates of the portion of the simulated
at-risk populations estimated to
experience daily maximum end-of-hour
absolute COHb levels above identified
34 As they result only from endogenous CO
formation, the REA ‘‘baseline’’ COHb levels would
also be expected to be, and generally are, lower than
the initial, pre-exposure, COHb levels of subjects in
the controlled exposure studies. REA estimates of
endogenously formed COHb averaged about 0.3%
across the simulated populations, with slightly
higher levels in the higher altitude Denver study
area (REA, pp. B–21 to B–22). Levels in the Denver
study population ranged from 0.1 to 1.1% COHb,
with an average of 0.31%, while levels for Los
Angeles ranged from 0.1 to 0.7% with an average
of 0.27% COHb. Initial, pre-exposure COHb levels
in the subjects of the Allred et al. study (1989b),
which reflect the subjects pre-study exposure
history as well as endogenous CO formation, ranged
from 0.2 to 1.1%, averaging about 0.6% COHb.
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benchmark levels (at least once and on
multiple occasions), as well as estimates
of the percentage of population persondays (the only metric available from the
modeling for the 1994 review), and also
population estimates of daily maximum
ambient contribution to end-of-hour
COHb levels. In identifying COHb
benchmark levels of interest, primary
attention was given to the multilaboratory study in which COHb was
analyzed by the more accurate GC
method (Allred et al., 1989a, 1989b,
1991) discussed in section II.B.2 above.
The REA identified a series of
benchmark levels for considering
estimates of absolute COHb: 1.5%,
2.0%, 2.5% and 3% COHb (REA,
section 2.6). This range includes the
range of COHb levels identified as levels
of concern in the review completed in
1994 (2.0 to 2.9%) and the level given
particular focus (2.1%) at that time, as
described in section 2.1.1 above
(USEPA, 1992; 59 FR 48914). Selection
of this range of benchmark levels is
based on consideration of the evidence
from controlled human exposure studies
of subjects with CAD (discussed in
section 2.2.1 above), with the lower end
of the range extending below the lowest
mean COHb level resulting from
controlled exposure to CO in the
clinical evidence (e.g., 2.0% postexercise in Allred et al., 1989b). The
extension of this range reflects a number
of considerations, including: (1)
Comments from the CASAC CO panel
on the draft Scope and Methods Plan
(Brain, 2009); (2) consideration of the
uncertainties regarding the actual COHb
levels experienced in the controlled
human exposure studies; (3) that these
studies did not include individuals with
most severe cardiovascular disease;35 (4)
the lack of studies that have evaluated
effects of experimentally controlled
short-term CO exposures resulting in
mean COHb levels below 2.0–2.4%; and
(5) the lack of evidence of a threshold
at the increased COHb levels evaluated.
We note that CASAC comments on the
first draft REA recommended the
addition of a benchmark at 1.0% COHb
and results are presented for this COHb
level in the REA. Given that this level
overlaps with the upper part of the
range of endogenous levels in healthy
individuals as characterized in the ISA
(ISA, p. 2–6), and is within the upper
35 Although the CAD patients evaluated in the
controlled human exposure study by Allred et al.
(1989a, 1989b, 1991) are not necessarily
representative of the most sensitive population, the
level of disease in these individuals ranged from
moderate to severe, with the majority either having
a history of myocardial infarction or having ≥70%
occlusion of one or more of the coronary arteries
(ISA, p. 5–43).
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part of the range of baseline COHb
levels in the study by Allred et al
(1989b, Appendix B), however, we
considered that it may not be
appropriate to place weight on it as a
benchmark level and accordingly have
not focused on interpreting absolute
COHb estimates at and below this level
in the discussion below. Additionally
we note the REA estimates indicating
that, in the absence of CO exposure,
approximately 0.5% to 2% of the
simulated at-risk populations in the two
study areas were estimated to
experience a single daily maximum endof-hour COHb level, arising solely from
endogenous CO production, at or above
1% (REA, Appendix B, Figure B–3).
The Policy Assessment also
considered the evidence from controlled
human exposure studies in interpreting
the REA estimates of maximum ambient
exposure contributions to end-of-hour
COHb levels (described in sections 4.4.7
and 5.10.3 of the REA). As discussed
above, the study by Allred et al (1989a,
1989b, 1991) observed reduced time to
exercise-induced angina and STsegment change in groups of subjects
with pre-existing CAD for which
controlled CO exposures increased their
COHb levels by on average 1.4–1.8%
and 3.2–4.0% COHb from initial COHb
levels of on average 0.6% COHb (ISA,
section 5.2.4; Allred et al., 1989a,
1989b, 1991). The study reported a
dose-response relationship in terms of
time reduction per 1% increase in
COHb concentration based on analysis
of the full data set across both exposure
groups. For purposes of the discussion
in this document, we have presented the
percentage of the simulated at-risk
populations estimated to experience
maximum ambient contribution to endof-hour COHb levels above and below a
range of levels extending from 1.4 to
2.0%. As noted above, the Policy
Assessment recognized distinctions
between the REA ‘‘baseline’’ (arising
from prior ambient exposure and
endogenous CO production) and the
pre-exposure COHb levels in the
controlled human exposure study
(arising from ambient and nonambient
exposure history, as well as from
endogenous CO production), and also
noted the impact of ‘‘baseline’’ COHb
levels on COHb levels occurring in
response to short ambient CO exposure
events such as those simulated in the
REA as discussed above.
2. Key Limitations and Uncertainties
Numerous improvements have been
made over the last decade that have
reduced the uncertainties associated
with the models used to estimate COHb
levels resulting from ambient CO
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exposures under different air quality
conditions, including those associated
with just meeting the current CO
NAAQS (REA, section 4.3). This
progression in exposure model
development has led to the model
currently used by the Agency
(APEX4.3), which has an enhanced
capacity to estimate population CO
exposures and more accurately predicts
COHb levels in persons exposed to CO.
Our application of APEX4.3 in this
review, using updated data and new
algorithms to estimate exposures and
doses experienced by individuals, better
represents the variability in population
exposure and COHb dose levels than the
model version used in previous CO
assessments.36 However, while APEX
4.3 is greatly improved when compared
with previously used exposure models,
its application is still limited with
regard to data to inform our
understanding of spatial relationships in
ambient CO concentrations and within
microenvironments of particular
interest. Further information regarding
model improvements and remaining
exposure modeling uncertainties are
summarized in section 2.2.2 of the
Policy Assessment and described in
detail in chapter 7 of the REA.
The uncertainties associated with the
quantitative estimates of exposure and
dose were considered using a generally
qualitative approach intended to
identify and compare the relative
impact that important sources of
uncertainty may have on the estimated
potential health effect endpoints (i.e.,
estimates of the maximum end-of-hour
COHb levels in the simulated at-risk
population). The approach used was
developed using World Health
Organization (WHO) guidelines on
conducting a qualitative uncertainty
characterization (WHO, 2008) and was
also applied in the most recent NO2
(USEPA, 2008c) and SO2 NAAQS
reviews (USEPA, 2009e). A qualitative
approach was employed given the
extremely limited data available to
inform probabilistic uncertainty
analyses. The qualitative approach used
varies from that of WHO (2008) in that
a greater focus of the characterization
performed was placed on evaluating the
direction and the magnitude of the
uncertainty; that is, qualitatively rating
how the source of uncertainty, in the
presence of alternative information, may
affect the estimated exposures and
health risk results. Additionally,
36 APEX4.3 provides estimates for percent of
population projected to experience a single or
multiple occurrences of a daily maximum COHb
level above the various benchmark levels, as well
as percent of person-days.
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consistent with the WHO (2008)
guidance, the REA discusses the
uncertainty in the knowledge base (e.g.,
the accuracy of the data used,
acknowledgement of data gaps) and
decisions made where possible (e.g.,
selection of particular model forms),
though qualitative ratings were assigned
only to uncertainty regarding the
knowledge base.
Sixteen separate sources of
uncertainty associated with four main
components of the assessment were
identified. By comparing judgments
made regarding the magnitude and
direction of influence that the identified
sources have on estimated exposure
concentrations and dose levels and the
existing uncertainties in the knowledge
base, seven sources of uncertainty (i.e.,
the spatial and temporal representation
of ambient monitoring data, historical
data used in representing alternative air
quality scenarios, activity pattern
database, longitudinal profile algorithm,
microenvironmental algorithm and
input data, and physiological factors)
were identified as the most important
areas of uncertainty in this assessment
(PA, section 2.2.2). Taking into
consideration improvements in the
model algorithms and data since the last
review, and having identified and
characterized these uncertainties here,
the Policy Assessment concludes that
the estimates associated with the
current analysis, at a minimum, better
reflect the full distribution of exposures
and dose as compared to results from
the 1992 analysis. As noted in the
Policy Assessment, however, potentially
greater uncertainty remains in our
characterization of the upper and lower
percentiles of the distribution of
population exposures and COHb dose
levels relative to that of other portions
of the respective distribution. When
considering the overall quality of the
current exposure modeling approach,
the algorithms, and input data used,
alongside the identified limitations and
uncertainties, the REA and Policy
Assessment conclude that the
quantitative assessment provides
reasonable estimates of CO exposure
and COHb dose for the simulated
population the assessment is intended
to represent (i.e., the population
residing within the urban core of each
study area).
The Policy Assessment additionally
notes the impact on the REA dose
estimates for ambient CO contribution
to COHb of the lack of nonambient
sources in the model simulations. This
aspect of the assessment design may
contribute to higher estimates of the
contribution of short-duration ambient
CO exposures to total COHb than would
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result from simulations that include the
range of commonly encountered CO
sources beyond just those contributing
to ambient air CO concentrations.
Although the specific quantitative
impact of this on estimates of
population percentages discussed in
this document is unknown,
consideration of COHb estimates from
the 2000 assessment indicates a
potential for the inclusion of
nonambient sources to appreciably
affect absolute COHb (REA, section 6.3)
and accordingly implies the potential,
where present, for an impact on overall
ambient contribution to a person’s
COHb level.
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D. Conclusions on Adequacy of the
Current Standards
The initial issue to be addressed in
the current review of the primary CO
standards is whether, in view of the
advances in scientific knowledge and
additional information now available,
the existing standards should be
retained or revised. In evaluating
whether it is appropriate to retain or
revise the current standards, the
Administrator builds upon the last
review and reflects the broader body of
evidence and information now
available. The Administrator has taken
into account both evidence-based and
quantitative exposure- and risk-based
considerations in developing
conclusions on the adequacy of the
current primary CO standards.
Evidence-based considerations include
the assessment of evidence from
controlled human exposure,
toxicological and epidemiological
studies evaluating short- or long-term
exposures to CO, with supporting
evidence related to dosimetry and
potential mode of action, as well as the
integration of evidence across each of
these disciplines, and with a focus on
policy-relevant considerations as
discussed in the PA. The exposure/
dose-based considerations draw from
the results of the quantitative analyses
presented in the REA and summarized
in section II.C above, and consideration
of those results in the PA. More
specifically, estimates of the magnitude
of ambient CO-related exposures and
associated COHb levels associated with
just meeting the current primary CO
NAAQS have been considered. Together
the evidence-based and risk-based
considerations have informed the
Administrator’s proposed conclusions
related to the adequacy of the current
CO standards in light of the currently
available scientific evidence.
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1. Approach
In considering the evidence and
quantitative exposure and dose
estimates with regard to judgments on
the adequacy afforded by the current
standards, we note that the final
decision is largely a public health policy
judgment. A final decision must draw
upon scientific information and
analyses about health effects and risks,
as well as judgments about how to
consider the range and magnitude of
uncertainties that are inherent in the
scientific evidence and analyses. Our
approach to informing these judgments,
discussed more fully below, is based on
the recognition that the available health
effects evidence generally reflects a
continuum, consisting of ambient levels
at which scientists generally agree that
health effects are likely to occur,
through lower levels at which the
likelihood and magnitude of the
response become increasingly uncertain.
This approach is consistent with the
requirements of the NAAQS provisions
of the Act and with how EPA and the
courts have historically interpreted the
Act. These provisions require the
Administrator to establish primary
standards that, in the Administrator’s
judgment, are requisite to protect public
health with an adequate margin of
safety. In so doing, the Administrator
seeks to establish standards that are
neither more nor less stringent than
necessary for this purpose. The Act does
not require that primary standards be set
at a zero-risk level, but rather at a level
that avoids unacceptable risks to public
health, including the health of sensitive
groups.37
The following subsections include
background information on the
approach used in the previous review of
the CO standards (section II.D.1.a) and
also a description of the approach for
the current review (section II.D.1.b).
a. Previous Reviews
The current primary standards for CO
are set at 9 parts per million (ppm) as
an 8-hour average and 35 ppm as a 1hour average, neither to be exceeded
more than once per year. These
standards were initially set in 1971 to
protect against the occurrence of
carboxyhemoglobin (COHb) levels that
37 The sensitive population groups identified in a
NAAQS review may (or may not) be comprised of
low income or minority groups. Where low income/
minority groups are among the sensitive groups, the
rulemaking decision will be based on providing
protection for these and other sensitive population
groups. To the extent that low income/minority
groups are not among the sensitive groups, a
decision based on providing protection of the
sensitive groups would be expected to provide
protection for the low income/minority groups (as
well as any other less sensitive population groups).
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may be associated with effects of
concern (36 FR 8186). Reviews of these
standards in the 1980s and early 1990s
identified additional evidence regarding
ambient CO, CO exposures, COHb
levels, and associated health effects
(USEPA, 1984a, 1984b; USEPA, 1991;
USEPA, 1992; McClellan, 1991, 1992).
Assessment of the evidence in those
reviews, completed in 1985 and 1994,
led the EPA to retain the existing
primary standards without revision (50
FR 37484, 59 FR 38906).
The 1994 decision to retain the
primary standards without revision was
based on the evidence published
through 1990 and reviewed in the 1991
AQCD (USEPA, 1991), the 1992 Staff
Paper assessment of the policy-relevant
information contained in the AQCD and
the quantitative exposure assessment
(USEPA, 1992), and the advice and
recommendations of CASAC (McClellan
1991, 1992). At that time, as at the time
of the first NAAQS review (50 FR
37484), COHb levels in blood were
recognized as providing the most useful
estimate of exogenous CO exposures
and serving as the best biomarker of CO
toxicity for ambient-level exposures to
CO (59 FR 38909). Consequently, COHb
levels were used as the indicator of
health effects in the identification of
health effect levels of concern for CO
(59 FR 38909).
In reviewing the standards in 1994 the
Administrator first recognized the need
to determine the COHb levels of concern
‘‘taking into account a large and diverse
health effects database.’’ The more
uncertain and less quantifiable evidence
was taken into account to identify the
lower end of this range to provide an
adequate margin of safety for effects of
clear concern. To consider ambient CO
concentrations likely to result in COHb
levels of concern, a model solution to
the Coburn-Forster-Kane (CFK)
differential equation was employed in
the analysis of CO exposures expected
to occur under air quality scenarios
related to just meeting the current 8hour CO NAAQS, the controlling
standard (USEPA, 1992).38 Key
considerations in this approach are
described below.
The assessment of the science that
was presented in the 1991 AQCD
(USEPA, 1991) indicated that CO is
associated with effects in the
cardiovascular system, central nervous
system (CNS), and the developing fetus.
Additionally, factors recognized as
having the potential to alter the effects
38 Air quality analyses of CO levels in the U.S.
consistently demonstrate that meeting the 8-hour
standard results in 1-hour maximum concentrations
well below the corresponding 1-hour standard.
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of CO included exposures to other
pollutants, some drugs and some
environmental factors, such as altitude.
Cardiovascular effects of CO, as
measured by decreased time to onset of
angina and to onset of significant
electrocardiogram (ECG) ST-segment
depression were judged by the
Administrator to be ‘‘the health effects of
greater concern, which clearly had been
associated with CO exposures at levels
observed in ambient air’’ (59 FR 38913).
Based on the consistent findings of
response in patients with coronary
artery disease across the controlled
human exposure evidence (Adams et
al., 1988; Allred et al., 1989a, 1989b,
1991; Anderson et al., 1973; Kleinman
et al., 1989, 1998; Sheps et al., 1987 39)
and discussions of adverse health
consequences in the 1991 AQCD and
the 1992 Staff Paper,40 at the CASAC
meetings and in the July 1991 CASAC
letter, the Administrator concluded that
‘‘CO exposures resulting in COHb levels
of 2.9–3.0 percent (CO–Ox) or higher in
persons with heart disease have the
potential to increase the risk of
decreased time to onset of angina pain
and ST-segment depression’’ (59 FR
38913). While EPA and CASAC
recognized the existence of a range of
views among health professionals on the
clinical significance of these responses,
CASAC noted that the dominant view
was that they should be considered
‘‘adverse or harbinger of adverse effect’’
(McClellan, 1991) and EPA recognized
that it was ‘‘important that standards be
set to appropriately reduce the risk of
ambient exposures which produce
COHb levels that could induce such
potentially adverse effects’’ (59 FR
38913).
In further considering additional
results from the controlled human
exposure evidence, such as the results
from Allred et al. (1989a, 1989b) at 2.0%
COHb (using GC measurement) induced
by short (approximately 1-hour) CO
exposure, as well as other aspects of the
available evidence and uncertainties
regarding modeling estimates of COHb
formation and human exposure to COHb
levels in the population associated with
attainment of a given CO NAAQS, the
Administrator recognized the need to
extend the range of COHb levels for
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39 See
footnote 15 above.
on consideration of the key studies,
including those two that investigated more than a
single target COHb level, discussions in the 1991
AQCD and with CASAC, the 1992 Staff Paper
recommended that ‘‘2.9–3.0% COHb (CO–Ox),
representing an increase above initial COHb of 1.5
to 2.2% COHb, be considered a level of potential
adversity for individuals at risk’’ (59 FR 38911;
USEPA, 1992; USEPA, 1991, pp. 1–11 to 1–12;
Allred et al., 1989a, 1989b, 1991; Anderson et al.,
1973).
40 Based
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consideration in evaluating whether the
current CO standards provide an
adequate margin of safety to those
falling between 2.0 to 2.9% COHb (59
FR 38913). Factors considered in
recognizing this margin of safety
included the following (59 FR 38913).
• Uncertainty regarding the clinical
importance of cardiovascular effects
associated with exposures to CO that
resulted in COHb levels of 2 to 3
percent. Although recognizing the
possibility that there is no threshold for
these effects even at lower COHb levels,
the clinical importance of
cardiovascular effects associated with
short (approximately 1-hour) exposures
to CO resulting in COHb levels as low
as 2.0% COHb by GC (Allred et al.,
1989a,b) was described as ‘‘less certain’’
than effects noted for exposures
contributing to higher COHb (CO–Ox)
levels (59 FR 38913).
• Findings of short-term reduction in
maximal work capacity measured in
trained athletes exposed to CO at levels
resulting in COHb levels of 2.3 to 7
percent.
• The potential that the most
sensitive individuals have not been
studied, the limited information
regarding the effects of ambient CO in
the developing fetus, and concern about
visitors to high altitudes, individuals
with anemia or respiratory disease, or
the elderly.
• Potential for short term peak CO
exposures to be responsible for
impairments (impairment of visual
perception, sensorimotor performance,
vigilance or other CNS effects) which
could be a matter of concern for
complex activities such as driving a car,
although these effects had not been
demonstrated to be caused by CO
concentrations in ambient air.
• Concern based on limited evidence
for individuals exposed to CO
concurrently with drugs (e.g., alcohol),
during heat stress, or co-exposure to
other pollutants.
• Uncertainties, described as ‘‘large,’’
that remained regarding modeling COHb
formation and estimating human
exposure to CO which could lead to
overestimation of COHb levels in the
population associated with attainment
of a given CO NAAQS.
• Uncertainty associated with COHb
measurements made using CO–Ox
which may not reflect COHb levels in
angina patients studied, thereby creating
uncertainty in establishing a lowest
effects level for CO.
Based on these considerations of the
evidence, the Administrator identified a
range of COHb levels for considering
margin of safety, extending from 2.9%
COHb (representing an increase of 1.5%
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above baseline when using CO–Ox
measurements) at the upper end down
to 2% at the lower end (59 FR 38913),
and also concluded that ‘‘evaluation of
the adequacy of the current standard
should focus on reducing the number of
individuals with cardiovascular disease
from being exposed to CO levels in the
ambient air that would result in COHb
levels of 2.1 percent’’ (59 FR 38914). She
additionally concluded that standards
that ‘‘protect against COHb levels at the
lower end of the range should provide
an adequate margin of safety against
effects of uncertain occurrence, as well
as those of clear concern that have been
associated with COHb levels in the
upper-end of the range’’ (59 FR 38914).
To estimate CO exposures and
resulting COHb levels that might be
expected under air quality conditions
that just met the current standards, an
analysis of exposure and associated
internal dose in terms of COHb levels in
the population of interest in the city of
Denver, Colorado was performed (59 FR
38906; USEPA, 1992). That analysis
indicated that if the 9 ppm 8-hour
standard were just met, the proportion
of the nonsmoking population with
cardiovascular disease experiencing a
daily maximum 8-hour exposure at or
above 9 ppm for 8 hours decreased by
an order of magnitude or more as
compared to the proportion under thenexisting CO levels, down to less than 0.1
percent of the total person-days in that
population. Further, upon meeting the
8-hour standard, EPA estimated that less
than 0.1% of the nonsmoking
cardiovascular-disease population
would experience a COHb level greater
than or equal to 2.1% and a smaller
percentage of the at-risk population was
estimated to exceed higher COHb levels
(59 FR 38914).41 Based on these
estimates, the Administrator concluded
that ‘‘relatively few people of the
cardiovascular sensitive population
group analyzed will experience COHb
levels ≥ 2.1 percent when exposed to CO
levels in absence of indoor sources
when the current standards are
attained.’’ The analysis also took into
account that certain indoor sources (e.g.,
passive smoking, gas stove usage)
contributed to total CO exposure and
EPA recognized that such sources may
be of concern for such high risk groups
41 In the 1992 assessment, the person-days
(number of persons multiplied by the number of
days per year exposed) and person-hours (number
of persons multiplied by the number of hours per
year exposed) were the reported exposure metrics.
Upon meeting the 8-hour standard, it was estimated
that less than 0.1% of the total person-days
simulated for the nonsmoking cardiovasculardisease population were associated with a
maximum COHb level greater than or equal to 2.1%
(USEPA, 1992; Johnson et al., 1992).
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as individuals with cardiovascular
disease, pregnant women, and their
unborn children but concluded that ‘‘the
contribution of indoor sources cannot be
effectively mitigated by ambient air
quality standards’’ (59 FR 38914).
Based on consideration of the
evidence and the quantitative results of
the exposure assessment, the
Administrator concluded that revisions
of the current primary standards for CO
were not appropriate at that time (59 FR
38914). The Administrator additionally
concluded that both averaging times for
the primary standards, 1 hour and 8
hours, be retained. The 1-hour and 8hour averaging times were first chosen
when EPA promulgated the primary
NAAQS for CO in 1971. The selection
of the 8-hour averaging time was based
on the following: (a) Most individuals’
COHb levels appeared to approach
equilibrium after 8 hours of exposure,
(b) the 8-hour time period corresponded
to the blocks of time when people were
often exposed in a particular location or
activity (e.g., working or sleeping), and
(c) judgment that this provided a good
indicator for tracking continuous
exposures during any 24-hour period.
The 1-hour averaging time was selected
as better representing a time period of
interest to short-term CO exposure and
providing protection from effects which
might be encountered from very short
duration peak exposures in the urban
environment (59 FR 38914).
b. Current Review
To evaluate whether it is appropriate
to consider retaining the current
primary CO standards, or whether
consideration of revisions is
appropriate, we adopted an approach in
this review that builds upon the general
approach used in the last review and
reflects the broader body of evidence
and information now available. As
summarized above, the Administrator’s
decisions in the previous review were
based on an integration of information
on health effects associated with
exposure to ambient CO; expert
judgment on the adversity of such
effects on individuals; and a public
health policy judgment as to what
standard is requisite to protect public
health with an adequate margin of
safety, which were informed by air
quality and related analyses,
quantitative exposure and risk
assessments when possible, and
qualitative assessment of impacts that
could not be quantified. Similarly, in
this review, as described in the Policy
Assessment, we draw on the current
evidence and quantitative assessments
of exposure pertaining to the public
health risk of ambient CO. In
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considering the scientific and technical
information, here as in the Policy
Assessment, we consider both the
information available at the time of the
last review and information newly
available since the last review,
including the current ISA and the 2000
AQCD (USEPA, 2010a; USEPA, 2000),
as well as current and preceding
quantitative exposure/dose assessments
(USEPA 2010b; Johnson et al., 2000;
USEPA 1992).
As described earlier, at this time as at
the time of the last review, the best
characterized health effect associated
with CO levels of concern is hypoxia
(reduced oxygen availability) induced
by increased COHb levels in blood (ISA,
section 5.1.2). Accordingly, CO
exposure is of particular concern for
those with impaired cardiovascular
systems, and the most compelling
evidence of cardiovascular effects is that
from a series of controlled human
exposure studies among exercising
individuals with CAD (ISA, sections
5.2.4 and 5.2.6). Additionally available
in this review are a number of
epidemiological studies that
investigated the association of
cardiovascular disease-related health
outcomes with concentrations of CO at
ambient monitors. To inform our review
of the ambient standards, we performed
a quantitative exposure and dose
modeling analysis that estimated COHb
levels associated with different air
quality conditions in simulated at-risk
populations in two U.S. cities, as
described in detail in the REA and
summarized in the Policy Assessment
(PA, section 2.2.2). Thus, in developing
conclusions with regard to the CO
NAAQS, EPA has taken into account
both evidence-based and exposure/dosebased considerations.
The approach to reaching a decision
on the adequacy of the current primary
standards is framed by consideration of
the following series of key policyrelevant questions.
• Does the currently available
scientific evidence- and exposure/dose/
risk-based information, as reflected in
the ISA and REA, support or call into
question the adequacy of the protection
afforded by the current CO standards?
• Does the current evidence alter our
conclusions from the previous review
regarding the health effects associated
with exposure to CO?
• Does the current evidence continue
to support a focus on COHb levels as the
most useful indicator of CO exposures
and the best biomarker to characterize
potential for health effects associated
with exposures to ambient CO? Or does
the current evidence provide support for
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a focus on alternate dose indicators to
characterize potential for health effects?
• Does the current evidence alter our
understanding of populations that are
particularly susceptible to CO
exposures? Is there new evidence that
suggest additional susceptible
populations that should be given
increased focus in this review?
• Does the current evidence alter our
conclusions from the previous review
regarding the levels of CO in ambient air
associated with health effects?
• To what extent have important
uncertainties identified in the last
review been reduced and/or have new
uncertainties emerged?
The following sections describe the
assessment of these issues in the Policy
Assessment, the advice received from
CASAC, as well as the comments
received from various parties, and then
presents the Administrator’s proposed
conclusions regarding the adequacy of
the current primary standards.
2. Evidence-Based and Exposure/DoseBased Considerations in the Policy
Assessment
The Policy Assessment (chapter 2)
considers the evidence presented in the
Integrated Science Assessment, and
preceding AQCDs, as discussed above in
section II.B as a basis for evaluating the
adequacy of the current CO standards,
recognizing that important uncertainties
remain. The Policy Assessment
concludes that the combined
consideration of the body of evidence
and the results from the quantitative
exposure and dose assessment provide
support for standards at least as
protective as the current suite of
standards to provide appropriate public
health protection for susceptible
populations, including most particularly
individuals with cardiovascular disease,
against effects of CO in exacerbating
conditions of reduced oxygen
availability to the heart (PA, section
2.4). More specifically, the Policy
Assessment concludes that the
combined consideration of the evidence
and quantitative estimates from the REA
may be viewed as providing support for
either retaining or revising the current
suite of standards (PA, p. 2–59). CASAC
stated agreement with this conclusion,
while additionally expressing a
‘‘preference’’ for revisions to a lower
standard. Members of the public who
provided comments on the draft Policy
Assessment supported retaining the
current standard without revision. The
specific considerations on which the
Policy Assessment conclusions are
based are described in the subsections
below.
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a. Evidence-Based Considerations
In considering the evidence available
for the current review of the CO
NAAQS, the Policy Assessment
discussed whether or not, or the extent
to which, the current evidence alters
conclusions reached in the previous
review regarding levels of CO in
ambient air associated with health
effects and associated judgments on
adequacy of the current standards. With
this discussion, the Policy Assessment
also considered the extent to which
important uncertainties identified in the
last review have been reduced or new
uncertainties have emerged.
As an initial matter, the Policy
Assessment recognized that at the time
of the last review, EPA’s conclusions
regarding the adequacy of the existing
CO standards were drawn from the
combined consideration of the evidence
of COHb levels for which cardiovascular
effects of concern had been reported and
the results of an exposure and dose
modeling assessment (59 FR 38906). As
described in more detail above, the key
effects judged to be associated with CO
exposures resulting from concentrations
observed in ambient air were
cardiovascular effects, as measured by
decreased time to onset of exerciseinduced angina and to onset of ECG STsegment depression (59 FR 38913). As at
the time of the last review, the Policy
Assessment noted that the evidence
available in this review includes
multiple studies that document
decreases in time to onset of exerciseinduced angina (a symptom of
myocardial ischemia) in multiple
studies at post-exposure COHb levels
ranging from 2.9 to 5.9% (CO–Ox),
which represent incremental increases
of approximately 1.4–4.4% COHb from
baseline (CO–Ox) (PA, Table 2–2;
Adams et al., 1988; Allred et al., 1989a,
1989b, 1991; Anderson et al., 1973;
Kleinman et al., 1989, 1998 42; Sheps et
al., 1987 43). The study results from
Allred et al. (1989a, 1989b, 1991) also
provide evidence for these effects in
terms of COHb measurements using gas
chromatography.44 45 Evidence also
available at the time of the last review
42 One new study of this type is available since
the 1994 review. This study, which focused on a
target COHb level of 3.9% COHb (CO–Ox) and is
discussed in the 2000 AQCD is generally consistent
with the previously available studies (2000 AQCD,
section 6.2.2; Kleinman et al., 1998).
43 See footnote 15 above.
44 Gas chromatography is generally recognized to
be the more accurate method for COHb levels below
5% (ISA, section 5.2.4).
45 In the lower CO exposure group, the postexposure mean COHb was 3.21% by CO–Ox and
2.38% by GC, while the post-exercise mean COHb
was 2.65% by CO–Ox and 2.00% by GC (Allred et
al., 1989a, 1989b, 1991).
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of effects in other clinical study groups
includes effects in subjects with cardiac
arrhythmias and effects on exercise
duration and maximal aerobic capacity
in healthy adults. Among the studies of
myocardial ischemia indicators in
patients with CAD, none provide
evidence of a measurable threshold at
the lowest experimental CO exposures
and associated COHb levels assessed
(e.g., mean of 2.0–2.4% COHb, GC)
which resulted in average increases in
COHb of about 1.5% over pre-exposure
baseline (Anderson et al., 1973;
Kleinman et al., 1989; Allred et al.
1989a, 1989b, 1991).46 Allred et al.
(1989a, 1989b, 1991) further reported a
dose-response relationship between the
increased COHb levels and the response
of the assessed indicators of myocardial
ischemia (Allred et al., 1989a, 1989b,
1991). While this evidence informs our
conclusions regarding COHb levels
associated with health effects, the CO
exposure concentrations employed in
the studies to achieve these COHb levels
were substantially above ambient
concentrations. Thus, an exposure and
dose assessment was performed to
consider the COHb levels that might be
attained as a result of exposures to
ambient CO allowed under the current
NAAQS, as described in section II.C
above.
Since the time of the last review, there
have been no new controlled human
exposure studies specifically designed
to evaluate the effects of CO exposure in
susceptible populations at study mean
COHb levels at or below 2% COHb.
Thus, similar to the last review, the
multilaboratory study by Allred et al.
(1989a, 1989b, 1991) continues to be the
study that has evaluated cardiovascular
effects of concern (i.e., reduced time to
exercise-induced myocardial ischemia
as indicated by ECG ST-segment
changes and angina) at the lowest tested
COHb levels (ISA, section 2.7). This
study is also of particular importance in
this review because it is considered the
most rigorous and well designed study,
presenting the most sensitive analysis
methods (GC used in addition to CO–
Ox) to quantify COHb blood levels. Key
findings from that study with regard to
levels of CO associated with health
effects, as discussed in section II.B.2
above, include the following:
• Short (50–70 minute) exposure to
increased CO concentrations that
46 The studies by Anderson et al. (1973) and
Kleinman et al. (1989) did not use GC to measure
COHb levels, and reported reduced exercise
duration due to increased chest pain at CO
exposures resulting in 2.8–3.0% COHb (CO–Ox).
The COHb levels assessed in these two studies
represented increase in average COHb levels over
baseline of 1.4% and 1.6% COHb.
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resulted in increases in COHb to mean
levels of 2.0% and 3.9% (post-exercise)
from mean a baseline level of 0.6%
significantly reduced exercise time
required to induce markers of
myocardial ischemia in CAD patients.
For the more objective marker of STsegment change, the lower exposure
reduced the time to onset by 5.1%
(approximately one half minute) and the
higher exposure reduced the time to
onset by 12.1%.47
• The associated dose-response
relationship between incremental
changes in COHb and change in time to
myocardial ischemia in CAD patients
indicates a 1.9% and 3.9% reduction in
time to onset of exercise-induced angina
and ST-segment change, respectively,
per 1% increase in COHb concentration
from average baseline COHb of 0.6%
without evidence of a measurable
threshold.
As described in section II.B.2 above,
a number of epidemiological studies of
health outcome associations with
ambient CO have been conducted since
the last review. These include studies
that have reported associations with
different ambient CO metrics (e.g., 1hour and 8-hour averages, often as
central-site estimates) derived from CO
measurements at fixed-site ambient
monitors in selected urban areas of the
U.S. and cardiovascular endpoints other
than stroke, particularly hospitalizations
and emergency department visits for
specific cardiovascular health outcomes
including IHD, CHF and CVD (Bell et
al., 2009; Koken et al., 2003; Linn et al.,
2000; Mann et al., 2002; Metzger et al.,
2004; Symons et al., 2006; Tolbert et al.,
2007; Wellenius et al., 2005). In general,
these studies, many of which were
designed to evaluate the effects of a
variety of air pollutants, including CO,
report positive associations, a number of
which are statistically significant (ISA,
sections 5.2.3 and 5.2.1.9). The longstanding body of evidence for CO
summarized above, including the wellcharacterized role of CO in limiting
oxygen availability, lends biological
plausibility to the ischemia-related
health outcomes reported in the
epidemiological studies, providing
coherence between these studies and
the clinical evidence of short-term
exposure to CO and health effects. Thus,
although there is no new evidence
47 Across all subjects, the mean time to angina
onset for baseline or control (‘‘clean’’ air) exposures
was approximately 8.5 minutes, and the mean time
to ST endpoint was approximately 9.5 minutes,
with the ‘‘time to onset’’ reductions of the two
exposure levels being approximately one half and
one minute, respectively for ST-segment change,
and slightly less and slightly more than one half
minute, respectively, for angina (Allred et al.,
1989b).
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regarding the effects of short-term
controlled CO exposures that result in
lower COHb levels, the evidence is
much expanded with regard to
epidemiological 48 analyses of ambient
monitor concentrations, which observed
associations between specific and
overall cardiovascular-related outcomes
and ambient CO measurements.
The Policy Assessment considered the
combined evidence base for CO
cardiovascular effects in the context of
a conceptual model of the pathway from
CO exposures to the occurrence of these
effects (as described in section 2.2.1 of
the PA). In this context, the Policy
Assessment noted differences between
the controlled human exposure and
epidemiological studies, described
above, with regard to the elements along
this pathway that have been
investigated in those studies. The
controlled human exposure studies
document relationships between
directly measured controlled short-term
CO exposures and specific levels of an
internal dose metric, COHb, which
elicited specific myocardial ischemiarelated responses in CAD patients.
These studies inform our interpretation
of the associations we observed in the
epidemiological studies. The
epidemiological studies reported
associations between CO levels
measured at fixed-site monitors and
emergency department visits and/or
hospital admissions for IHD and other
cardiovascular disease-related outcomes
that are plausibly related to the effects
on physiological indicators of
myocardial ischemia (e.g., ST-segment
changes) demonstrated in the controlled
human exposure studies, providing
coherence between the two sets of
findings (ISA, p. 5–48). With regard to
extending our understanding of effects
occurring below levels of CO evaluated
in the controlled human exposure
studies, however, the epidemiological
evidence for CO is somewhat limited.
The epidemiological evidence lacks
measurements of COHb or personal
exposure concentrations that would
facilitate integration with the controlled
human exposure study data.
Furthermore, the epidemiological
evidence base for IHD outcomes or CVD
outcomes as a whole includes a number
of studies involving conditions in which
the current standard was not met.
Though these studies are informative to
consideration of the relationship of
health effects to the full range of
48 Few epidemiological studies that had
investigated the relationship between CO exposure
and ischemic heart disease were available at the
time of the last completed review (1991 AQCD,
section 10.3.3).
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ambient CO concentrations, the Policy
Assessment indicated that they are less
useful to informing our conclusions
regarding adequacy of the current
standards.
As discussed in the Policy
Assessment, the smaller set of
epidemiological studies, under
conditions where the current standards
were met, is considered to better inform
our assessment of the adequacy of the
standards or conditions of lower
ambient concentrations. Among the few
studies conducted during conditions in
which the current standards were
always met, however, the studies
reporting statistical significance for IHD
or all CVD outcomes are limited to a
single study area (i.e. Atlanta). When the
analyses reporting significance for
association with CHF outcomes are also
considered, a second study area is
identified (Allegheny County, PA) in
which the current standard is met
throughout the study period. The
analyses for both areas involve the use
of central site monitor locations or areawide average concentrations, which
given the significant concentration
gradients of CO in urban areas (ISA,
section 3.6.8.2), complicates our ability
to draw conclusions from them
regarding ambient CO concentrations of
concern. Therefore, the Policy
Assessment primarily focused
consideration of the epidemiological
studies on the extent to which this
evidence is consistent with and
generally supportive of conclusions
drawn from the combined consideration
of the controlled human exposure
evidence with estimates from the
exposure and dose assessment, as
discussed below. The Policy
Assessment indicated that, as in the
previous review, the integration of the
controlled human exposure evidence
with the exposure and dose estimates
will be most important to informing
conclusions regarding ambient CO
concentrations of public health concern.
With regard to areas of uncertainty,
the Policy Assessment recognized that
some important uncertainties have been
reduced since the time of the last
review, some still remain and others,
associated with newly available
evidence, have been identified. This
range of uncertainties identified at the
time of the last review (59 FR 38913,
USEPA, 1992), as well as any newly
identified uncertainties were considered
in the Policy Assessment as discussed
below (PA, section 2.2.1).
The CO-induced effects considered of
concern at the time of the last review
were reduced time to exercise-induced
angina and ST-segment depression in
patients suffering from coronary artery
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disease as a result of increases in COHb
associated with short CO exposures.
These effects had been well documented
in multiple studies, and it was
recognized that the majority of
cardiologists at the time believed that
recurrent exercise-induced angina was
associated with substantial risk of
precipitating myocardial infarction, fatal
arrhythmia, or slight but cumulative
myocardial damage (USEPA, 1992, p.
22; 59 FR 38911; Basan, 1990; 1991
AQCD). As at the time of the last review,
although ST-segment depression is a
recognized indicator of myocardial
ischemia, the exact physiological
significance of the observed changes
among individuals with CAD is unclear
(ISA, p. 5–48).
In interpreting the study results at the
time of the last review, EPA recognized
uncertainty in the COHb measurements
made using CO–Ox and associated
uncertainty in establishing a lowest
effects level for CO (USEPA, 1992, p.
31). A then-recent multicenter study
(Allred et al., 1989a, 1989b, 1991) was
of great importance at that time for
reasons identified above. Similarly, the
Science and Policy Assessments place
primary emphasis on the findings from
this study in the current review of the
evidence related to cardiovascular
effects associated with CO exposure,
recognizing the superior quality of the
study, both in terms of the rigorous
study design as well as the sensitivity of
the analytical methods used in
determining COHb concentrations (ISA,
section 2.7). No additional controlled
human exposure studies are available
that evaluate responses to lower COHb
levels in the cardiovascular-disease
population, and uncertainties still
remain in determining specific and
quantitative relationships between the
CO-induced effects in these studies and
the increased risk of specific health
outcomes. Further, with regard to thenunidentified effects at lower COHb
levels, no studies have identified other
effects on the CAD population or on
other populations at lower exposures
(ISA, sections 5.2.2).
The last review recognized
uncertainty with regard to the potential
for short-term CO exposures to
contribute to CNS effects which might
affect an individual’s performance of
complex activities such as driving a car
or to contribute to other effects of
concern. It was concluded, however,
that the focus of the review on
cardiovascular effects associated with
COHb levels below 5% also provided
adequate protection against potential
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adverse neurobehavioral effects.49 No
new controlled human exposure studies
have evaluated CNS or behavioral
effects of exposure to CO (ISA, section
5.3.1). However, given the drastic
reduction in CO ambient
concentrations, the Policy Assessment
concludes that occurrence of these
effects in response to ambient CO would
be expected to be rare within the current
population. Thus, the Policy
Assessment concludes that uncertainty
with regard to the potential for such
effects to be associated with current
ambient CO exposures is reduced (PA,
p. 2–35).
Since the 1994 review, the
epidemiologic and toxicological
evidence of effects on birth and
developmental outcomes has expanded,
although the available evidence is still
considered limited with regard to effects
on preterm birth, birth defects,
decreases in birth weight, measures of
fetal growth, and infant mortality (ISA,
section 5.4). Further, while animal
toxicological studies provide support
and coherence for those effects, the
understanding of the mechanisms
underlying reproductive and
developmental effects is still lacking
(ISA, section 5.4.1). Thus, the Policy
Assessment recognizes that although the
evidence continues to ‘‘suggest[s] that
critical developmental phases may be
characterized by enhanced sensitivity to
CO exposure’’ (ISA, p. 2–11), evidence is
lacking for adverse developmental or
reproductive effects at CO exposure
concentrations near those associated
with current levels of ambient CO (PA,
pp. 2–35 to 2–36).
As described above, the muchexpanded epidemiologic database in the
current review includes studies that
show associations between ambient CO
concentrations and increases in
emergency room visits and
hospitalizations for disease events
plausibly linked to the effects observed
in the controlled human exposure
studies of CAD patients (ISA, section
2.5.1), providing support for the ISA’s
conclusion regarding coronary artery
disease as the most important
susceptibility characteristic for
increased health risk due to CO
exposure (ISA, p. 2–10). However, the
Policy Assessment recognizes aspects of
this epidemiological evidence that
complicate quantitative interpretation of
it with regard to ambient concentrations
that might be eliciting the reported
49 The evidence available at the time of the last
review was based on a series of studies conducted
from the mid 1960’s through the early 1990’s, with
inconsistent findings of neurological effects at
exposures to CO resulting in COHb levels ranging
from 5–20% (1991 AQCD).
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health outcomes. As an initial matter,
the Policy Assessment notes the
substantially fewer studies conducted in
areas meeting the current CO standards
than is the case for NO2 and PM
(USEPA, 2008d, 2009f). Further, the
Policy Assessment recognizes
complicating aspects of the evidence
that relate to conclusions regarding CO
as the pollutant eliciting the effect
reported in the epidemiological studies
and to our understanding of the ambient
CO and nonambient concentrations to
which study subjects demonstrating
these outcomes are exposed.
With regard to these complications,
the Policy Assessment first considers
the extent to which the use of twopollutant regression models, a
commonly used statistical method (ISA,
section 1.6.3), inform conclusions
regarding CO as the pollutant eliciting
the effects in these studies (PA, pp. 2–
36 to 2–37). Although CO associations,
in some studies, are slightly attenuated
in models that adjusted for other
combustion-related pollutants (e.g.,
PM2.5 or NO2), they generally remain
robust (ISA, Figures 5–6 and 5–7).50 In
considering these two-pollutant model
results, however, the Policy Assessment
recognizes the potential for there to be
etiologically relevant pollutants that are
correlated with CO yet absent from the
analysis. Similarly, CASAC commented
that ‘‘the problem of co-pollutants
serving as potential confounders is
particularly problematic for CO’’. They
stated that ‘‘consideration needs to be
given to the possibility that in some
situations CO may be a surrogate for
exposure to a mix of pollutants
generated by fossil fuel combustion’’ and
‘‘a better understanding of the possible
role of co-pollutants is relevant to * * *
the interpretation of epidemiologic
studies on the health effects of CO’’
(Brain and Samet, 2010d). This issue is
particularly important in the case of CO
in light of uncertainty associated with
CO-related effects at low ambient
concentrations (discussed below) and in
light of the sizeable portion of ambient
CO measurements that are at or below
monitor detection limits. Consequently,
50 In interpreting the epidemiological evidence
for cardiovascular morbidity the ISA notes that it
‘‘is difficult to determine from this group of studies
the extent to which CO is independently associated
with CVD outcomes or if CO is a marker for the
effects of another traffic-related pollutant or mix of
pollutants. On-road vehicle exhaust emissions are
a nearly ubiquitous source of combustion pollutant
mixtures that include CO and can be an important
contributor to CO in near-road locations. Although
this complicates the efforts to disentangle specific
CO-related health effects, the evidence indicates
that CO associations generally remain robust in
copollutant models and supports a direct effect of
short-term ambient CO exposure on CVD
morbidity.’’ (ISA, pp. 5–40 to 5–41).
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8177
the extent to which multi-pollutant
regression models effectively
disentangle and quantitatively interpret
a CO-specific effect distinct from that of
other pollutants remains an area of
uncertainty.
In considering ambient concentrations
that may be triggering health outcomes
analyzed in the epidemiological studies,
the Policy Assessment recognizes the
uncertainty introduced by exposure
error. Exposure error can occur when a
surrogate is used for the actual ambient
exposure experienced by the study
population (e.g., ISA, section 3.6.8).
There are two aspects to the
epidemiological studies in the specific
case of CO, as contrasted with the cases
of other pollutants such as NO2 and PM,
that may contribute to exposure error in
the CO studies. The first relates to the
low concentrations of CO considered in
the epidemiological studies and monitor
detection limits. The second relates to
the use in the epidemiological studies of
area-wide or central-site monitor CO
concentrations in light of information
about the gradient in CO concentrations
with distance from source locations
such as highly-trafficked roadways (ISA,
section 3.5.1.3).
As discussed in the Policy
Assessment, uncertainty in the
assessment of exposure to ambient CO
concentrations is related to the
prevalence of ambient CO monitor
concentrations at or below detection
limits, which is a greater concern for the
more recently available epidemiological
studies in which the study areas have
much reduced ambient CO
concentrations compared with those in
the past (PA, pp. 2–37 to 2–38). For
example, the ISA notes that roughly one
third of the 1-hour ambient CO
measurements reported to AQS for
2005–2007 were below the method limit
of detection for the monitors analyzed
(ISA, p. 3–34). A similarly notable
proportion of measurements occur
below the monitor detection limit for
epidemiological study areas meeting the
current standards (e.g., Atlanta,
Allegheny County) (PA, Appendix B).
This complicates our interpretation of
specific ambient CO concentrations
associated with health effects (ISA, p. 3–
91; Brain and Samet, 2010d). In contrast
to CO, other combustion-related criteria
pollutants such as PM2.5 and NO2
generally occur above levels of
detection, providing us with greater
confidence in quantitative
interpretations of epidemiological
studies for those pollutants.
There are also differences in the
spatial variability associated with PM2.5
and NO2 concentrations as compared to
CO concentrations that add complexity
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to the estimation of CO exposures in
epidemiological studies. In general,
PM2.5 concentrations tend to be more
spatially homogenous across an urban
area than CO concentrations. CO
concentrations in urban areas are largely
driven by mobile sources, while urban
PM2.5 concentrations substantially
reflect contributions from mobile and a
variety of stationary sources. The greater
spatial homogeneity in PM2.5
concentrations is due in part to the
transport and dispersion of small
particles from the multiple sources
(USEPA, 2009f, sections 3.5.1.2 and
3.9.1.3), as well as to contributions from
secondarily formed components
‘‘produced by the oxidation of precursor
gases (e.g., sulfur dioxide and nitrogen
oxides) and reactions of acidic products
with NH3 and organic compounds’’
(USEPA, 2009f, p. 3–185), which likely
contribute to spatial homogeneity.
Similarly, ‘‘because NO2 in the ambient
air is due largely to the atmospheric
oxidation of NO emitted from
combustion sources (ISA, section 2.2.1),
elevated NO2 concentrations can extend
farther away from roadways than the
primary pollutants also emitted by onroad mobile sources’’ (40 FR 6479,
February 9, 2010). In contrast to PM2.5
and NO2, CO is not formed through
common atmospheric oxidation
processes, which may contribute to the
steeper CO gradient observed near
roadways. Therefore, the
misclassification of exposure arising
from the utilization of central site
monitors to measure PM2.5 and NO2
exposures is likely to be smaller than is
the case for CO exposures.
An additional complication to a
comparison of our consideration of the
CO epidemiological evidence to that for
other criteria pollutants is that, in
contrast to the situation for all other
criteria pollutants, the epidemiological
studies for CO use a different exposure/
dose metric from that which is the focus
of the broader health evidence base, and
additional information that might be
used to bridge this gap is lacking. In the
case of CO, the epidemiological studies
use air concentration as the exposure/
dose metric, while the broader health
effects evidence for CO demonstrates
and focuses on an internal biomarker of
CO exposure (COHb) which has been
considered a critical key to CO toxicity.
In the case of the only other criteria
pollutant for which the health evidence
relies on an internal dose metric—
lead—the epidemiological studies also
use that metric.51 For other criteria
51 In the case of lead (Pb), in contrast to that of
CO, the epidemiological evidence is focused on
associations of Pb-related health effects with
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pollutants, including PM and NO2, air
concentrations are used as the exposure/
dose metric in both the epidemiological
studies and the other types of health
evidence. Thus, there is no comparable
aspect in the PM or NO2 evidence base.
The strong evidence describing the role
of COHb in CO toxicity is important to
consider in interpreting the CO
epidemiological studies and contributes
to the biological plausibility of the
ischemia-related health outcomes that
have been associated with ambient CO
concentrations. Yet, we do not have
information on the COHb levels of
epidemiological study subjects that we
can evaluate in the context of the COHb
levels eliciting health effects in the
controlled human exposure studies.
Further, we lack additional information
on the CO exposures of the
epidemiological study subjects to both
ambient and nonambient sources of CO
that might be used to estimate their
COHb levels and bridge the gap between
the two study types.
Additionally the ISA recognizes that
the changes in COHb that would likely
be associated with exposure to the low
ambient CO concentrations assessed in
some of the epidemiological studies
would be smaller than changes
associated with ‘‘substantially reduced
{oxygen} delivery to tissues,’’ that might
plausibly lead to the outcomes observed
in those studies, with additional
investigation needed to determine
whether there may be another
mechanism of action for CO that
contributes to the observed outcomes at
low ambient concentrations (ISA, p. 5–
48). Thus, there are uncertainties
associated with the epidemiological
evidence that ‘‘complicate the
quantitative interpretation of the
epidemiologic findings, particularly
regarding the biological plausibility of
health effects occurring at COHb levels
resulting from exposures to the ambient
CO concentrations’’ assessed in these
studies (ISA, p. 2–17).
In summary, the Policy Assessment
concludes that some important
uncertainties from the last review have
been reduced, including those
associated with concerns for ambient
levels of CO to pose neurobehavioral
risks as current concentrations of
ambient CO are well below those that
might be expected to result in COHb
levels as high as those associated with
these effects. Additionally, our exposure
measurements of Pb in blood, providing a direct
linkage between the pollutant, via the internal
biomarker of dose, and the health effects. Thus, for
Pb, as compared to the case for CO, we have less
uncertainty in our interpretations of the
epidemiological studies with regard to the pollutant
responsible for the health effects observed.
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and dose models have improved giving
us increased confidence in their
estimates. A variety of uncertainties still
remain including the adverse nature and
significance of the small changes in time
to ST-segment depression identified at
the lowest COHb levels investigated,
and the magnitude of associated risk of
specific health outcomes, as well as the
potential for as-yet-unidentified health
effects at COHb levels below 2%.
Additionally, although the evidence
base is somewhat expanded with regard
to the potential for CO effects on the
developing fetus, uncertainties remain
in our understanding of the potential
influence of low, ambient CO exposures
on conditions existing in the fetus and
newborn infant and on maternal-fetal
relationships. We additionally recognize
that the expanded body of
epidemiological evidence includes its
own set of uncertainties which
complicates its interpretation,
particularly with regard to ambient
concentrations that may be eliciting
health outcomes.
b. Exposure/Dose-Based Considerations
In considering the evidence from
controlled human exposure studies to
address the question regarding ambient
CO concentrations associated with
health effects, we have developed
estimates of COHb associated with
different air quality conditions using
quantitative exposure and dose
modeling, as was done at the time of the
last review. The current estimates are
presented in the REA and discussed
with regard to policy-relevant
considerations in this review in the
Policy Assessment (PA, section 2.2.2).
Since the last review, there have been
numerous improvements to the
exposure and COHb models that we use
to estimate exposure and dose for the
current review. The results of modeling
using these improved tools in the
current review and associated
conclusions in the Policy Assessment
are described below with regard to the
expectation for COHb levels of concern
to occur in the at-risk population under
air quality conditions associated with
the current CO standards.
In considering the results from the
REA, the Policy Assessment considered
several questions including those
concerning the magnitude of COHb
levels estimated in the simulated at-risk
populations in response to ambient CO
exposure, as well as the extent to which
such estimates may be judged to be
important from a public health
perspective.
In addressing the questions
concerning the magnitude of at-risk
population COHb levels estimated to
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occur in areas simulated to just meet the
current, controlling, 8-hour standard
and what portion of the at-risk
population is estimated to experience
maximum COHb levels above levels of
potential health concern, the Policy
Assessment first noted the context for
the population COHb estimates
provided by the REA simulations of
exposure to ambient CO (REA, section
6.2). As in the last review, the Policy
Assessment recognized that indoor
sources of CO can be important
determinants of population exposures to
CO and to population distributions of
daily maximum COHb levels, and that
for some portions of the population,
these sources may dominate CO
exposures and related maximum COHb
levels. The Policy Assessment
additionally took note of the
conclusions drawn in the previous
review that the contribution of indoor
sources to individual exposures and
associated COHb levels cannot be
effectively mitigated by ambient air
quality standards (e.g., 59 FR 38914)
and so focused on COHb levels resulting
from ambient CO exposures. In so
doing, however, the Policy Assessment
also recognized as noted in section II.C
above, that simulations focused solely
on exposures associated with ambient
CO may overestimate the response of
COHb levels to short-duration ambient
exposures (the ambient contribution) as
pre-exposure baseline COHb levels will
necessarily not reflect the contribution
of both nonambient and ambient
sources. Additionally, these simulations
may underestimate COHb levels that
would occur in situations with
appreciable nonambient exposure.
As recognized in the Policy
Assessment and described in detail in
the REA, estimates for exposure
concentrations indicated that highest
ambient CO exposures occurred in invehicle microenvironments, with next
highest exposures in
microenvironments where running
vehicles congregate such as parking
areas and fueling stations, (REA, section
6.1).
In considering the REA estimates for
current or ‘‘as is’’ air quality conditions
and conditions simulated to just meet
the current 8-hour standard, the Policy
Assessment particularly focused on the
extent to which the current standards
provide protection to the simulated atrisk population from COHb levels of
potential concern, by comparing the
estimated levels in the population to the
benchmarks described above. As
described above, the REA presents two
sets of COHb estimates: the first set of
absolute estimates reflect the impact of
ambient CO exposures in the absence of
exposure to nonambient CO, but in the
presence of endogenous CO production,
while the second set are estimates of the
portion of absolute COHb estimated to
occur in response to the simulated
ambient CO exposures, i.e., after
subtraction of COHb resulting from
endogenous CO production (REA,
sections 4.4.7 and 5.10.3). In describing
the REA results, the Policy Assessment
draws from exposure and dose estimates
for both the HD and CHD populations
(REA, section 6.2), recognizing that, in
terms of percentages of persons exposed
and experiencing daily maximum endof-hour COHb at or above specific
levels, the results are similar for the two
simulated at-risk populations (HD and
CHD). We note that, in terms of absolute
numbers of persons, the results differ
due to differences in the size of the two
populations.
The Policy Assessment first
considered the absolute COHb results
with regard to the percentage of
simulated populations experiencing at
least one day with an end-of hour COHb
level above selected benchmarks (Table
1 includes these results for the HD
populations). Another dimension of the
analysis, presented in Table 2 (for the
CHD populations),52 is the percentage of
simulated populations experiencing
multiple days in the simulated year
with an end-of-hour COHb level above
the same benchmarks. These two
dimensions of the dose estimates are
combined in the metric, person-days,
which is presented in Tables 6–15, 6–
16, 6–18 and 6–19 of the REA. The
metric, person-days, was the focus of
exposure/dose considerations in the last
review for which a previous version of
the exposure/dose model was used (59
FR 38914; USEPA, 1992).53 The persondays metric, which summarizes
occurrences across the number of
persons in the at-risk population
multiplied by the number of days in the
year, is a common cumulative measure
of population exposure/dose that
simultaneously takes into account both
the number of people affected and the
numbers of times each is affected.
As expected, given that current
ambient concentrations in the two study
areas are well below the CO standards,
the absolute COHb estimates under
current air quality conditions are
appreciably lower than the
corresponding estimates for conditions
of higher ambient CO concentrations in
which the current 8-hour standard is
just met (Table 1). Under ‘‘as is’’ (2006)
conditions in the two study areas, no
person in the simulated at-risk
populations is estimated to experience
any days in the year with end-of-hour
COHb concentrations at or above 3%
COHb, and less than 0.1% of the
simulated at-risk populations are
estimated to experience at least one endof-hour COHb concentration at or above
2% (Table 1).
Under conditions with higher ambient
CO concentrations simulated to just
meet the current 8-hour standard, the
portion of the simulated at-risk
populations estimated to experience
daily maximum end-of-hour COHb
levels at or above benchmarks is greater
in both study areas, with somewhat
higher percentages for the Denver study
area population (Table 1). In both study
areas, nonetheless, less than 1% of the
simulated at-risk populations is
estimated to experience a single day
with a maximum end-of hour COHb
level at or above 3% (Table 1) and no
person is estimated to experience more
than one such day in a year (Table 2).
Further, less than 0.1% of either
simulated population in either study
area is estimated to experience a single
day with maximum end-of-hour COHb
at or above 4%. A difference between
the study areas is more evident for
lower benchmarks, with less than 5% of
the simulated at-risk population in the
Denver study area and less than 1% of
the corresponding population in the Los
Angeles study area estimated to
experience any days with a maximum
end-of-hour COHb level at or above 2%
(Table 1). Appreciably smaller
percentages of the simulated at-risk
population were estimated to
experience more than one day with such
levels (Table 2). For example, less than
1.5% of the population is estimated to
experience more than one day in a year
with a maximum COHb level at or above
2.0%, and less than 0.1% are estimated
to experience six or more such days in
a year. Additionally, consistent with the
findings of the assessment performed for
the review completed in 1994, less than
0.1% of person-days for the simulated
at-risk populations were estimated to
have end-of-hour COHb levels at or
above 2% COHb (REA, Tables 6–18 and
6–19).
52 As described in the REA, the analyses
providing results for Table 2 were only performed
for the CHD populations, and so are not available
for the larger HD population, although as
mentioned above the results in terms of percentage
are expected to be similar.
53 As described in section II.C. above, pNEM, the
model used in the last review, employed a cohort-
based approach from which person-days were the
exposure and dose metrics (USEPA, 1992; Johnson
et al., 1992).
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TABLE 1—PORTION OF SIMULATED HD POPULATIONS WITH AT LEAST ONE DAILY MAXIMUM END-OF-HOUR COHb LEVEL
(ABSOLUTE) AT OR ABOVE INDICATED LEVELS UNDER AIR QUALITY CONDITIONS SIMULATED TO JUST MEET THE CURRENT STANDARD AND ‘‘AS IS’’ CONDITIONS
Percentage (%) of simulated HD population A
Los Angeles
(1-hr DV = 11.8 ppm)
≥
≥
≥
≥
≥
4.0%
3.0%
2.5%
2.0%
1.5%
‘‘As is’’ (2006) conditions
Just meeting current 8-hour standard
(8-hr DV = 9.4 ppm)
Daily maximum end-of-hour COHb
(absolute)
..............................................
..............................................
..............................................
..............................................
..............................................
Los Angeles
(8-hr DV = 5.6 ppm)
(1-hr DV = 8.2 ppm)
Denver
(1-hr DV = 16.2 ppm)
B<
0
0.1
B < 0.1
0.6
5.0
0.1
0.3
0.9
4.5
24.5
B<
Denver
(8-hr DV = 3.1 ppm)
(1-hr DV = 4.6 ppm)
0
B<
0
B<
0.1
1.6
0.1
1.2
A Drawn
from Tables 6–15 through 6–19 of the REA.
is used to represent nonzero estimates below 0.1%.
Abbreviations: hr = hour, DV = Design Value.
B <0.1
TABLE 2—PORTION OF SIMULATED CHD POPULATION WITH MULTIPLE DAYS OF MAXIMUM END-OF-HOUR COHb LEVELS
(ABSOLUTE) AT OR ABOVE THE INDICATED LEVELS UNDER AIR QUALITY CONDITIONS SIMULATED TO JUST MEET THE
CURRENT STANDARD AND ‘‘AS IS’’ CONDITIONS
Percentage (%) of simulated CHD population A
‘‘As is’’ (2006) conditions
Just meeting current 8-hour standard
(8-hr DV = 9.4 ppm)
Maximum end-of-hour
COHb level (absolute)
Los Angeles
(1-hr DV = 11.8 ppm)
≥2
days
≥
≥
≥
≥
3.0%
2.5%
2.0%
1.5%
..............................
..............................
..............................
..............................
B<
0
0.1
0.2
2.2
Los Angeles
(8-hr DV = 5.6 ppm)
(1-hr DV = 8.2 ppm)
Denver
(1-hr DV = 16.2 ppm)
≥4
days
≥6
days
0
0
B < 0.1
0.7
0
0
B < 0.1
0.5
≥2
days
≥4
days
0
0.1
1.4
11.2
B<
0
0
0.2
5.0
≥6
days
0
0
B < 0.1
3.3
≥2
days
0
0
0
0.5
≥4
days
Denver
(8-hr DV = 3.1 ppm)
(1-hr DV = 4.6 ppm)
≥6
days
0
0
0
0.2
0
0
0
0.1
≥2
days
≥4
days
≥6
days
0
0
B < 0.1
0.7
0
0
B < 0.1
0.5
0
0
B < 0.1
0.4
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A These estimates are drawn mainly from Figures 6–5 and 6–6 of the REA and represent the percentage of persons experiencing greater than
or equal to 2, 4, or 6 days with a maximum end-of-hour COHb (absolute) at or above the selected level.
B <0.1 is used to represent nonzero estimates below 0.1%.
As described above, the REA also
presented estimates of the portion of the
absolute COHb levels occurring in
response to the simulated ambient CO
exposures (i.e., that not derived from
endogenous CO production). The REA
refers to these estimates as the ambient
CO contribution to (absolute) COHb. As
observed with the absolute COHb
estimates under conditions just meeting
the standard, the results for the Denver
study area included larger percentages
of the population above specific COHb
ambient contribution levels than those
for the Los Angeles study area,
reflecting the study area difference in
1-hour peak concentrations. Although
estimates of population percentages for
multiple occurrences are not available
for the ambient contribution estimates,
it is expected that similar to those for
absolute COHb, they would be
appreciably lower than those shown
here for at least one occurrence.
Additionally, as mentioned above,
somewhat lower ambient contribution
estimates might be expected if other
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(nonambient) CO sources were present
in the simulations.
In considering the estimates of
population occurrences of daily
maximum COHb levels for REA
simulations under conditions just
meeting the current 8-hour standard
(presented in Tables 1 and 2 above), the
Policy Assessment notes that an
important contributing factor to the
higher percentages estimated for the
Denver study area population is the
occurrence of higher 1-hour peak
ambient CO concentrations and
consequent higher CO exposures than
occur in the corresponding Los Angeles
study area simulation (REA, section
6.1.2, Tables 6–7 and 6–10). The
difference in the peak 1-hour ambient
concentrations is illustrated by the
higher 1-hour design value for Denver as
compared to Los Angeles (16.2 ppm
versus 11.8 ppm), as noted in Tables 1
and 2. This difference, particularly at
the upper percentiles of the air quality
distribution, is likely driving the higher
population percentages estimated to
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experience higher 1-hour and 8-hour
exposures in the Denver study area as
compared to Los Angeles (REA, Tables
6–7 and 6–10).54 The situation is largely
reversed under ‘‘as is’’ conditions, where
the Los Angeles study area has generally
higher 1-hour and 8-hour ambient CO
concentrations as illustrated by the
design values for as is conditions in
Tables 1 and 2 above (as well as Tables
3–1 to 3–6, 5–14 and 5–16 of the REA),
and Los Angeles also has higher
percentages of people estimated to be
exposed to the higher exposure
concentrations (REA, Tables 6–1 and
6–4). Thus, the Policy Assessment
recognizes the impact on daily
maximum COHb levels of 1-hour
54 Other factors that contribute less to differences
in COHb estimates between the two study areas
include altitude, which slightly enhances
endogenous CO and COHb formation and can
enhance COHb formation induced by CO exposure
under resting conditions (ISA, p. 4–19), and design
aspects of the study areas with regard to spatial
variation in monitor CO concentrations and
population density near these monitors (REA,
section 7.2.2.1).
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ambient concentrations separate from
the impact of 8-hour average
concentrations, and takes note of this in
considering the REA results with regard
to the adequacy of the 1-hour standard.
The Policy Assessment concludes that,
taken together, the REA results indicate
occurrences of COHb levels above the
benchmarks considered here that are
associated with 1-hour ambient
concentrations that are not controlled by
the current suite of standards (PA,
section 2.2.2).
In considering the public health
implications of the quantitative dose
estimates, the Policy Assessment
considered the daily maximum end-ofhour levels estimated in the REA for
conditions just meeting the current suite
of standards in light of the effects
identified by the evidence at the COHb
benchmark levels considered. For
example, as a result of ambient CO
exposures occurring under air quality
conditions adjusted to just meet the
current 8-hour standard, the REA
estimates that 0.6 percent of the Los
Angeles and 4.5 percent of the Denver
study at-risk populations may
experience an occurrence of a daily
maximum end-of-hour COHb level at or
above 2% COHb, the low end of the
range of average COHb levels
experienced by the lower controlled
exposure group in the study by Allred
et al. (1989a, 1989b, 1991), while 0.2
and 1.4 percent, respectively, of the
simulated at-risk populations are
estimated to experience more than one
such occurrence. Additionally, less than
0.1 percent of the simulated populations
in either study area are estimated to
experience a COHb level similar to the
higher controlled exposure group (4%
COHb). As discussed in II.B.4 above, the
Policy Assessment recognized the
magnitude of the ‘‘time to onset’’
reductions observed in the study by
Allred et al. (1989a, 1989b, 1991), the
similarity of the study responses to
responses considered clinically
significant when evaluating medications
to treat angina from coronary artery
disease, and conclusions reached by the
independent review panel for the study
regarding the expectation that frequent
encounters in ‘‘everyday life’’ with
increased COHb levels on the order of
those tested in the study might limit
activity and affect quality of life (Allred
et al., 1989b, pp. 38, 92–94; 1991 AQCD,
p. 10–35), as well as considerations in
the review completed in 1994 and
assessment of the study findings in the
current ISA.
In considering public health
implications of the REA estimates, the
Policy Assessment also considered the
size of the at-risk populations simulated
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as described in section II.B.4 above,
recognizing that the U.S. population
with coronary heart disease, angina
pectoris (cardiac chest pain) or who
have experienced a heart attack in
combination with those with silent or
undiagnosed ischemia comprises a large
population represented by the REA
analyses and for which the COHb
benchmarks described above (based on
studies of CAD patients) are relevant,
that is, more susceptible to ambient CO
exposure when compared to the general
population (ISA, section 5.7). The
Policy Assessment also recognized that
the REA also simulated ambient CO
exposures for the larger HD population,
which may also be at increased risk of
CO-induced health effects (ISA, section
2.6.1), while noting that within this
broader group, implications of CO
exposures are more significant for those
persons for whom their disease state
affects their ability to compensate for
the hypoxia-related effects of CO (ISA,
section 4.4.4).
In summary, the Policy Assessment,
while noting the substantial size of the
population of individuals with CHD or
other heart diseases in the U.S.,
recognized that the REA results for
conditions just meeting the current
standards indicate a very small portion
of this population that might be
expected to experience more than one
occurrence of COHb above 2%, with
less than 0.1% of this population
expected to experience such a level on
as many as six days in a year or a single
occurrence as high as 4%, and 0% of the
population expected to experience more
than one occurrence above 4% COHb. In
light of the implications of the health
evidence discussed in section II.B.4 and
summarized above, the Policy
Assessment concluded that the public
health significance of these REA results
and conclusions regarding the extent to
which they are important from a public
health perspective depends in part on
public health policy judgments about
the public health significance of effects
at the COHb benchmark levels
considered and judgments about the
level of public health protection with an
adequate margin of safety.
c. Summary
With regard to the different elements
of the current standards, the Policy
Assessment concludes that it is
appropriate to continue to use
measurements of CO in accordance with
Federal reference methods as the
indicator to address effects associated
with exposure to ambient CO, and that
it is appropriate to continue to retain
standards with averaging times of 1 and
8 hours. With regard to form and level
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for these standards, the Policy
Assessment concludes that the
information available in this review
supports consideration of either
retaining the current suite of standards
or revising one or both standards.
The Policy Assessment concludes that
the extent to which the current
standards are judged to be adequate
depends on a variety of factors inclusive
of science policy judgments and public
health policy judgments. These factors
include public health policy judgments
concerning the appropriate COHb
benchmark levels on which to place
weight, as well as judgments on the
public health significance of the effects
that have been observed at the lowest
levels evaluated, particularly with
regard to relatively rare occurrences.
The factors relevant to judging the
adequacy of the standards also include
consideration of the uncertainty
associated with interpretation of the
epidemiological evidence as providing
information on ambient CO as distinct
from information on the mixture of
pollutants associated with traffic, and,
given this uncertainty, the weight to
place on interpretations of ambient CO
concentrations for the few
epidemiological studies available for air
quality conditions that did not exceed
the current standards. And, lastly these
factors include the interpretation of, and
decisions as to the weight to place on,
the results of the exposure assessment
for the two areas studied relative to each
other and to results from past
assessments, recognizing the
implementation of an improved
modeling approach and new input data,
as well as distinctions between the REA
simulations and resulting COHb
estimates and the response of COHb
levels to experimental CO exposure as
recorded in the controlled human
exposure studies.
The Policy Assessment conclusions
with regard to the adequacy of the
current standards are drawn from both
the evidence and from the exposure and
dose assessment, taking into
consideration related information,
limitations and uncertainties recognized
above. The combined consideration of
the body of evidence and the
quantitative exposure and dose
estimates are concluded to provide
support for a suite of standards at least
as protective as the current suite.
Further, the Policy Assessment
recognizes that conclusions regarding
the adequacy of the current standards
depend in part on public health policy
judgments identified above and
judgments about the level of public
health protection with an adequate
margin of safety.
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The Policy Assessment additionally
notes the influence that hourly ambient
CO concentrations well below the
current 1-hour standard may have on
ambient CO exposures and resultant
COHb levels under conditions just
meeting the 8-hour standard, as
indicated by the REA results. The REA
results are concluded to indicate the
potential for the current controlling 8hour standard to allow the occurrence of
1-hour ambient concentrations that
contribute to population estimates of
daily maximum COHb levels, that
depending on public health judgments
in the areas identified above, may be
considered to call into question the
adequacy of the 1-hour standard and
support consideration of revisions of
that standard in order to reduce the
likelihood of such occurrences in areas
just meeting the 8-hour standard. Thus,
the Policy Assessment concludes that
the combined consideration of the
evidence and quantitative estimates may
be viewed as providing support for
either retaining or revising the current
suite of standards.
The Policy Assessment conclusion
that it is appropriate to consider
retaining the current suite of standards
without revision is based on
consideration of the health effects
evidence in combination with the
results of the REA (PA, sections 2.2.1,
2.2.2, 2.3.2 and 2.3.3) and what may be
considered reasonable judgments on the
public health implications of the COHb
levels estimated to occur under the
current standard, the public health
significance of the CO effects being
considered, the weight to be given to
findings in the epidemiological studies
in locations where the current standards
are met, and advice from CASAC. Such
a conclusion takes into account the
long-standing body of evidence that
supports our understanding of the role
of COHb in eliciting effects in
susceptible populations, most
specifically the evidence for those with
cardiovascular disease, and gives
particular weight to findings of
controlled exposure studies of CAD
patients in which sensitive indicators of
myocardial ischemia were associated
with COHb levels resulting from shortduration, high-concentration CO
exposures. This conclusion also takes
into account uncertainties associated
with the differing circumstances of
ambient air CO exposures from the CO
exposures in the controlled human
exposure studies, as well as the unclear
public health significance of the size of
effects at the lowest studied exposures.
As in the last review, this conclusion
gives more weight to the significance of
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the effects observed in these studies at
somewhat higher COHb levels.
Additionally, this conclusion takes into
account judgments in interpreting the
public health implications of the REA
estimates of COHb associated with
ambient exposures based on the
application of our current exposure
modeling tools, and the size of the atrisk populations estimated to be
protected from experiencing daily
maximum COHb levels of potential
concern by the current standard.
Further, this conclusion considers the
uncertainties in quantitative
interpretations associated with the
epidemiological studies to be too great
for reliance on information from the few
studies where the current standards
were met as a basis for selection of
alternative standards.
In addition to considering retaining
the current suite of standards without
revision, the Policy Assessment also
concludes that it is reasonable to
consider revising the 1-hour standard
downward to provide protection from
infrequent short-duration peak ambient
concentrations that may not be
adequately provided by the current
standards. While the quantitative
analyses for this review focused
predominantly on the controlling,
8-hour standard, the analyses have
indicated the influential role of elevated
1-hour concentrations in contributing to
daily maximum COHb levels over
benchmark levels. In addition to the
REA results, the Policy Assessment
notes the health effects evidence from
1-hour controlled exposures, which
indicates the effects in susceptible
groups from such short duration
exposures. The Policy Assessment
interpreted the evidence and REA
estimates to indicate support for
consideration of a range of 1-hour
standard levels which would address
the potential for the current 8-hour
standard, as the controlling standard, to
‘‘average away’’ high short-duration
exposures that may contribute to
exposures of concern. Consequently, in
considering alternative standard levels,
the Policy Assessment focuses on the
1-hour standard as providing the most
direct approach for controlling the
likelihood of such occurrences.
With regard to a revision of the 1-hour
standard, the Policy Assessment
identified a range of 1-hour standard
levels from 15 to 5 ppm as being an
appropriate range for consideration.
These levels are in terms of a 99th
percentile daily maximum form,
averaged over three years, which the
Policy Assessment considers to provide
increased regulatory stability over the
current form. The Policy Assessment
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additionally takes note of CASAC’s
preference for a revision to the
standards to provide greater protection
and observes that the range of 1-hour
standard levels discussed is also the
range that the CASAC CO Panel
suggested was appropriate for
consideration.
The Policy Assessment indicates that
the upper part of the range of 1-hour
standard levels for consideration (11–15
ppm) was identified based on the
objective of providing generally
equivalent protection, nationally, to that
provided by current 8-hour standard
and potentially providing increased
protection in some areas, such as those
with relatively higher 1-hour peaks that
are allowed by the current 8-hour
standard. This part of the range is
estimated to generally correspond to
1-hour CO levels occurring under
conditions just meeting the current
8-hour standard based on current
relationships between 1-hour and 8hour average concentrations at current
U.S. monitoring locations (PA,
Appendix C). The Policy Assessment
states that selection of a 1-hour standard
within this upper part of the range
would be expected to allow for a
somewhat similar pattern of ambient CO
concentrations as the current,
controlling 8-hour standard, although
with explicit and independent control
against shorter-duration peak
concentrations which may contribute to
daily maximum COHb levels in those
exposed. Consideration of 1-hour
standard levels in this part of the range
would take into account the factors
recognized with regard to the option of
retaining the current standards. But it
would give greater weight to the
importance of limiting 1-hour
concentrations that are not controlled by
the current 8-hour standard but that
may contribute to exceedances of
relevant COHb benchmark levels.
The Policy Assessment also
concluded that, based on the evidence
and REA estimates and alternative
judgments regarding appropriate
population targets for maximum COHb
levels induced by ambient CO
exposures, it may be appropriate to
consider standard levels that provide
additional protection than that afforded
by the current standards against the
occurrence of short-duration peak
ambient CO exposures and associated
COHb levels. With this policy objective
in mind, the Policy Assessment also
described a rationale for consideration
of 1-hour standard levels of 9–10 ppm,
which comprise the middle part of the
range of 1-hour standard levels
suggested for consideration (PA, section
2.3.5). Additionally, the Policy
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Assessment identified 1-hour standard
levels of 5–8 ppm, in the lower part of
the range for consideration in light of
alternative judgments with regard to the
evidence and REA, including the weight
to place on public health significance of
smaller changes in COHb and the small
number of epidemiological studies in
areas meeting the current standards (PA,
section 2.3.5).
In considering the relative strength of
the evidence supporting each of the 3
parts of the range, the Policy
Assessment concludes that the upper
part of the range is most strongly
supported, both with regard to
judgments concerning adversity and
quantitative interpretation of the
epidemiological studies with regard to
ambient concentrations that may elicit
effects. For the lower parts of the range,
the Policy Assessment concludes that
support provided by the available
information is more limited, especially
for the lowest part of the range.
In conjunction with consideration of
a revised 1-hour standard, the Policy
Assessment, also concludes it is
appropriate to consider retaining a
standard with an 8-hour averaging time,
recognizing that, as when it was
established, the 8-hour standard
continues to provide protection from
multiple-hour ambient CO exposures
which may contribute to elevated COHb
levels and associated effects. In
conjunction with consideration of a
revised 1-hour standard, the Policy
Assessment additionally describes
revision to the 8-hour standard form
that may be appropriate to consider to
potentially provide greater regulatory
stability, with adjustment to level to
provide generally equivalent protection
as the current 8-hour standard or as a
revised 1-hour standard level (PA,
section 2.3.5). The range of 8-hour levels
identified in the Policy Assessment is
inclusive of the range of levels included
in the example policy option suggested
by CASAC.
3. CASAC Advice
In our consideration of the adequacy
of the current standards, in addition to
the evidence- and exposure/dose-based
information discussed above, we have
also considered the advice and
recommendations of CASAC, based on
their review of the ISA, the REA, and
the draft Policy Assessment, as well as
comments from the public on drafts of
these documents.55 In these reviews,
55 All written comments submitted to the Agency
thus far in this review are available in the docket
for this rulemaking, as are transcripts of the public
meetings held in conjunction with CASAC’s review
of the draft PA, of drafts of the REA, and of drafts
of the ISA.
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CASAC has provided an array of advice,
both with regard to interpreting the
scientific evidence and quantitative
exposure/dose assessment, as well as
with regard to consideration of the
adequacy of the current standards (Brain
and Samet, 2009, 2010a, 2010b, 2010c,
2010d).
In their review of the draft ISA,
CASAC noted various limitations and
uncertainties associated with the
evidence, particularly from the
epidemiological studies, as noted in
section II.D.2.1 above. For example, they
recognized limitations in representation
of population exposure to ambient CO.
Further they noted that ‘‘[t]he problem
of co-pollutants serving as potential
confounders is particularly problematic
for CO’’ and that CO may be serving as
a surrogate for a mixture of pollutants
generated by fossil fuel combustion
(Brain and Samet, 2010d) as well as
noting uncertainty regarding the
possibility for confounding effects of
indoor sources of CO (Brain and Samet,
2010c).
In their comments on the draft PA, the
CASAC CO Panel stated overall
agreement with staff’s conclusion that
the body of evidence and the
quantitative exposure and risk
assessment provide support for
retaining or revising the current 8-hour
standard. They additionally, however,
expressed a ‘‘preference’’ for a lower
standard and stated that ‘‘[i]f the
epidemiological evidence is given
additional weight, the conclusion could
be drawn that health effects are
occurring at levels below the current
standard, which would support the
tightening of the current standard.’’
Taking this into account, the Panel
further advised that ‘‘revisions that
result in lowering the standard should
be considered’’ (Brain and Samet,
2010c).
As noted in section I.C. above, the
final Policy Assessment was completed
with consideration of CASAC comments
on the draft document, as well as their
comments on the second draft REA, and
also public comments. Among the
revisions made in completing the final
Policy Assessment were those based on
additional consideration of the
epidemiological studies in light of
CASAC comments. Discussion of these
studies and the complications with
regard to their quantitative
interpretation is described in section
II.D.2.a above, in addition to other
evidence-based considerations
described in the final Policy
Assessment, and is considered in the
Administrator’s proposed conclusions
below.
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The few public comments received on
this review to date that have addressed
adequacy of the current standards
conveyed the view that the current
standards are adequate. In support of
this view, these commenters disagreed
with the REA estimates of in-vehicle
exposure concentrations and argued that
little weight should be given to the
epidemiological studies.
4. Administrator’s Proposed
Conclusions Concerning Adequacy
Based on the large body of evidence
concerning the public health impacts of
exposure to ambient CO available in this
review, the Administrator proposes that
the current primary standards provide
the requisite protection of public health
with an adequate margin of safety and
should be retained.
In considering the adequacy of the
current standards, the Administrator has
carefully considered the available
evidence and conclusions contained in
the Integrated Science Assessment; the
information, exposure/dose assessment,
rationale and conclusions presented in
the Policy Assessment; the advice and
recommendations from CASAC; and
public comments to date. In the
discussion below, the Administrator
considers first the long-standing
evidence base concerning effects
associated with exposure to CO,
including the controlled human
exposure studies, and the health
significance of responses observed at the
2% COHb level induced by 1-hour CO
exposure, as compared to higher COHb
levels. As at the time of the review
completed in 1994, the Administrator
also takes note of the results for the
modeling of exposures to ambient CO
under conditions simulated to just meet
the current, controlling, 8-hour standard
in two study areas, as described in the
REA and Policy Assessment, and the
public health significance of those
results. She also considers the newly
available and much-expanded
epidemiological evidence, including the
complexity associated with quantitative
interpretation of these studies,
particularly the few studies available in
areas where the current standards are
met. Further, the Administrator
considers the advice of CASAC,
including both their overall agreement
with the Policy Assessment conclusion
that the current evidence and
quantitative exposure and dose
estimates provide support for retaining
the current standard, as well as their
view that in light of the epidemiological
studies, revisions to lower the standards
should be considered and their
preference for a lower standard.
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As an initial matter, the Administrator
takes note of the Policy Assessment’s
consideration of the long-standing body
of evidence for CO, augmented in some
aspects since the last review, as
summarized in the current Integrated
Science Assessment. This long-standing
evidence base has established the
following key aspects of CO toxicity that
are relevant to this review as they were
to the review completed in 1994. The
common mechanism of CO health
effects involves binding of CO to
reduced iron in heme proteins and the
alteration of their function. Hypoxia
(reduced oxygen availability) induced
by increased COHb blood levels plays a
key role in eliciting CO-related health
effects. Accordingly, COHb is
commonly used as the bioindicator and
dose metric for evaluating CO exposure
and the potential for health effects.
Further, people with cardiovascular
disease are a key population at risk from
short-term ambient CO exposures.
With regard to the evidence of health
effects associated with ambient CO
exposures relevant to this review, the
Administrator first recognizes the
Integrated Science Assessment’s
conclusion that a causal relationship is
likely to exist between relevant shortterm exposures to CO and
cardiovascular morbidity. Further, as at
the time of the review completed in
1994, the Administrator takes particular
note of the evidence from controlled
human exposure studies that
demonstrates a reduction in time to
onset of exercise-induced markers of
myocardial ischemia in response to
increased COHb resulting from shortterm CO exposures, and recognizes the
greater significance accorded both to
larger reductions in time to myocardial
ischemia, and to more frequent
occurrences of myocardial ischemia.
The Administrator also recognizes the
uncertain health significance associated
with the smaller responses to the lowest
COHb level assessed in the study given
primary consideration in this review
(Allred et al., 1989a, 1989b, 1991) and
with single occurrences of such
responses. In the study by Allred et al.
(1989a, 1989b, 1991), a 4–5% reduction
in time (approximately 30 seconds) to
the onset of exercise-induced markers of
myocardial ischemia was associated
with the 2% COHb level induced by 1hour CO exposure. In considering the
significance of the magnitude of the
time decrement to onset of myocardial
ischemia observed at the 2% COHb
level induced by short-term CO
exposure, as well as the potential for
myocardial ischemia to lead to more
adverse outcomes, the EPA generally
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places less weight on the health
significance associated with infrequent
or rare occurrences of COHb levels at or
just above 2% as compared to that
associated with repeated occurrences
and occurrences of appreciably higher
COHb levels in response to short-term
CO exposures. For example, at the 4%
COHb level, the study by Allred et al.,
(1989a, 1989b, 1991) observed a 7–12%
reduction in time to the onset of
exercise-induced markers of myocardial
ischemia. The Administrator places
more weight on this greater reduction in
time to onset of exercise-induced
markers compared to the reduction in
time to onset at 2% COHb. The
Administrator also notes that at the time
of the 1994 review, an intermediate
level of approximately 3% COHb was
identified as a level at which adverse
effects had been demonstrated in
persons with angina. Now, as at the time
of the 1994 review, the Administrator
primarily considers the 2% COHb level,
resulting from 1-hour CO exposure, with
regard to providing a margin of safety
against effects of concern that have been
associated with higher COHb levels,
such as 3–4% COHb.
As at the time of the last review, the
Administrator additionally considers
the exposure and dose modeling results,
taking note of key limitations and
uncertainties associated with the
exposure and dose assessment
summarized in section II.C.2. above, and
in light of judgments above regarding
the health significance of findings from
the controlled human exposure studies,
placing less weight on the health
significance of infrequent or rare
occurrences of COHb levels at or just
above 2% and more weight to the
significance of repeated such
occurrences, as well as occurrences of
higher COHb levels. Under air quality
conditions just meeting the current,
controlling, 8-hour standard, the
assessment estimates that, as was the
case for the assessment conducted for
the 1994 review, daily maximum COHb
levels were below 2% COHb for more
than 99.9% of person-days in the study
areas evaluated. Further, under these
conditions, greater than 99.9% of the atrisk populations in the study areas
evaluated would not be expected to
experience daily maximum COHb levels
at or above 4% COHb, and more than
95% and 98.6% of those populations
would be expected to avoid single or
multiple occurrences, respectively, at or
just above 2% COHb.
The Administrator additionally takes
note of the now much-expanded
evidence base of epidemiological
studies, including the multiple studies
that observe positive associations
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between cardiovascular outcomes and
short-term ambient CO concentrations
across a range of CO concentrations,
including conditions above as well as
below the current NAAQS. She notes
particularly the Integrated Science
Assessment finding that these studies
are logically coherent with the larger,
long-standing health effects evidence
base for CO and the conclusions drawn
from it regarding cardiovascular diseaserelated susceptibility. In further
considering the epidemiological
evidence base with regard to the extent
to which it provides support for
conclusions regarding adequacy of the
current standards, the Administrator
takes note of CASAC’s conclusions that
‘‘[i]f the epidemiological evidence is
given additional weight, the conclusion
could be drawn that health effects are
occurring at levels below the current
standard, which would support the
tightening of the current standard’’
(Brain and Samet, 2010c). Additionally,
the Administrator places weight on the
final Policy Assessment consideration of
aspects that complicate quantitative
interpretation of the epidemiological
studies with regard to ambient
concentrations that might be eliciting
the reported health outcomes.
For purposes of evaluating the
adequacy of the current standards, there
are multiple complicating features of the
epidemiological evidence base, as
described in more detail in the final
Policy Assessment and in section
II.D.2.a, above. First, while a number of
studies observed positive associations of
cardiovascular disease-related outcomes
with short-term CO concentrations, very
few of these studies were conducted in
areas that met the current standards
throughout the period of study. In
addition, CASAC, in their advice
regarding interpretation of the currently
available evidence commented that
‘‘[t]he problem of co-pollutants serving
as potential confounders is particularly
problematic for CO’’ and that given the
currently low ambient CO levels, there
is a possibility that CO is acting as a
surrogate for a mix of pollutants
generated by fossil fuel combustion.
CASAC further stated that ‘‘[a] better
understanding of the possible role of copollutants is relevant to regulation’’
(Brain and Samet, 2010d). As described
in the Policy Assessment, there are also
uncertainties related to representation of
ambient CO exposures given the steep
concentration gradient near roadways,
as well as the prevalence of
measurements below the method
detection limit across the database.
CASAC additionally indicated the need
to consider the potential for
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confounding effects of indoor sources of
CO. As discussed in section II.D.2.a
above, the interpretation of
epidemiological studies for CO is
further complicated because, in contrast
to the situation for all other criteria
pollutants, the epidemiological studies
for CO use an exposure/dose metric (air
concentration) that differs from the
metric commonly used in the other key
CO health studies (COHb).
Although CASAC expressed a
preference for a lower standard, CASAC
also indicated that the current evidence
provides support for retaining the
current suite of standards. CASAC’s
recommendations appear to recognize
that their preference for a lower
standard was contingent on a judgment
as to the weight to be placed on the
epidemiological evidence. For the
reasons explained above, after full
consideration of CASAC’s advice and
the epidemiological evidence, as well as
its associated uncertainties and
limitations, the Administrator judges
those uncertainties and limitations to be
too great for the epidemiological
evidence to provide a basis for revising
the current standards.
In considering the adequacy of the
level of protection provided by the
current standards, the Administrator
notes the findings of the exposure and
dose assessment in light of
considerations discussed above
regarding the weight given to different
COHb levels and their frequency of
occurrence. The exposure and dose
assessment results indicate that only a
very small percentage of the at-risk
population is estimated to experience a
single occurrence in a year of daily
maximum COHb at or above 3.0%
COHb under conditions just meeting the
current 8-hour standard in the two
study areas evaluated, and no multiple
occurrences are estimated. The
Administrator also notes the results
indicating that only a small percentage
of the at-risk populations are estimated
to experience a single occurrence of 2%
COHb in a year under conditions just
meeting the standard, and still fewer
estimated to experience multiple such
occurrences. Taken together, the
Administrator considers the current
standard to provide a very high degree
of protection for the COHb levels and
associated health effects of concern, as
indicated by the extremely low
estimates of occurrences, and provides
slightly less but a still high degree of
protection for the effects associated with
lower COHb levels, the physiological
significance of which is less clear.
Additionally, the Administrator
proposes to conclude that consideration
of the epidemiological studies does not
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lead her to identify a need for any
greater protection. Thus, the
Administrator proposes to conclude that
the current suite of standards provides
an adequate margin of safety against
adverse effects associated with shortterm ambient CO exposures. For these
and all of the reasons discussed above,
and recognizing the CASAC conclusion
that, overall, the current evidence and
REA results provide support for
retaining the current standard, the
Administrator proposes to conclude that
the current suite of primary CO
standards are requisite to protect public
health with an adequate margin of safety
from effects of ambient CO.
The Administrator also solicits
comment on whether it would be
appropriate to revise the current
primary standards. The Administrator
takes note that, while CASAC indicated
their view that the evidence and
exposure and dose estimates provide
support for retaining the current
NAAQS, they also indicated their
preference for a lower standard. For
example, the CASAC CO Panel stated
that giving additional weight to the
epidemiological evidence would
support a tightening of the current
standard. The Administrator also takes
note of the Policy Assessment
conclusions, summarized in section
II.D.2.c above. Thus, in light of views
expressed by CASAC, as well as the
Policy Assessment conclusions, the
Administrator additionally solicits
comment on the appropriateness of
potential revisions to the form and level
of the standards. Any comments on
such revisions should include an
explanation of the basis for the
commenters’ views.
8185
protect the public welfare from any
known or anticipated adverse effects
associated with the presence of the
pollutant in ambient air.’’ Section 302(h)
of the Act defines effects on welfare in
part as ‘‘effects on soils, water, crops,
vegetation, man-made materials,
animals, weather, visibility, and
climate.’’ We first summarize the history
of EPA’s consideration of secondary
standards for CO in section III.A. In
section III.B, we then discuss the
evidence currently available for welfare
effects to inform decisions in this
review as to whether, and if so how, to
establish secondary standards for CO
based on public welfare considerations
as presented in the Policy Assessment.
Advice from CASAC is summarized in
section III.C. Lastly, the Administrator’s
proposed conclusions are presented in
section III.D.
E. Summary of Proposed Decisions on
Primary Standards
For the reasons discussed above, and
taking into account information and
assessments presented in the Integrated
Science Assessment and Policy
Assessment, the advice and
recommendations of CASAC, and the
public comments to date, the
Administrator proposes to retain the
existing suite of primary CO standards.
Additionally, the Administrator solicits
comment on the appropriateness of
revisions to the form and level of the
standards.
A. Background and Considerations in
Previous Reviews
With the establishment of the first
NAAQS for CO in 1971, secondary
standards were set identical to the
primary standards. CO was not shown
to produce detrimental effects on certain
higher plants at levels below 100 ppm.
The only significant welfare effect
identified for CO levels possibly
approaching those in ambient air was
inhibition of nitrogen fixation by
microorganisms in the root nodules of
legumes associated with CO levels of
100 ppm for one month (U.S. DHEW,
1970). In the first review of the CO
NAAQS, which was completed in 1985,
the threshold level for plant effects was
recognized to occur well above ambient
CO levels, such that vegetation damage
as a result of CO in ambient air was
concluded to be very unlikely (50 FR
37494). As a result, EPA concluded that
the evidence did not support
maintaining a secondary standard for
CO, as welfare-related effects had not
been documented to occur at ambient
concentrations (50 FR 37494). Based on
that conclusion, EPA revoked the
secondary standard. In the most recent
review of CO, which was completed in
1994, EPA again concluded there was
insufficient evidence of welfare effects
occurring at or near ambient levels to
support setting a secondary NAAQS (59
FR 38906). That review did not consider
climate-related effects.
III. Consideration of a Secondary
Standard
This section focuses on the key
policy-relevant issues related to the
review of public welfare-related effects
of CO. Under section 109(b) of the Clean
Air Act, a secondary standard is to be
established at a level ‘‘requisite to
B. Evidence-Based Considerations in the
Policy Assessment
To evaluate whether establishment of
a secondary standard for CO is
appropriate, we adopted an approach in
this review that builds upon the general
approach used in the last review and
reflects the broader body of evidence
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and information now available.
Considerations of the evidence available
in this review in the Policy Assessment
were organized around the following
overarching question: Does the currently
available scientific information provide
support for considering the
establishment of a secondary standard
for CO?
In considering this overarching
question, the Policy Assessment first
noted that the extensive literature
search performed for the current review
did not identify any evidence of
ecological effects of CO unrelated to
climate-related effects, at or near
ambient levels (ISA, section 1.3 and p.
1–3). However, ambient CO has been
associated with welfare effects related to
climate (ISA, section 3.3). Climaterelated effects of CO were considered for
the first time in the 2000 AQCD. The
greater focus on climate in the current
ISA relative to the 2000 AQCD reflects
comments from CASAC and increased
attention to the role of CO in climate
forcing (Brain and Samet, 2009; ISA,
section 3.3). Based on the current
evidence, the ISA concludes that ‘‘a
causal relationship exists between
current atmospheric concentrations of
CO and effects on climate’’ (ISA, section
2.2). Accordingly, the following
discussion focuses on climate-related
effects of CO in addressing the question
posed above.
As concluded in the Policy
Assessment, recently available
information does not alter the current
well-established understanding of the
role of urban and regional CO in
continental and global-scale chemistry,
as outlined in the 2000 AQCD (PA,
section 3.2). As recognized in the ISA,
CO is a weak direct contributor to
greenhouse warming. The most
significant effects on climate result
indirectly from CO chemistry, related to
the role of CO as the major atmospheric
sink for hydroxyl radicals. Increased
concentrations of CO can lead to
increased concentrations of other gases
whose loss processes also involve
hydroxyl radical chemistry. Some of
these gases, such as methane and ozone
(O3), contribute to the greenhouse effect
directly while others deplete
stratospheric O3 (ISA, section 3.3 and
p. 3–11).
Advances in modeling and
measurement have improved our
understanding of the relative
contribution of CO to climate forcing
(PA, section 3.2). CO contributes to
climate forcing through both direct
radiative forcing (RF) of CO, estimated
at 0.024 watts per square meter (W/m2)
by Sinha and Toumi (1996), and
indirect effects of CO on climate
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through methane, O3 and carbon
dioxide (Forster et al. 2007). The
Intergovernmental Panel on Climate
Change estimated the combined RF for
these indirect effects of CO to be ∼0.2
W/m2 over the period 1750–2005
(Forster et al., 2007), with more than
one-half of the forcing attributed to O3
formation (ISA, section 3.3 and p. 3–13).
As discussed in the Policy
Assessment, CO is classified as a shortlived climate forcing agent, prompting
CO emission reductions to be
considered as a possible strategy to
mitigate effects of global warming (PA,
section 3.2). However, in considering
the information presented in the ISA,
the Policy Assessment notes that it is
highly problematic to evaluate the
indirect effects of CO on climate due to
the spatial and temporal variation in
emissions and concentrations of CO and
due to the localized chemical
interdependencies involving CO,
methane, and O3 (ISA section 3.3 and p.
3–12). Most climate model simulations
are based on global-scale scenarios and
have a high degree of uncertainty
associated with short-lived climate
forcers such as CO (ISA, section 3.3 and
p. 3–16). These models may fail to
consider the local variations in climate
forcing due to emissions sources and
local meteorological patterns (ISA,
section 3.3 and p. 3–16). It is possible
to compute individual contributions to
RF of CO from separate emissions
sectors, although uncertainty in these
estimates has not been quantified (ISA,
section 3.3, p. 3–13 and Figure 3–7).
Uncertainties in the estimates of the
indirect RF from CO are noted in the
Policy Assessment to be related to
uncertainties in the chemical
interdependencies of CO and trace
gases, as described above. Large regional
variations in CO concentrations also
contribute to the uncertainties in the RF
from CO and other trace gases (ISA
section 3.3 and p. 3–12). Although
measurement of and techniques for
assessing climate forcing are improving,
estimates of RF still have approximately
50% uncertainty (ISA, section 3.3, and
p. 3–13).
In summary, the Policy Assessment
drew the following conclusions based
on the considerations identified above.
As an initial matter, with respect to nonclimate welfare effects, including
ecological effects and impacts to
vegetation, the Policy Assessment
concluded that there is no currently
available scientific information that
supports a CO secondary standard (PA,
section 3.4). Secondly, with respect to
climate-related effects, the Policy
Assessment recognized the evidence of
climate forcing effects associated with
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CO (ISA, sections 2.2 and 3.3), while
also noting that the available
information provides no basis for
estimating how localized changes in the
temporal and spatial patterns of ambient
CO likely to occur across the U.S. with
(or without) a secondary standard
would affect local, regional, or
nationwide changes in climate.
Moreover, more than half of the indirect
forcing effect of CO is attributable to O3
formation, and welfare-related effects of
O3 are more appropriately considered in
the context of the review of the O3
NAAQS, rather than in this CO NAAQS
review (PA, section 3.4). For these
reasons, the Policy Assessment
concluded that there is insufficient
information at this time to support the
consideration of a secondary standard
based on CO effects on climate
processes (PA, section 3.4).
C. CASAC Advice
In consideration of a secondary
standard, in addition to the evidence
discussed above, EPA has also
considered the advice and
recommendations of CASAC, based on
their review of the ISA, and the draft
Policy Assessment.56
In their comments on the draft Policy
Assessment, CASAC took note of the
substantial evidence that CO has
adverse effects on climate and
recommended that staff summarize
information that is currently lacking and
would assist in consideration of a
secondary standard in the future (ISA,
sections 3.2 and 3.3; Brain and Samet,
2010c).57 CASAC noted without
objection or disagreement the staff’s
conclusions that there is insufficient
information to support consideration of
a secondary standard at this time (Brain
and Samet, 2010c).
D. Administrator’s Proposed
Conclusions Concerning a Secondary
Standard
The proposed conclusions presented
here are based on the assessment and
integrative synthesis of the scientific
evidence presented in the ISA, building
on the evidence described in the 2000
AQCD, as well as staff consideration of
this evidence in the Policy Assessment
and CASAC advice. In considering
whether the currently available
scientific information supports setting a
secondary standard for CO, EPA takes
note of the Policy Assessment
consideration of the body of available
evidence (briefly summarized above in
56 Thus far in this review, no public comments
have been received regarding the secondary
standard.
57 This recommendation is addressed in section
3.5 of the Policy Assessment.
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section III.B). First, EPA concludes that
the currently available scientific
information with respect to non-climate
welfare effects, including ecological
effects and impacts to vegetation, does
not support a CO secondary standard.
Secondly, with respect to climaterelated effects, the EPA takes note of
staff considerations in the Policy
Assessment and concurs with staff
conclusions that this information is
insufficient at this time to provide
support for a CO secondary standard.
Thus, in considering the evidence, staff
considerations in the Policy Assessment
summarized here, as well as the views
of CASAC, summarized above, the
Administrator proposes to conclude that
no secondary standards should be set at
this time because, as in the past reviews,
having no standard is requisite to
protect public welfare from any known
or anticipated adverse effects from
ambient CO exposures.
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IV. Proposed Amendments to Ambient
Monitoring Requirements
The EPA is proposing changes to the
ambient air monitoring network design
requirements to support the NAAQS for
CO discussed above in section II.
Because the availability of ambient CO
monitoring data is an essential element
of the NAAQS implementation
framework, EPA is proposing to revise
the requirements for the ambient CO
monitoring network to include a
minimum set of monitors to provide
data for comparison to the NAAQS (i.e.,
for determining whether areas are
attaining the standards) in locations
near roads where CO emissions
associated with mobile source related
activity lead to increased ambient
concentrations. Under such
requirements, State, local, and Tribal
monitoring agencies (‘‘monitoring
agencies’’) collect ambient CO
monitoring data in accordance with the
monitoring requirements contained in
40 CFR parts 50, 53, and 58 for
comparison to the NAAQS and to meet
other objectives.
A. Monitoring Methods
Ambient air monitoring data are used
for various purposes, including
determining compliance with the
NAAQS. The use of reference methods
provides uniform, reproducible
measurements of pollutant
concentrations in ambient air.
Equivalent methods allow for the
introduction of new or alternative
technologies for the same purpose,
provided these methods produce
measurements directly comparable to
the reference methods. EPA has
established procedures for determining
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and designating reference and
equivalent methods, known as Federal
Reference Methods (FRMs) and Federal
Equivalent Methods (FEMs), at 40 CFR
part 53.
Ambient air monitoring data for CO
must be obtained using an FRM or an
FEM, as defined in 40 CFR parts 50 and
53, for such data to be comparable to the
NAAQS for CO. All CO monitoring
methods in use currently by State and
local monitoring agencies are EPAdesignated FRM analyzers (USEPA,
2010f). No FEM analyzer, i.e. one using
an alternative measurement principle,
has yet been designated by EPA for CO.
These continuous FRM analyzers have
been used in monitoring networks for
many years (USEPA, 2010f) and provide
CO monitoring data adequate for
determining CO NAAQS compliance.
The current list of all approved FRMs
capable of providing ambient CO data
for this purpose may be found on the
EPA Web site, https://www.epa.gov/ttn/
amtic/files/ambient/criteria/referenceequivalent-methods-list.pdf. Although
both the existing CO FRM in 40 CFR
part 50 and the FRM and FEM
designation requirements in part 53
remain adequate to support the CO
NAAQS, EPA is nevertheless proposing
editorial revisions to the CO FRM and
both technical and editorial revisions to
part 53, as discussed below.
1. Proposed Changes to Part 50,
Appendix C
Reference methods for criteria
pollutants are described in several
appendices to 40 CFR part 50; the CO
FRM is set forth in appendix C of part
50. A nondispersive infrared
photometry (NDIR) measurement
principle is formally prescribed as the
basis for the CO FRM. Appendix C
describes the technical nature of the
NDIR measurement principle stipulated
for FRM CO analyzers as well as two
acceptable calibration procedures for
CO FRM analyzers. It further requires
that an FRM analyzer must meet
specific performance, performance
testing, and other requirements set forth
in 40 CFR part 53.
From time to time, as pollutant
measurement technology advances, EPA
assesses the FRMs in the 40 CFR part 50
FRM appendices to determine if they
are still adequate or if improved or more
suitable measurement technology has
become available to better meet current
FRM needs as well as potential future
FRM requirements. The CO FRM was
originally promulgated on April 30,
1971 (36 FR 8186), in conjunction with
EPA’s establishment (originally as 42
CFR part 410) of the first NAAQS for six
pollutants (including CO) as now set
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forth in 40 CFR part 50. The method
was amended in 1982 and 1983 (47 FR
54922; 48 FR 17355) to incorporate
minor updates, but no substantive
changes in the fundamental NDIR
measurement technique have been made
since its original promulgation. (Those
updates included clarification that the
FRM NDIR measurement principle
encompassed the specific ‘‘gas filter
correlation’’ measurement technique
now used by many commercial FRM
analyzers.).
In connection with the current review
of the NAAQS for CO, EPA is proposing
to again update the existing CO FRM—
with no substantive changes—as
explained in further detail below. This
action is based on the scientific view
that the CO FRM, as originally
established and updated in the 1980’s,
is still fully adequate for FRM purposes
and is fulfilling that role well. Further,
the FRM is also well suited for use in
routine CO monitoring, and several high
quality FRM analyzer models have been
available for many years and continue to
be offered and supported by multiple
analyzer manufacturers. Finally, EPA
has determined that no new ambient CO
measurement technique has become
available that is superior to the NDIR
technique specified for the current FRM.
While EPA believes that the current
CO FRM is adequate, we also believe
that the existing CO FRM should be
improved by implementing updates to
clarify the language of some provisions,
to make the format match more closely
the format of more recently promulgated
automated FRMs, and to better reflect
the design and improved performance of
current, commercially available CO
FRM analyzers. EPA found that no
substantive changes were needed to the
basic NDIR FRM measurement
principle; therefore, the proposed
updates are of a very minor, editorial
nature. However, these proposed
changes are numerous enough so that
EPA is proposing to re-promulgate the
entire CO FRM in appendix C of 40 CFR
part 50, replacing the existing FRM
language with revised language.
2. Proposed Changes to Part 53
In close association with the proposed
editorial revision to the CO FRM
described above, EPA is also proposing
to update the performance requirements
for FRM CO analyzers currently
contained in 40 CFR part 53. These
requirements were established in the
1970’s, based primarily on the NDIR CO
measurement technology available at
that time. While the fundamental NDIR
measurement principle, as implemented
in commercial FRM analyzers, has
changed little over several decades,
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FRM analyzer performance has
improved markedly. Contemporary
advances in digital electronics, sensor
technology, and manufacturing
capabilities have permitted today’s
NDIR analyzers to exhibit substantially
improved measurement performance,
reliability, and operational convenience
at modest cost. This improved
instrument performance is not reflected
in the current performance requirements
for CO FRM analyzers specified in 40
CFR part 53, indicating a need for an
update to reflect that improved
performance. The updated part 53
performance requirements would also
apply to candidate FEM CO analyzers,
if any new, alternative CO measurement
technology should be developed.
As noted previously, the performance
of FRM analyzers designated under the
presently specified performance
requirements of Part 53 is fully adequate
for current monitoring needs. A review
of analyzer manufacturers’
specifications has determined that all
existing CO analyzer models currently
in use in the monitoring network
already meet the proposed new
requirements (for the standard
measurement range). Upgrading the
analyzer performance requirements to
be more consistent with the typical
performance capability available in
contemporary FRM analyzers would
ensure that newly designated FRM
analyzers will have this improved
measurement performance. Therefore,
EPA believes that the Part 53
requirements should be updated to be at
least commensurate with this typical
level of CO analyzer performance. In
addition, this modernization also
provides for optional, new performance
requirements applicable to lower, more
sensitive measurement ranges that
would support improved monitoring
data quality in areas of low CO
concentrations. Accordingly, EPA is
proposing to amend the performance
requirements applicable to CO FRMs
(and any new FEMs) set forth in subpart
B of 40 CFR part 53, as described in the
following discussion.
Subpart B of 40 CFR part 53
prescribes explicit test procedures to be
used for testing specified performance
aspects of candidate FRM and FEM
analyzers, along with the minimum
performance requirements that such
analyzers must meet to qualify for FRM
or FEM designation. These performance
requirements are specified in Table B–
1 of subpart B. Although Table B–1
covers candidate methods for SO2, O3,
CO, and NO2, the updates to Table B–
1 that EPA is now proposing would be
applicable only to candidate methods
for CO.
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Some updated performance
requirements are being proposed for
candidate CO analyzers that operate on
the specified ‘‘standard’’ measurement
range (0 to 50 ppm). This measurement
range would remain unchanged from
the existing requirements as it
appropriately addresses the monitoring
data needed for assessing attainment.
However, based on EPA’s review of the
performance of currently available CO
FRM analyzers (USEPA, 2010g), EPA is
proposing revised performance
requirements for CO analyzers in Table
B–1, as follows. The measurement noise
limit would be reduced from 0.5 to 0.2
ppm, and the lower detectable limit
would be reduced from 1 to 0.4 ppm.
Zero drift would be reduced from 1.0 to
0.5 ppm, and span drift would be
lowered from 2.5% to 2.0%. The
existing mid-span drift requirement,
tested at 20% of the upper range limit
(URL), would be withdrawn. EPA has
found that the mid-span drift
requirement is unnecessary for CO
instruments because the upper level
span drift (tested at 80% of the URL)
completely and much more accurately
defines analyzer span drift performance.
EPA proposes to change the lag time
allowed from 10 to 2 minutes, and the
rise and fall times from 5 to 2 minutes.
For precision, EPA proposes to change
the form of the precision limit
specifications from an absolute measure
(ppm) to percent (of the URL) for CO
analyzers and to set the limit at 1
percent for both 20% and 80% of the
URL. One percent is equivalent to the
existing limit value of 0.5 ppm for
precision for the standard (50 ppm)
measurement range. This change in
units from ppm to percent will make the
requirement responsive to higher and
lower measurement ranges (i.e., more
demanding for lower ranges).
The interference equivalent limit of 1
ppm for each interferent would not be
changed, but EPA proposes to withdraw
the existing limit requirement for the
total of all interferents. EPA has found
that the total interferent limit is
redundant with the individual
interferent limit for modern CO
analyzers.
These proposed new performance
requirements would apply only to
newly designated CO FRM or FEM
analyzers. Essentially all existing FRM
analyzers in use today, as noted
previously, are providing CO
monitoring data of adequate quality and
fulfill the proposed requirements. Thus,
existing FRM analyzers would not be
required to be re-tested and redesignated under the proposed new
requirements. All currently designated
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FRM analyzers would retain their
original FRM designations.
EPA recognizes that some CO
monitoring objectives (e.g., area-wide
monitoring away from major roads and
rural area surveillance) require
analyzers with lower, more sensitive
measurement ranges than the standard
range used for typical ambient
monitoring. Part 53 (40 CFR 53.20(b))
allows an FRM or FEM designation to
include lower ranges. To make such
lower-range measurements more
meaningful, EPA is proposing a separate
set of performance requirements that
would apply specifically to lower ranges
(i.e., those having a URL of less than 50
ppm) for CO analyzers. The proposed
additional, lower-range requirements
are listed in the proposed revised Table
B–1. A candidate analyzer that meets
the Table B–1 requirements for the
standard measurement range (0 to 50
ppm) could optionally have one or more
lower ranges included in its FRM or
FEM designation by further testing to
show that it also meets these proposed
supplemental, lower-range
requirements.
Although no substantive changes have
been determined to be needed to the test
procedures and associated provisions of
subpart B for CO, the detailed language
in many of the subpart B sections is in
need of significant updates,
clarifications, refinement, and (in a few
cases) correction of minor typographical
errors. EPA believes that these
provisions should be amended at this
time in its on-going, pollutant-bypollutant effort to bring the entire
content of subpart B fully up to date.
The proposed changes to the subpart
B text (apart from the changes proposed
for Table B–1 discussed above) are very
minor and almost entirely editorial in
nature, with no changes to the substance
of the requirements. However, because
these small changes are quite numerous,
EPA believes that it is expedient and
advantageous to propose replacement of
the subpart B text, in its entirety, with
the modified text. As discussed
previously, Table B–1, which sets forth
the pollutant-specific performance
limits and was recently amended as
applicable primarily to SO2 analyzers,
would be amended at this time only as
necessary and applicable to CO
analyzers. EPA intends to amend Table
B–1 for the remaining pollutant
methods (O3 and NO2) later, at such
time as each of those pollutants—along
with its associated FRM in part 50—is
addressed specifically.
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3. Implications for Air Monitoring
Networks
As noted previously, existing CO FRM
analyzers (no CO FEMs are presently
available) are currently providing
monitoring data that are adequate for
the current CO NAAQS. Although EPA
is proposing to re-promulgate the entire
CO FRM, the changes are minor, with
no substantive changes being proposed.
Thus, this action would have little, if
any, effect on existing air monitoring
networks. Similarly, EPA is proposing
revisions to subpart B of part 53, which
specifies the testing and performance
requirements for FRM and FEM
analyzers. Again, the changes are minor,
with the exception of the CO analyzer
performance requirements in Table B–1,
which EPA is proposing to make more
consistent with modern CO analyzers
representative of monitors used in the
current CO monitoring network. These
new requirements would be used for
designation of new CO FRM and FEM
analyzers. Existing EPA-designated
FRMs would be unaffected by the
proposed changes and would continue
to be designated. As most commercially
available CO FRM analyzers already
meet the proposed new performance
requirements, the cost of new CO
analyzers that would meet the proposed
new performance requirements would
not be increased by the proposed new
requirements. Therefore, there would be
no immediate impact on monitoring
agencies or on their CO monitoring
networks due to the proposed
amendments to the CO FRM and the
associated new performance
requirements proposed for subpart B.
In the longer term, the proposed new
performance requirements would ensure
that CO network monitors, going
forward, would maintain their improved
performance. Monitoring agencies
would benefit by having greater
confidence in their CO monitoring data
quality, particularly at the lower
ambient levels prevalent in most areas.
Further, the assurance of increased CO
data quality in years to come will
provide better databases to support
future reviews of the CO NAAQS.
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B. Network Design
The objectives of an ambient
monitoring network include the
collection and dissemination of air
pollution data to the general public in
a timely manner, to determine
compliance with ambient air quality
standards and the effectiveness of
emissions control strategies, and to
provide support for air pollution
research (40 CFR part 58, appendix D).
This section on CO network design
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provides background on the monitoring
network, information on the sources of
CO, information on factors affecting CO
emissions, and provides rationale for a
proposed network design intended to
support the implementation of the CO
NAAQS.
1. Background
EPA issued the first regulations for
ambient air quality surveillance,
codified at 40 CFR part 58, for criteria
pollutants including CO in 1979 (44 FR
27558, May 10, 1979). These 1979
regulations established a monitoring
network for CO (described in detail in
the CO Network Review and
Background document [Watkins and
Thompson, 2010]) that required two CO
monitors in urban areas with 500,000 or
more people. The first of these two
monitors was a ‘‘peak’’ concentration
monitor, intended to be located in areas
‘‘* * * around major traffic arteries and
near heavily traveled streets in
downtown areas.’’ The second monitor
was intended to represent a wider
geographic area, particularly at
neighborhood scales ‘‘where
concentration exposures are significant.’’
The 2006 monitoring rule (Revisions to
Ambient Air Monitoring Regulations, 71
FR 61236 (October 17, 2006)) removed
the minimum monitoring requirements
for the ambient CO monitoring network
that were promulgated in 1979.
However, the 2006 monitoring rule
maintained a requirement that if there
was ongoing CO monitoring in an area,
the area must have at least one monitor
located to measure maximum
concentration of CO in that area. The
2006 monitoring rule also included a
provision requiring the approval of the
EPA Regional Administrator before any
existing CO ambient monitors could be
removed. Finally, the 2006 monitoring
rule included a requirement for CO
monitors to be operated at all National
Core (NCore) multi-pollutant monitoring
stations; with approximately 80 stations
projected to have been operational
nationwide by January 1, 2011 to
support multi-pollutant monitoring
objectives.
An analysis of the available CO
monitoring network data in the Air
Quality System (AQS) database shows
that the network was comprised of
approximately 345 monitors during
2009. Information stored in AQS for
these monitors describes the most
frequently stated monitor objectives for
sites in the current CO network as
assessment of concentrations for general
population exposure and maximum
(highest) concentrations at the
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neighborhood scale.58 Approximately
56 of the monitors operating in 2009
were at microscale sites, a majority of
which were likely sites representing
‘‘peak’’ concentrations which were
required under the monitoring
regulations originally promulgated in
1979, intended to characterize mobile
source impacts in heavily traveled
downtown streets or near major arterial
roads (Watkins and Thompson, 2010).
The rest of these sites were likely being
operated to meet objectives including
NAAQS comparison, to support longterm trend determination, to meet State
Implementation Plan (SIP) and
maintenance plan requirements, and to
support ongoing health studies.
2. On-Road Mobile Sources
The REA for this review notes that
‘‘motor vehicle emissions continue to be
important contributors to ambient CO
concentrations’’ (REA, section 2.2).
Microenvironments influenced by onroad mobile sources are important
contributors to ambient CO exposures,
particularly in urban areas (REA, section
2.7), as indicated by personal exposure
studies that have generally shown that
the highest ambient CO exposure levels
occur while people are in transit in
motor vehicles (ISA, section 2.3).
Mobile sources are the primary
contributors to ambient CO emissions
because CO is formed by incomplete
combustion of carbon-containing fossil
fuels widely used in motor vehicles
(ISA, section 2.1; REA, section 3.3).
Further, spark-ignition engines (gasoline
or light-duty engines) have higher CO
emission rates than diesel engines
(heavy-duty engines) because they
typically operate closer to the
stoichiometric air-to-fuel ratio, have
58 Spatial scales are defined in 40 CFR part 58
Appendix D, Section 1.2, where the scales of
representativeness of most interest for the
monitoring site types include:
1. Microscale—Defines the concentration in air
volumes associated with area dimensions ranging
from several meters up to about 100 meters.
2. Middle scale—Defines the concentration
typical of areas up to several city blocks in size,
with dimensions ranging from about 100 meters to
0.5 kilometers.
3. Neighborhood scale—Defines concentrations
within some extended area of the city that has
relatively uniform land use with dimensions in the
0.5 to 4.0 kilometers range.
4. Urban scale—Defines concentrations within an
area of city-like dimensions, on the order of 4 to 50
kilometers. Within a city, the geographic placement
of sources may result in there being no single site
that can be said to represent air quality on an urban
scale. The neighborhood and urban scales have the
potential to overlap in applications that concern
secondarily formed or homogeneously distributed
air pollutants.
5. Regional scale—Defines usually a rural area of
reasonably homogeneous geography without large
sources, and extends from tens to hundreds of
kilometers.
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relatively short residence times at peak
combustion temperatures, and have very
rapid cooling of cylinder exhaust gases
(ISA, section 3.2.1).
Ambient CO concentrations have
significantly declined over the past 20
years, reflecting reductions in on-road
vehicle emissions, as described in
section II.A above. Overall, based on the
2002 National Emissions Inventory
(NEI), on-road mobile sources account
for approximately 52% of total CO
emissions. Based on the more recent
2005 NEI, the contributions of on-road
mobile sources has now risen to
approximately 60% of the total CO
emissions inventory (not counting
wildfire emissions) (https://
www.epa.gov/ttn/chief/
eiinformation.html). As described in
section II.A above, in some metropolitan
areas in the U.S., as much as 75% of all
CO emissions result from on-road
vehicle exhaust (ISA, section 2.1).
On-road vehicle CO emission rates
vary depending on operating conditions,
such as cold-start conditions and
operating speed. Under cold start
conditions, which only last for the first
minutes of vehicle operation, CO
emissions are higher due to temporary
ineffectiveness of vehicle exhaust
catalysts until they are heated to
optimal operating temperatures (ISA,
section 3.2.1; Singer et al., 1999).
Meanwhile, CO emissions also vary
based on vehicle operating speeds.
Increased CO emissions occur under
conditions of high acceleration, rapid
speed fluctuations, and heavy vehicle
loads (ISA, section 3.2.1). Studies have
found that CO emission rates for tested
light-duty vehicles are highest for
accelerating vehicles, second highest for
vehicles in cruise, third highest for
vehicles under deceleration, and fourth
highest (of four operating speed related
categories) for vehicles at idle (Frey et
al., 2003). High acceleration and rapid
speed fluctuations (such as acceleration
and deceleration occurring over a short
time period) can be associated with
congested, stop-and-go traffic
conditions.
3. Near-Road Environment
Information in the ISA and other peerreviewed literature suggest that
concentrations of mobile source
pollutants, such as CO, typically display
peak concentrations on or immediately
adjacent to roads, typically producing a
gradient in pollutant concentrations
where concentrations decrease with
increasing distance from roads (ISA,
section 2.3; ISA, section 3.5.1.3; Baldauf
et al., 2008; Clements et al., 2009;
Karner et al., 2010; Zhou and Levy,
2008; Zhu et al., 2002). CO is emitted by
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on-road mobile sources, and is not
secondarily formed in the near-road
environment like NO2 (which is both
primarily emitted and secondarily
formed in the near-road environment).
As a result, the near-road gradient for
CO can be quite steep, where
concentrations rapidly decay with
increasing distance away from the road
when compared to other mobile source
pollutants such as NO2. Karner et al.
(2010), synthesized findings from 41
near-road pollutant monitoring studies
ranging from 1978 through June 2008 to
advance the understanding of on-road
mobile source pollutant dispersion.
They performed two regression
analyses, one being a local regression of
background normalized concentrations
on distance, and the second being a
local regression of edge [of road]
normalized concentrations on distance.
These analyses found CO to have the
highest approximate edge-of-road peaks,
as much as 21 times background
concentrations, of all pollutants
analyzed, and also showed CO to have
one of the fastest decay rates with
increasing distance from the road,
showing as much as a 90 percent drop
in concentration 150 meters from the
edge of the road. A key reason in the
difference in decay rate with increasing
distance from roads between CO and
NO2 is due to how the two pollutants
are introduced into the near-road
environment. CO is a primary emission
from motor vehicle fuel combustion,
while NO2 is both emitted as a primary
emission and secondarily formed in the
near-road environment. The Integrated
Science Assessment for Oxides of
Nitrogen—Health Criteria (NOX ISA;
USEPA, 2008d) notes that the direct
emission of NO2 from mobile sources is
estimated to be only a few percent of the
total NOX emissions for light duty
gasoline vehicles, and from less than 10
percent up to 70 percent of the total
NOX emission from heavy duty diesel
vehicles, depending on the engine, the
use of emission control technologies
such as catalyzed diesel particulate
filters (CDPFs), and mode of vehicle
operation. Although much of the NOX
emissions are initially in the form of
NO, the rate of conversion of NO to NO2
is generally a rapid process (i.e., on the
order of a minute) (NOX ISA, section
2.2.2). Thus, more of the NO2 in the
near-road environment is a result of
secondary formation than from primary
emissions, while CO is almost
exclusively a result of direct emissions
from tailpipes.
Overall, the literature suggests that
CO concentrations generally return to
near-background levels within a few
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hundred meters from the road (Karner et
al., 2010; Zhou and Levy, 2007). The
actual concentrations of CO, and other
mobile source pollutants such as NOX
and particulate matter, that occur in the
near-road environment, and the rate of
decay of those pollutant concentrations
with increasing distance from the road,
are dependent on a number of variables
including traffic volume, traffic fleet
mix, roadway type, roadway design,
surrounding features, topography (or
terrain), and meteorology (Baldauf et al.,
2009; Baldauf et al., 2008; Clements et
al., 2009; Hagler et al., 2010; Heist et al.,
2009). EPA notes that these factors were
taken into account in the requirements
for the near-road NO2 monitoring
network, promulgated in February 2010
(75 FR 6474), which required near-road
NO2 sites to be selected with
consideration given to traffic volume
(via use of Annual Average Daily Traffic
[AADT] counts), fleet mix, congestion
patterns, roadway design, terrain, and
meteorology.
4. Urban Downtown Areas and Urban
Street Canyons
As noted above in section IV.B.2,
increased CO emissions occur under
operating conditions of high
acceleration, rapid speed fluctuations
(such as acceleration and deceleration
occurring over a short time period), and
increased vehicle loads (ISA, section
3.2.1). High acceleration and rapid
speed fluctuations can be associated
with congested traffic conditions, such
as stop-and-go traffic, which can occur
on heavily trafficked roads such as
highways, freeways, and along major
arterial roads, and also along roads with
multiple intersections in relatively close
proximity to each other. Thus, elevated
CO concentrations, relative to
surrounding background concentrations,
can occur not only along heavily
trafficked roads but also may be found
in urban downtown areas, where a
relatively higher number of roads exist
in an area (high density of roads per
unit area) and a relatively higher density
of roadway intersections exist in an area
(high roadway intersection per unit
area), which can lead to increased
occurrences of vehicles operating under
modes of high acceleration and/or rapid
speed fluctuations. Even though streets
in urban downtown areas may not
individually carry as much traffic as
larger highways, freeways, or major
arterials, the impact of many relatively
smaller streets in close proximity
carrying traffic experiencing periods of
high acceleration and/or rapid speed
fluctuations, or congested traffic, may
collectively contribute to elevated CO
concentrations in that downtown area.
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In addition to traffic undergoing
periods of high acceleration and/or
rapid speed fluctuations or experiencing
general traffic congestion, urban
downtown areas often have a number of
relatively tall buildings, typically in
close proximity to each other. Such
configurations of tall buildings in
relatively close proximity often create
urban features called urban canyons or
urban street canyons. Although the term
urban canyon, or urban street canyon, is
not formally defined, it can generally be
described as an urban feature,
resembling a natural canyon 59, where
streets or roads exist within dense
blocks of relatively tall buildings. These
urban features are of interest because, as
noted in the ISA, recent research by
Kaur and Nieuwenhuijsen (2009), and
Carlaw et al. (2007), suggest CO
concentrations are related to traffic
volume and fleet mix in the urban street
canyon environment, which can
influence potential exposures. EPA has
had monitoring requirements in the past
that characterized concentrations of CO
in heavily trafficked downtown streets,
i.e. ‘‘urban street canyons,’’ (Watkins and
Thompson, 2010), and notes such
locations may have still have relevance
going forward.
5. Meteorological and Topographical
Influences
In 2003, the National Research
Council (NRC) of the National
Academies published a document titled
Managing Carbon Monoxide Pollution
in Meteorological and Topographical
Problem Areas. This report noted how
drastically ambient CO concentrations
had dropped across the country from
the 1970s through the early 2000s, and
that some of the remaining areas of the
country that continued to have
relatively high concentrations tended to
have meteorological and topographical
characteristics that exacerbate pollution.
In particular, meteorological impacts
can concentrate pollutant build-up in an
area due to atmospheric inversions and
cold temperatures. Atmospheric
inversions essentially prevent pollutant
emissions in an area from dispersing
through vertical mixing. As explained
by the NRC (NRC, 2003), the extent to
which air mixes vertically depends on
how the air temperature changes with
altitude. Warm air is less dense than
cold air and thus more buoyant,
allowing surface air to mix upward as
relatively warmer air rises in the
atmosphere. However, if the vertical
temperature profile is such that
59 A natural canyon may be defined as a ‘‘deep
narrow valley with steep sides’’ (https://
www.merriam-webster.com/dictionary/canyon).
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temperatures decrease more slowly than
normal, or increase with height, vertical
mixing is inhibited. Inversions can be
caused by several different specific
phenomena, including surface based
cooling (for example, due to snow on
the ground), due to high altitudes, and
sometimes due to warm air advection at
higher altitudes.
The topographical impacts that can
lead to pollutant build-up in an area are
typically due to physical terrain features
that may aid in trapping pollution in an
area and/or contribute to meteorological
related inversions. An example of
topographical impacts might be an
urban area within a valley, or
surrounded on several sides by
mountain ranges. In such a case,
pollutant dispersion is inhibited in the
horizontal, with terrain features
effectively preventing mixing or
transport of pollution from a given area.
Further, in some cases both
meteorological and topographical
impacts can combine to exacerbate
pollutant build-up, such as in an area
partially surrounded by high terrain
which is also subject to inversions.
Although there is available
information on what can cause
increased potential for air pollutant
build-up due to meteorological and
topographical impacts, there are no
easily defined or applied criteria that
could be implemented nationally by
which all such locations could be
identified. Identification of such
locations would require a case-by-case
approach, where localized and detailed
information on terrain and meteorology
would be needed, plus an
understanding of the types and amounts
of emission sources in or around any
particular area.
6. Proposed Changes
Although EPA is proposing to retain
the current 8-hour and 1-hour CO
NAAQS, as discussed above in section
II, the Agency is proposing to revise the
requirements for the ambient CO
monitoring network to include a
minimum set of monitors to collect data
for comparison to the NAAQS in nearroadway locations where CO emissions
associated with mobile source related
activity lead to increased ambient
concentrations. The current network of
CO monitors, beyond those at NCore
sites, consists of monitors that were
established to meet the 1979 monitoring
rule requirements or which were placed
by State and local air monitoring
agencies to meet their own needs or
objectives. These additional monitors in
the current network are being operated
without being required under EPA
monitoring network regulations and as a
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result, they do not reflect a national
monitoring network design. In CASAC
comments on the second draft REA, the
CASAC panel, aware of the current CO
monitoring network configuration,
commented on the need to reconsider
CO monitoring network designs, stating
that ‘‘ * * * the approach for siting [CO]
monitors needs greater consideration.
More extensive coverage may be
warranted for areas where
concentrations may be more elevated,
such as near roadway locations’’ (Brain
and Samet, 2010b). Since there is a
strong relationship between CO
exposures and mobile source activity, as
described in the ISA and REA and
summarized in sections II.D.2 and
IV.B.2 above, primarily in the near-road
environment, EPA believes that some
CO monitors should be located near onroad mobile source activity, where
ambient concentrations are expected to
be more elevated, as noted by CASAC.
Accordingly, EPA is proposing to
require locating ambient CO monitors
which would produce data for
comparison to both the 8-hour and 1hour NAAQS at a subset of near-road
NO2 monitoring stations, which are
required under the Primary National
Ambient Air Quality Standards for
Nitrogen Dioxide; Final Rule (75 FR
6474), codified at 40 CFR part 58,
appendix D. This requirement would
support the objective of characterizing
ambient conditions at highly trafficked
near-road locations where elevated CO
concentrations (relative to surrounding
background concentrations) are
expected to occur.
The EPA is not proposing to require
dedicated CO monitoring sites to
characterize area-wide concentrations
representing neighborhood and larger
spatial scales. Based on a recent review
of the current CO monitoring network
(Watkins and Thompson, 2010), EPA
believes that the required NCore sites
and many of the existing monitoring
sites in the network provide data
representative of neighborhood and
larger spatial scales. These monitors are
useful in providing relative background
concentrations that, when compared to
near-road CO monitors, could aid in the
quantification of the near-road gradient
of CO in a given urban area. Between
the required NCore sites, and an
expectation based on experience that
some number of non-required area-wide
sites will continue to operate in the
future, we do not believe it is necessary
to propose a specific area-wide
monitoring requirement in this
rulemaking.
EPA believes that the proposed
network design which places CO
monitors at a subset of near-road NO2
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monitoring stations, as described in
detail in the following sections, will
require a relatively modest amount of
new resources by State and local air
agencies. Recalling that there were
approximately 345 CO monitors
operating in 2009, which were largely
discretionary monitors not operated
pursuant to Federal network design
requirements, the Agency believes that
a large majority of State and local air
agencies could meet the proposed
minimum monitoring requirements by
relocating an existing CO monitor to a
near-road NO2 monitoring station. In
some of these cases, the EPA believes
that the relocation of a CO monitor from
an existing stand-alone site to a multipollutant near-road NO2 site may also
result in additional operational cost
savings as, in some areas, the total
number of ambient monitoring sites for
which operational support is needed
could be reduced.
The EPA believes that the proposed
requirement for placing CO monitors at
some of the forthcoming near-road NO2
monitoring stations would provide an
important benefit by facilitating the
implementation of a more targeted
ambient CO monitoring network that
provides data for comparison to the
NAAQS, and is considerably smaller
than the CO network currently in
operation. EPA notes that under the
current regulation, the current CO
network is subject to a potentially
significant reduction in size (as detailed
in Watkins and Thompson, 2010) since
non-required CO monitoring stations
can be shut down upon State request, an
evaluation of historical data to evaluate
concentrations relative to the NAAQS
(per 40 CFR 58.14), and EPA Regional
Administrator approval. The occurrence
of such a reduction, however, would
lack the focus and direction needed to
ensure retention of a network with the
surveillance aspects essential to
supporting the implementation of the
CO NAAQS. In addition to ensuring that
an effective, modestly sized network
shall operate in the future, other
benefits of the proposed approach of colocating required CO monitors at
required near-road NO2 monitoring
stations include: ongoing comparison of
data to the NAAQS (for assessing
attainment), providing data that can
support health studies, providing data
that can be used in verification of
modeling results, and supporting the
implementation of the Agency’s multipollutant monitoring objectives.60
a. Monitoring for Carbon Monoxide at
Required Near-Road Nitrogen Dioxide
Monitoring Stations
Traffic volume on urban area roads is
much greater than in the more rural
areas of the country, as was noted in the
preamble to the final rule to the NO2
NAAQS (75 FR 6474). The U.S.
Department of Transportation Federal
Highway Administration’s Status of the
Nation’s Highways, Bridges, and
Transit: 2008 Conditions and
Performance document (https://
www.fhwa.dot.gov/policy/2008cpr/
es.htm#c2b) states that ‘‘while urban
mileage constitutes only 25.8 percent of
total (U.S.) mileage, these roads carried
66.3 percent of the 3 trillion vehicles
miles travelled (VMT) in the United
States in 2006.’’ The document also
states that urban interstate highways
made up only 0.8 percent of total (U.S.)
mileage but carried 16.3 percent of total
VMT.
The EPA notes that the 2007
American Housing Survey (https://
www.census.gov/hhes/www/housing/
ahs/ahs07/ahs07.html) estimates that
over 20 million housing units are within
300 feet (∼91 meters) of a 4-lane
highway, airport, or railroad. Using the
same survey, and considering that the
average number of residential occupants
in a housing unit is approximately 2.25,
it is estimated that at least 45 million
American citizens live near 4-lane
highways, airports, or railroads. Among
these three transportation facilities,
roads are the most pervasive of the
three, suggesting that a significant
number of people may live near major
roads. Furthermore, the 2008 American
Time Use Survey (https://www.bls.gov/
tus/) reported that the average U.S.
civilian spent over 70 minutes traveling
per day, and as recognized in section
II.D.2.b, the exposure and dose
assessment for this review found invehicle microenvironments to be those
with the highest ambient CO exposures.
Additionally, as described in the ISA,
PA and the REA, higher concentrations
are reported at locations immediately
near or on roadways as compared to
monitors somewhat removed from the
roadways (ISA, section 3.6; PA, section
2.2.1; REA, section 2.7). These locations
capture ambient concentrations that
contribute to ambient exposure
concentrations occurring in vehicles.
Accordingly, EPA believes that air
pollution monitors near major roads
will provide information pertaining to a
significant component of ambient CO
60 The EPA’s strategy encouraging multi-pollutant
monitoring is presented most recently in the
Ambient Air Monitoring Strategy for State, Local,
and Tribal Air Agencies document published
December 2008 (https://www.epa.gov/ttn/amtic/
files/ambient/monitorstrat/
AAMS%20for%20SLTs%20%20%20FINAL%20Dec%202008.pdf).
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exposure for a large portion of the
population that would otherwise not be
available.
The EPA recognizes the information
mentioned above regarding the
dominant role of mobile sources in the
national CO emission inventory
(discussed in section IV.B.2 above),
findings of the substantial near-road
concentration gradient, with elevated
CO concentrations in the near-road
environment compared to relative
background concentrations (discussed
in section IV.B.3 above), and the
importance of on-road mobile sources as
contributors to ambient CO exposures
particularly in urban areas (REA, section
2.7). We also note that (as referenced
above) CASAC indicated that additional
monitoring near roadways may be
warranted, and further stated ‘‘the Panel
found in some instances current
networks underestimated carbon
monoxide levels near roadways. Such
underestimation is a critical issue
* * *’’ (Brain and Samet, 2010b). In
light of this information, and the fact
that we generally expect the increased
levels of ambient CO (and the greatest
exposure to ambient CO) to occur nearroadways, EPA has determined that it is
appropriate to propose requiring CO
monitoring near heavily trafficked roads
in urban areas.
EPA additionally notes that near-road
NO2 monitoring sites will be placed
near highly trafficked roads in urban
areas, where elevated CO concentrations
due to on-road mobile sources are
known to occur, and that CASAC has
recommended that EPA establish a nearroad monitoring network that would
include sites with both NO2 and CO
monitors (Russell and Samet, 2010).
Accordingly, the EPA is proposing to
require CO monitors that will provide
data for comparison to the NAAQS to
operate at a subset of required near-road
NO2 monitoring stations, which are
required in 40 CFR part 58, appendix D.
Specifically, the EPA is proposing that
CO monitors be required in any required
near-road NO2 monitoring station in a
core based statistical area (CBSA) with
a population of 1,000,000 or more
persons. Based on 2009 U.S. Census
estimates (https://www.census.gov) and
Federal Highway Administration data
(https://www.fhwa.dot.gov/
policyinformation/tables/02.cfm)
applied to near-road NO2 network
design requirements (noted above),
there would be approximately 77 CO
monitoring sites required within nearroad NO2 monitoring stations within 53
CBSAs (including San Juan, PR).61
61 The near-road NO monitoring stations, which
2
are proposed to house required CO monitors, shall
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In this proposal, EPA concludes that,
given the strong relationship between
CO exposures and mobile source
activity, placing CO monitors at nearroad NO2 monitoring sites (which will
be near highly trafficked roads in urban
areas) is needed to fulfill the ambient
CO monitoring objectives identified in
section IV.B above. While having two
monitors within CBSAs of 500,000 or
more persons was the historical
monitoring requirement (discussed in
detail in Watkins and Thompson, 2010),
with declining ambient levels we
believe there is less likelihood for high
CO concentrations in relatively smaller
(in population) CBSAs. Accordingly, we
believe that proposing to require CO
monitoring only in near-road NO2
monitoring stations in CBSAs of
1,000,000 or more persons is a
reasonable approach that results in a
sufficient number of CO monitors near
highly trafficked roads in urban areas to
provide data for supporting the NAAQS,
for use in health studies, for model
validation, and to support multipollutant monitoring objectives. The
EPA solicits comment upon the
proposed requirement to require CO
monitors to operate within a subset of
required near-road NO2 monitoring
stations, specifically those in CBSAs
with 1,000,000 or more persons. The
EPA solicits comment on using
alternative population thresholds within
which CO monitors might be required to
operate in near-road NO2 monitoring
stations, e.g. CBSAs with 750,000 or
500,000 or more persons (which would
require approximately 92 and 126
monitors, respectively), in light of the
proposal to retain the existing CO
NAAQS. Finally, the EPA also solicits
comment on the merits of having any
minimum near-road monitoring
requirements for the CO monitoring
network.
b. Regional Administrator Authority
The EPA is proposing to include a
provision allowing the Regional
Administrators to have the discretion to
require monitoring above the minimum
requirements as necessary to address
situations where minimum monitoring
requirements are not sufficient to meet
monitoring objectives presented above
in section IV.B.1. The EPA recognizes
that minimum monitoring requirements
may not always result in a network
be selected per considerations spelled out in 40
CFR part 58, Appendix D, section 4.3.2(a)(1), which
prescribes site selection by ranking all road
segments in a CBSA by AADT and then identifying
a location or locations adjacent to those highest
ranked road segments, considering fleet mix,
roadway design, congestion patterns, terrain, and
meteorology.
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sufficient to fulfill one or more data
needs or monitoring objectives for a
particular area. An example of when an
EPA Regional Administrator might
require an additional monitor above the
minimum requirements is to address a
situation where data or other
information suggest that a stationary CO
source may be contributing to ground
level concentrations that are
approaching or exceeding the NAAQS.
A second example of where an EPA
Regional Administrator might require
additional monitoring is in otherwise
unmonitored urban downtown areas or
urban street canyons (as discussed
above in section IV.B.4), where data or
other information suggest CO
concentrations may be approaching or
exceeding the NAAQS. A third example
of where an EPA Regional
Administrator might require additional
monitoring is in unmonitored areas that
are subject to high ground level CO
concentrations particularly due to or
enhanced by topographical and
meteorological impacts, as discussed in
section IV.B.5 above. In all cases, the
Regional Administrator and the
responsible State or local air monitoring
agency should work together to design
and/or maintain the most appropriate
CO network to service monitoring
objectives and any particular variety of
data needs for an area.
c. Required Network Implementation
EPA proposes that state and, when
appropriate, local air monitoring
agencies provide a plan for deploying
required CO monitors by July 1, 2012.
We also propose that the ambient CO
monitoring network be physically
established no later than January 1,
2013. These dates correspond with the
implementation schedule of the
required near-road NO2 sites, which are
the same locations at which CO
monitors have been proposed to be
placed. EPA solicits comment on these
proposed implementation dates.
7. Microscale Carbon Monoxide Monitor
Siting Criteria
Carbon monoxide monitors that are
proposed to operate at near-road NO2
sites would likely be classified as
microscale-type sites, per the general
definition of microscale sites in 40 CFR
part 58, appendix D, section 1.2. Such
CO monitors would be paired with NO2
monitors required to have inlet probe
heights between 2 and 7 meters, and be
placed within 50 meters of a target road
segment. However, when the original
minimum monitoring requirements for
CO were introduced in the 1979
monitoring rule (44 FR 27571), the
siting criteria codified for microscale CO
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sites was specifically intended to
account for the installation of a nearroad site in street canyon or street
corridor locations. The specific siting
criteria for microscale CO sites,
currently located at 40 CFR part 58,
appendix E, section 6.2, and listed in
Table E–4 of appendix E, state that ‘‘the
inlet probes for microscale carbon
monoxide monitors that are being used
to measure concentrations near
roadways must be between 2.5 and 3.5
meters above ground level.’’ Likewise,
criteria currently located at 40 CFR part
58, appendix E, section 6.2, and listed
in Table E–4 of appendix E state that
microscale CO monitors are to be
between 2 and 10 meters from the edge
of the nearest traffic lane. These siting
criteria, originally developed in 1979,
were for use primarily in the urban
downtown and urban street canyon
environment. In that type of urban
environment, such specific and
relatively tight siting criteria were, and
still are, appropriate since there is often
little space within which ambient air
monitoring inlets can be accommodated
due to the typical dense configuration of
buildings. However, outside of the
urban downtown and urban street
canyon environment, such criteria may
be less applicable, considering site
placement logistics and site safety for
monitoring near the major highways,
freeways, interstates, and major arterials
that carry so much of today’s urban
traffic volume.
As noted above, the intent of existing
microscale CO siting criteria reflects the
historical intent of monitoring in urban
downtown areas and urban street
canyons. Since EPA is proposing that
CO monitors be required to operate at a
subset of near-road NO2 sites to
characterize roadway pollutant
concentrations the majority of which are
not anticipated to be in urban street
canyons, EPA has revisited the
appropriateness of the existing
microscale CO siting requirement,
particularly for near-road sites that exist
outside of the downtown urban areas
and urban street canyons. EPA
consulted on this issue with the CASAC
Ambient Air Monitoring and Methods
Subcommittee (CASAC–AAMMS) in
September, 2010. Specifically, EPA
requested feedback on whether it would
be appropriate to revise existing
microscale CO siting criteria to match
those of near-road NO2 monitors and
microscale PM2.5 monitors. In their
response to EPA, the CASAC–AAMMS
recommended ‘‘that sampling criteria for
CO and other monitors at sites installed
to monitor [at] near-road NO2 [sites]
match those for NO2.’’ The CASAC–
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AAMMS also noted that ‘‘sampling
configurations of existing microscale CO
monitors should be assessed in terms of
their own sampling objectives, and need
not necessarily conform to those of nearroad NO2 monitors’’ (Russell and Samet,
2010).
Based in part on the CASAC–AAMMS
comments above, EPA believes that it is
appropriate to revise the existing siting
criteria for microscale CO monitors to
encompass both the current criteria,
which are still appropriate when
monitoring in the urban downtown and/
or urban street canyon environment, as
well as the criteria for near-road NO2
sites. Therefore, EPA is proposing that
microscale CO siting criteria for probe
height and horizontal spacing be
changed to match those of near-road
NO2 sites as prescribed in 40 CFR part
58 appendix E, sections 2, 4(d), 6.4(a),
and Table E–4. Specifically, EPA
proposes to allow microscale CO
monitor inlet probes to be between 2
and 7 meters above the ground; that CO
monitor inlet probes be placed so they
have an unobstructed air flow, where no
obstacles exist at or above the height of
the monitor probe, between the monitor
probe and the outside nearest edge of
the traffic lanes of the target road
segment; and that the CO monitor inlet
probe shall be as near as practicable to
the outside nearest edge of the traffic
lanes of the target road segment, but
shall not be located at a distance greater
than 50 meters in the horizontal from
the outside nearest edge of the traffic
lanes of the target road segment.
These proposed siting criteria
encompass, or bracket, the current
allowable vertical and horizontal
spacing criteria for microscale CO sites,
which will allow current microscale CO
sites to continue to meet siting criteria.
EPA believes the proposed revision to
the microscale CO siting criteria
presented above will allow States to
meet siting criteria while co-locating
required microscale CO monitors with
required near-road NO2 monitors near
heavily trafficked roads outside of urban
downtown areas and urban street
canyons. EPA solicits comment upon
the revised CO siting requirements
proposed above. The Agency also
solicits comment upon whether it
should create two distinct sets of siting
criteria for microscale CO monitoring.
One set of siting criteria would be those
proposed above, while the second set
would be the current siting criteria, but
directed specifically to apply to existing
or new microscale CO monitoring sites
located in downtown urban areas and
urban street canyons.
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V. Statutory and Executive Order
Reviews
A. Executive Order 12866: Regulatory
Planning and Review
Under Executive Order 12866 (58 FR
51735, October 4, 1993), this action is a
‘‘significant regulatory action’’ because it
was deemed to ‘‘raise novel legal or
policy issues.’’ Accordingly, EPA
submitted this action to the Office of
Management and Budget (OMB) for
review under Executive Order 12866
and any changes made in response to
OMB recommendations have been
documented in the docket for this
action.
B. Paperwork Reduction Act
The information collection
requirements in this final rule have been
submitted for approval to the Office of
Management and Budget (OMB) under
the Paperwork Reduction Act, 44 U.S.C.
3501 et seq. The information collection
requirements are not enforceable until
OMB approves them. The Information
Collection Request (ICR) document
prepared by EPA for these revisions to
part 58 has been assigned EPA ICR
number 0940.23.
The information collected under 40
CFR part 53 (e.g., test results,
monitoring records, instruction manual,
and other associated information) is
needed to determine whether a
candidate method intended for use in
determining attainment of the National
Ambient Air Quality Standards
(NAAQS) in 40 CFR part 50 will meet
comparability requirements for
designation as a Federal reference
method (FRM) or Federal equivalent
method (FEM). We do not expect the
number of FRM or FEM determinations
to increase over the number that is
currently used to estimate burden
associated with CO FRM/FEM
determinations provided in the current
ICR for 40 CFR part 53 (EPA ICR
numbers 0940.23). As such, no change
in the burden estimate for 40 CFR part
53 has been made as part of this
rulemaking.
The information collected and
reported under 40 CFR part 58 is needed
to determine compliance with the
NAAQS, to characterize air quality and
associated health impacts, to develop
emissions control strategies, and to
measure progress for the air pollution
program. The amendments would revise
the technical requirements for CO
monitoring sites, require the relocation
or siting of ambient CO air monitors,
and the reporting of the collected
ambient CO monitoring data to EPA’s
Air Quality System (AQS). The annual
average reporting burden for the
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collection under 40 CFR part 58
(averaged over the first 3 years of this
ICR) for a network of 311 CO monitors
is $7,235,483. Burden is defined at 5
CFR 1320.3(b). State, local, and Tribal
entities are eligible for State assistance
grants provided by the Federal
government under the CAA which can
be used for monitors and related
activities.
An agency may not conduct or
sponsor, and a person is not required to
respond to, a collection of information
unless it displays a currently valid OMB
control number. The OMB control
numbers for EPA’s regulations in 40
CFR are listed in 40 CFR part 9.
To comment on the Agency’s need for
this information, the accuracy of the
provided burden estimates, and any
suggested methods for minimizing
respondent burden, EPA has established
a public docket for this rule, which
includes this ICR, under Docket ID
number EPA–HQ–OAR–2008–0015.
Submit any comments related to the ICR
to EPA and OMB. See ADDRESSES
section at the beginning of this notice
for where to submit comments to EPA.
Send comments to OMB at the Office of
Information and Regulatory Affairs,
Office of Management and Budget, 725
17th Street, NW, Washington, DC 20503,
Attention: Desk Office for EPA. Since
OMB is required to make a decision
concerning the ICR between 30 and 60
days after February 11, 2011, a comment
to OMB is best assured of having its full
effect if OMB receives it March 14,
2011. The final rule will respond to any
OMB or public comments on the
information collection requirements
contained in this proposal.
C. Regulatory Flexibility Act
The Regulatory Flexibility Act (RFA)
generally requires an agency to prepare
a regulatory flexibility analysis of any
rule subject to notice and comment
rulemaking requirements under the
Administrative Procedure Act or any
other statute unless the agency certifies
that the rule will not have a significant
economic impact on a substantial
number of small entities. Small entities
include small businesses, small
organizations, and small governmental
jurisdictions.
For purposes of assessing the impacts
of today’s proposed rule on small
entities, small entity is defined as: (1) A
small business that is a small industrial
entity as defined by the Small Business
Administration’s (SBA) regulations at 13
CFR 121.201; (2) a small governmental
jurisdiction that is a government of a
city, county, town, school district or
special district with a population of less
than 50,000; and (3) a small
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organization that is any not-for-profit
enterprise which is independently
owned and operated and is not
dominant in its field.
After considering the economic
impacts of this proposed rule on small
entities, I certify that this action will not
have a significant economic impact on
a substantial number of small entities.
This proposed rule will not impose any
requirements on small entities. Rather,
this rule proposes to retain existing
national standards for allowable
concentrations of CO in ambient air as
required by section 109 of the CAA. See
also American Trucking Associations v.
EPA. 175 F. 3d at 1044–45 (NAAQS do
not have significant impacts upon small
entities because NAAQS themselves
impose no regulations upon small
entities). Similarly, the proposed
amendments to 40 CFR part 58 address
the requirements for States to collect
information and report compliance with
the NAAQS and will not impose any
requirements on small entities. We
continue to be interested in the
potential impacts of the proposed rule
on small entities and welcome
comments on issues related to such
impacts.
D. Unfunded Mandates Reform Act
Title II of the Unfunded Mandates
Reform Act of 1995 (UMRA), Public
Law 104–4, establishes requirements for
Federal agencies to assess the effects of
their regulatory actions on State, local,
and Tribal governments and the private
sector. Unless otherwise prohibited by
law, under section 202 of the UMRA,
EPA generally must prepare a written
statement, including a cost-benefit
analysis, for proposed and final rules
with ‘‘Federal mandates’’ that may result
in expenditures to State, local, and
Tribal governments, in the aggregate, or
to the private sector, of $100 million or
more in any one year (adjusted for
inflation). Before promulgating an EPA
rule for which a written statement is
required under section 202, section 205
of the UMRA generally requires EPA to
identify and consider a reasonable
number of regulatory alternatives and to
adopt the least costly, most costeffective or least burdensome alternative
that achieves the objectives of the rule.
The provisions of section 205 do not
apply when they are inconsistent with
applicable law. Moreover, section 205
allows EPA to adopt an alternative other
than the least costly, most cost-effective
or least burdensome alternative if the
Administrator publishes with the final
rule an explanation why that alternative
was not adopted. Before EPA establishes
any regulatory requirements that may
significantly or uniquely affect small
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governments, including Tribal
governments, it must have developed
under section 203 of the UMRA a small
government agency plan. The plan must
provide for notifying potentially
affected small governments, enabling
officials of affected small governments
to have meaningful and timely input in
the development of EPA regulatory
proposals with significant Federal
intergovernmental mandates, and
informing, educating, and advising
small governments on compliance with
the regulatory requirements.
This action is not subject to the
requirements of sections 202 and 205 of
the UMRA. EPA has determined that
this proposed rule does not contain a
Federal mandate that may result in
expenditures of $100 million or more
for State, local, and Tribal governments,
in the aggregate, or the private sector in
any one year (adjusted for inflation).
This rule proposes to retain existing
national ambient air quality standards
for carbon monoxide. The expected
costs associated with the monitoring
requirements are described in EPA’s ICR
document, but those costs are expected
to be well less than $100 million
(adjusted for inflation) in the aggregate
for any year. Furthermore, as indicated
previously, in setting a NAAQS, EPA
cannot consider the economic or
technological feasibility of attaining
ambient air quality standards.
EPA has determined that this
proposed rule contains no regulatory
requirements that might significantly or
uniquely affect small governments
because it imposes no enforceable duty
on any small governments. Therefore,
this rule is not subject to the
requirements of section 203 of the
UMRA.
E. Executive Order 13132: Federalism
This action does not have federalism
implications. It will not have substantial
direct effects on the States, on the
relationship between the national
government and the States, or on the
distribution of power and
responsibilities among the various
levels of government, as specified in
Executive Order 13132. The rule does
not alter the relationship between the
Federal government and the States
regarding the establishment and
implementation of air quality
improvement programs as codified in
the CAA. Under section 109 of the CAA,
EPA is mandated to establish and
review NAAQS; however, CAA section
116 preserves the rights of States to
establish more stringent requirements if
deemed necessary by a State.
Furthermore, this proposed rule does
not impact CAA section 107 which
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establishes that the States have primary
responsibility for implementation of the
NAAQS. Finally, as noted in section D
(above) on UMRA, this rule does not
impose significant costs on State, local,
or Tribal governments or the private
sector. Thus, Executive Order 13132
does not apply to this rule.
However, as also noted in section D
(above) on UMRA, EPA recognizes that
States will have a substantial interest in
this rule, including the proposed air
quality surveillance requirements of 40
CFR part 58. Therefore, in the spirit of
Executive Order 13132, and consistent
with EPA policy to promote
communications between EPA and State
and local governments, EPA specifically
solicits comment on this proposed rule
from State and local officials.
F. Executive Order 13175: Consultation
and Coordination With Indian Tribal
Governments
This action does not have Tribal
implications, as specified in Executive
Order 13175 (65 FR 67249, November 9,
2000). It does not have a substantial
direct effect on one or more Indian
Tribes, since Tribes are not obligated to
adopt or implement any NAAQS. Thus,
Executive Order 13175 does not apply
to this rule.
G. Executive Order 13045: Protection of
Children From Environmental Health
and Safety Risks
This action is not subject to EO 13045
(62 FR 19885, April 23, 1997) because
it is not economically significant as
defined in EO 12866, and because the
Agency does not believe the
environmental health or safety risks
addressed by this action present a
disproportionate risk to children. This
action’s health and risk assessments are
described in sections II.C and II.D.2.b.
The public is invited to submit
comments or identify peer-reviewed
studies and data that assess effects of
early life exposures to CO.
H. Executive Order 13211: Actions That
Significantly Affect Energy Supply,
Distribution or Use
This action is not a ‘‘significant energy
action’’ as defined in Executive Order
13211, (66 FR 28355 (May 22, 2001))
because it is not likely to have a
significant adverse effect on the supply,
distribution, or use of energy. The rule
concerns the review of the NAAQS for
CO. The rule does not prescribe specific
pollution control strategies by which
these ambient standards will be met.
Such strategies are developed by States
on a case-by-case basis, and EPA cannot
predict whether the control options
selected by States will include
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distributors, or users.
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I. National Technology Transfer and
Advancement Act
Section 12(d) of the National
Technology Transfer and Advancement
Act of 1995 (NTTAA), Public Law 104–
113, section 12(d) (15 U.S.C. 272 note)
directs EPA to use voluntary consensus
standards in its regulatory activities
unless to do so would be inconsistent
with applicable law or otherwise
impractical. Voluntary consensus
standards are technical standards (e.g.,
materials specifications, test methods,
sampling procedures, and business
practices) that are developed or adopted
by voluntary consensus standards
bodies. The NTTAA directs EPA to
provide Congress, through OMB,
explanations when the Agency decides
not to use available and applicable
voluntary consensus standards.
This proposed rulemaking involves
technical standards with regard to
ambient monitoring of CO. We have not
identified any potentially applicable
voluntary consensus standards that
would adequately characterize ambient
CO concentrations for the purposes of
determining compliance with the CO
NAAQS and none have been brought to
our attention.
EPA welcomes comments on this
aspect of the proposed rule, and
specifically invites the public to identify
potentially applicable voluntary
consensus standards and to explain why
such standards should be used in the
regulation.
J. Executive Order 12898: Federal
Actions To Address Environmental
Justice in Minority Populations and
Low-Income Populations
Executive Order 12898 (59 FR 7629
(Feb. 16, 1994)) establishes Federal
executive policy on environmental
justice. Its main provision directs
Federal agencies, to the greatest extent
practicable and permitted by law, to
make environmental justice part of their
mission by identifying and addressing,
as appropriate, disproportionately high
and adverse human health or
environmental effects of their programs,
policies, and activities on minority
populations and low-income
populations in the United States.
EPA has determined that this
proposed rule will not have
disproportionately high and adverse
human health or environmental effects
on minority or low-income populations
because it does not affect the level of
protection provided to human health or
the environment. The action proposed
in this notice is to retain without
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revision the existing NAAQS for CO.
Therefore this action will not cause
increases in source emissions or air
concentrations.
References
Adams K.F.; Koch G.; Chatterjee B.; Goldstein
G.M.; O’Neil J.J.; Bromberg P.A.; Sheps
D.S.; McAllister S.; Price C.J.; Bissette J.
(1988) Acute elevation of blood
carboxyhemoglobin to 6% impairs exercise
performance and aggravates symptoms in
patients with ischemic heart disease. J.
Am. Coll. Cardiol. 12:900–909.
Allred E.N.; Bleecker E.R.; Chaitman B.R.;
Dahms T.E.; Gottlieb S.O.; Hackney J.D.;
Pagano M.; Selvester R.H.; Walden S.M.;
Warren J. (1989a) Short-term effects of
carbon monoxide exposure on the exercise
performance of subjects with coronary
artery disease. N. Engl. J. Med. 321:1426–
1432.
Allred E.N.; Bleecker, E.R.; Chaitman B.R.;
Dahms T.E.; Gottlieb S.O.; Hackney J.D.;
Hayes D.; Pagano M.; Selvester R.H.;
Walden S.M.; Warren J. (1989b) Acute
effects of carbon monoxide exposure on
individuals with coronary artery disease.
Cambridge, MA: Health Effects Institute;
research report no. 25.
Allred E.N.; Bleecker E.R.; Chaitman B.R.;
Dahms T.E.; Gottlieb S.O.; Hackney J.D.;
Pagano M.; Selvester R.H.; Walden S.M.;
Warren J. (1991) Effects of carbon
monoxide on myocardial ischemia.
Environ. Health Perspect. 91:89–132.
AHA. (2003) Heart and Stroke Facts.
American Heart Association, Dallas, TX.
Available at: https://
www.americanheart.org/downloadable/
heart/1056719919740HSFacts2003text.pdf
Anderson E.W.; Andelman R.J.; Strauch J.M.;
Fortuin N.J. and Knelson, J.H. (1973) Effect
of low level carbon monoxide exposure on
onset and duration of angina pectoris.
Annals of Internal Medicine 79:46–50.
Baldauf R.; Thoma E.; Hays M.; Shores R.;
Kinsey J.; Gullett B.; Kimbrough S.; Isakov
V.; Long T.; Snow R.; Khlystov A.;
Weinstein J.; Chen F.L.; Seila R.; Olson D.;
Gilmour I.; Cho S.H.; Watkins N.; Rowley
P.; Bang J. (2008a). Traffic and
meteorological impacts on near-road air
quality: Summary of methods and trends
from the Raleigh near-road study. J Air
Waste Manag Assoc, 58:865–878. 190239
Baldauf R.; Thoma E.; Khlystov A.; Isakov V.;
Bowker G.; Long T.; Snow R. (2008b).
Impacts of noise barriers on near-road air
quality. Atmos Environ, 42: 7502–7507.
Baldauf, R.; Watkins, N.; Heist, D.; Bailey, C.;
Rowley, P.; Shores, R. (2009) Near-road air
quality monitoring: Factors affecting
network design and interpretation of data.
Air Qual. Atmos. Health. 2:1–9.
Basan M.M. (1990) Letter to the Editor. N.
Engl J Med 332:272.
Bell M.L.; Peng R.D.; Dominici F.; Samet J.M.
(2009) Emergency admissions for
cardiovascular disease and ambient levels
of carbon monoxide: Results for 126 U.S.
urban counties, 1999–2005. Circulation,
120:949–955.
Bissette J.; Carr G.; Koch G.G.; Adams K.F.;
Sheps D.S. (1986) Analysis of (events/time
at risk) ratios from two period crossover
PO 00000
Frm 00040
Fmt 4701
Sfmt 4702
studies. In: American Statistical
Association 1986 proceedings of the
Biopharmaceutical Section; August;
Chicago, IL., Washington, DC: American
Statistical Asssociation ; pp. 104–108.
Brain, J.D. (2009) Letter from Dr. J.D. Brain
to Administrator Lisa Jackson. Re:
Consultation on EPA’s Carbon Monoxide
National Ambient Air Quality Standards:
Scope and Methods Plan for Health Risk
and Exposure Assessment. CASAC–09–
012. July 14, 2009.
Brain J. and Samet J. (2009) Letter from Drs.
J.D. Brain and J.M. Samet to Administrator
Lisa Jackson. Re: Review of EPA’s
Integrated Science Assessment for Carbon
Monoxide (First External Review Draft)
EPA–CASAC–09–011. June 24, 2009.
Brain, J.D. and Samet, J.M. (2010a) Letter
from Drs. J.D. Brain and J.M. Samet to
Administrator Lisa Jackson. Re: Review of
the Risk and Exposure Assessment to
Support the Review of the Carbon
Monoxide (CO) Primary National Ambient
Air Quality Standards: First External
Review Draft. EPA–CASAC–10–006.
February 12, 2010.
Brain J.D. and Samet J.M. (2010b) Letter from
Drs. J.D. Brain and J.M. Samet to
Administrator Lisa Jackson. Re: Review of
the Risk and Exposure Assessment to
Support the Review of the Carbon
Monoxide (CO) Primary National Ambient
Air Quality Standards: Second External
Review Draft. EPA–CASAC–10–012. May
19, 2010.
Brain J.D. and Samet J.M. (2010c) Letter from
Drs. J.D. Brain and J.M. Samet to
Administrator Lisa Jackson. Re: Review of
the Policy Assessment for the Review of
the Carbon Monoxide National Ambient
Air Quality Standards (NAAQS): External
Review Draft. EPA–CASAC–10–013. June
8, 2010.
Brain J.D. and Samet J.M. (2010d) Letter from
Drs. J.D. Brain and J.M. Samet to
Administrator Lisa Jackson. Re: Review of
Integrated Science Assessment for Carbon
Monoxide (Second External Review Draft).
EPA–CASAC–10–005. January 20, 2010.
Carslaw D.C.; Beevers S.D.; Tate J.E. (2007)
Modelling and assessing trends in trafficrelated emissions using a generalised
additive modelling approach. Atmos
Environ, 41: 5289–5299.
Clements, A.; Jia, Y.; Denbleyker, A.;
McDonald-Buller, E.; Fraser, M.; Allen, D.;
Collins, D.; Michel, E.; Pudota, J.; Sullivan,
D.; Zhu, Y. (2009) Air pollutant
concentrations near three Texas roadways,
part II: Chemical characterization and
transformation of pollutants. Atmos
Environ. 43:4523–4534.
Forster P.; Ramaswamy V.; Artaxo P.;
Berntsen T.; Betts R.; Fahey D.W.;
Haywood J.; Lean J.; Lowe D.C.; Myhre G.;
Nganga J.; Prinn R.; Raga G.; Schultz M.;
Van Dorland R. (2007) Changes in
atmospheric constituents and in radiative
forcing, Chapter 2. In Solomon S; Qin D;
Manning M; Chen Z; Marquis M; Averyt
KB; Tignor M; Miller HL (Ed.) IPCC Fourth
Assessment Report (AR4): Climate Change
2007: Working Group I Report: The
Physical Science Basis. (pp. 129–234).
Cambridge, U.K. and New York, NY:
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Federal Register / Vol. 76, No. 29 / Friday, February 11, 2011 / Proposed Rules
Intergovernmental Panel on Climate
Change; Cambridge University Press.
Frey, C.; Unal, A.; Rouphail, N.M.; Colyar,
J.D. (2003) On-Road Measurement of
Vehicle Tailpipe Emissions Using a
Portable Instrument. J. Air & Waste
Manage. Assoc. 53:992–1002.
Hagler, G.; Thoma, E.; Baldauf, R. (2010)
High-Resolution Mobile Monitoring of
Carbon Monoxide and Ultrafine Particle
Concentrations in a Near-Road
Environment. Air & Waste Manage. Assoc.,
60:328–336.
Henderson R. (2008) Letter from Dr. Rogene
Henderson, Chairman, Clean Air Scientific
Advisory Committee, to Administrator
Stephen Johnson. Re: Consultation on
EPA’s Draft Plan for Review of the Primary
NAAQS for Carbon Monoxide CASAC–08–
013. June 12, 2008.
Heist, D.; Perry, S.; Brixey, L. (2009). A wind
tunnel study of the effect of roadway
configurations on the dispersion of trafficrelated pollution. Atmos Environ, 43:5101–
5111.
Johnson T.; Capel J.; Paul R.; Wijnberg L.
(1992) Estimation of Carbon Monoxide
Exposure and associated
Carboxyhemoglobin levels in Denver
Residents Using a Probabalistic verion of
NEM, prepared by International
Technology for U.S. EPA, Office of Air
Quality Planning and Standards, Durham,
NC, Contract No. 68–D0–0062.
Johnson T.; Mihlan G.; LaPointe J.; Fletcher
K.; Capel J. (2000) Estimation of Carbon
Monoxide Exposures and Associated
Carboxyhemoglobin Levels for Residents of
Denver and Los Angeles Using pNEM/CO
(Version 2.1). Report prepared by ICF
Consulting and TRJ Environmental, Inc.,
under EPA Contract No. 68–D6–0064. U.S.
Environmental Protection Agency,
Research Triangle Park, North Carolina.
Available at: https://www.epa.gov/ttn/fera/
human_related.html. June 2000.
Karner A.A.; Eisinger D.S.; Niemeier D.A.
(2010) Near-Roadway Air Quality:
Synthesizing the Findings from Real-World
Data. Environ Sci Technol 44: 5334–5344.
Kaur S; Nieuwenhuijsen MJ (2009).
Determinants of personal exposure to
PM2.5, ultrafine particle counts, and CO in
a transport microenvironment. Environ Sci
Technol, 43: 4737–4743.
Kleinman M.T.; Davidson D.M.; Vandagriff
R.B.; Caiozzo V.J.; Whittenberger J.L. (1989)
Effects of short-term exposure to carbon
monoxide in subjects with coronary artery
disease. Arch. Environ. Health 44:361–369.
Kleinman M.T.; Leaf D.A.; Kelly E.; Caiozzo
V.; Osann K.; O’Niell T. (1998) Urban
angina in the mountains: Effects of carbon
monoxide and mild hypoxemia on subjects
with chronic stable angina. Arch. Environ.
Health 53:388–397.
Koken P.J.M.; Piver W.T.; Ye F.; Elixhauser
A.; Olsen L.M.; Portier C.J. (2003)
Temperature, air pollution, and
hospitalization for cardiovascular diseases
among elderly people in Denver. Environ
Health Perspect, 111:1312–1317.
Lippmann, M. (1984) CASAC Findings and
Recommendations on the Scientific Basis
for a Revised NAAQS for Carbon
Monoxide. [Letter to W.D. Ruckelshous,
EPA Administrator]. May 17.
VerDate Mar<15>2010
20:50 Feb 10, 2011
Jkt 223001
Linn W.S.; Szlachcic Y.; Gong H. Jr; Kinney
P.L.; Berhane K.T. (2000) Air pollution and
daily hospital admissions in metropolitan
Los Angeles. Environ Health Perspect,
108:427–434.
McClellan R.O. (1991) Letter from Dr. Roger
McClellan, Chairman, Clean Air Scientific
Advisory Committee, to William K. Reilly,
EPA Administrator, July 17, 1991.
McClellan R.O. (1992) Letter from Dr. Roger
McClellan, Chairman, Clean Air Scientific
Advisory Committee, to William K. Reilly,
EPA Administrator, August 1, 1992.
Mann J.K.; Tager I.B.; Lurmann F.; Segal M.;
Quesenberry C.P. Jr; Lugg M.M.; Shan J.;
Van den Eeden S.K. (2002) Air pollution
and hospital admissions for ischemic heart
disease in persons with congestive heart
failure or arrhythmia. Environ Health
Perspect, 110:1247–1252.
Metzger K.B.; Tolbert P.E.; Klein M.; Peel J.L.;
Flanders W.D.; Todd K.H.; Mulholland
J.A.; Ryan P.B.; Frumkin H. (2004) Ambient
air pollution and cardiovascular emergency
department visits. Epidemiology, 15:46–56.
National Research Council. (2003) Managing
Carbon Monoxide Pollution in
Meteorological and Topographical Problem
Areas. The National Academies Press,
Washington, D.C.
Peel J.L.; Metzger K.B.; Klein M.; Flanders
W.D.; Mulholland J.A.; Tolbert P.E. (2007)
Ambient air pollution and cardiovascular
emergency department visits in potentially
sensitive groups. Am J Epidemiol,
165:625–633.
Russell T. and Samet J. (2010) Letter to
Administrator Johnson from Drs. Russell
and Samet, Clean Air Scientific Advisory
Committee. Subject: Review of the ‘‘Nearroad Guidance Document—Outline’’ and
‘‘Near-road Monitoring Pilot Study
Objectives and Approach’’ EPA–CASAC–
11–001. November 24, 2010.
Sheps D.S.; Adams K.F. Jr.; Bromberg P.A.;
Goldstein G.M.; O’Neil J.J.; Horstman D.;
Koch G. (1987) Lack of effect of low levels
of carboxyhemoglobin on cardiovascular
function in patients with ischemic heart
disease. Arch. Environ. Health 42:108–116.
Singer, B.C.; Kirchstetter, T.W.; Harley, R.A.;
Kendall, G.R.; Hesson, J.M. (1999) A FuelBased Approach to Estimating Motor
Vehicle Cold-Start Emissions. Air & Waste
Manage. Assoc. 49:125–135.
Sinha A. and Toumi R. (1996) A comparison
of climate forcings due to
chlorofluorocarbons and carbon monoxide.
Geophys Res Lett, 23: 65–68.
Symons J.M.; Wang L.; Guallar E.; Howell E.;
Dominici F.; Schwab M.; Ange B.A.; Samet
J.; Ondov J.; Harrison D.; Geyh A. (2006) A
case-crossover study of fine particulate
matter air pollution and onset of congestive
heart failure symptom exacerbation leading
to hospitalization. Am J Epidemiol,
164:421–433.
Tolbert P.E.; Klein M.; Peel J.L.; Sarnat S.E.;
Sarnat J.A. (2007) Multipollutant modeling
issues in a study of ambient air quality and
emergency department visits in Atlanta. J
Expo Sci Environ Epidemiol, 17:S29–S35.
U.S. Department of Health, Education and
Welfare. (1970) Air Quality Criteria for
Carbon Monoxide. National Air Pollution
Control Administration, Public Health
Service, Washington, DC.
PO 00000
Frm 00041
Fmt 4701
Sfmt 4702
8197
U.S. Environmental Protection Agency.
(1979a) Air Quality Criteria for Carbon
Monoxide. Office of Health and
Environmental Assessment, Environmental
Criteria and Assessment Office, Research
Triangle Park, NC. EPA–600/8–79–022.
U.S. Environmental Protection Agency.
(1979b) Assessment of Adverse Health
Effects from Carbon Monoxide and
Implications for Possible Modifications of
the Standard. Office of Air Quality
Planning and Standards, Research Triangle
Park, NC.
U.S. Environmental Protection Agency.
(1984a) Revised Evaluation of Health
Effects Associated with Carbon Monoxide
Exposure: An Addendum to the 1979 EPA
Air Quality Criteria Document for Carbon
Monoxide. Office of Health and
Environmental Assessment, Environmental
Criteria and Assessment Office, Research
Triangle Park, NC. EPA–600/8–83–033F
U.S. Environmental Protection Agency.
(1984b) Review of the NAAQS for Carbon
Monoxide: Reassessment of Scientific and
Technical Information. Office of Air
Quality Planning and Standards, Research
Triangle Park. NC. EPA–450/584–904
U.S. Environmental Protection Agency.
(1991) Air Quality Criteria for Carbon
Monoxide. Office of Health and
Environmental Assessment, Environmental
Criteria and Assessment Office, Research
Triangle Park, NC. EPA/600/8–90/045F.
Available at: https://www.epa.gov/ttn/
naaqs/standards/co/s_co_pr.html
U.S. Environmental Protection Agency.
(1992) Review of the National Ambient Air
Quality Standards for Carbon Monoxide:
Assessment of Scientific and Technical
Information, OAQPS Staff Paper. Office of
Air Quality Planning and Standards,
Research Triangle Park, NC. EPA/452/R–
92–004.
U.S. Environmental Protection Agency.
(2000) Air Quality Criteria for Carbon
Monoxide. National Center for
Environmental Assessment, Office of
Research and Development, Research
Triangle Park, NC. EPA/600/P–99/001F.
Available at: https://cfpub.epa.gov/ncea/
cfm/recordisplay.cfm?deid=18163
U.S. Environmental Protection Agency.
(2005) Review of the National Ambient Air
Quality Standards for Particulate Matter:
Policy Assessment of Scientific and
Technical Information, OAQPS Staff Paper.
Office of Air Quality Planning and
Standards, Research Triangle Park, NC.
EPA–452/R–05–005a.
U.S. Environmental Protection Agency.
(2007) Review of the National Ambient Air
Quality Standards for Ozone: Policy
Assessment of Scientific and Technical
Information, OAQPS Staff Paper. Office of
Air Quality Planning and Standards,
Research Triangle Park, NC. EPA–452/R–
07–007.
U.S. Environmental Protection Agency.
(2008a) Draft Plan for Review of the
National Ambient Air Quality Standards
for Carbon Monoxide. Also known as Draft
Integrated Review Plan. National Center for
Environmental Assessment and Office of
Air Quality Planning and Standards,
Research Triangle Park, NC. EPA–452/D–
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8198
Federal Register / Vol. 76, No. 29 / Friday, February 11, 2011 / Proposed Rules
08–001. Available at: https://www.epa.gov/
ttn/naaqs/standards/co/s_co_cr_pd.html.
U.S. Environmental Protection Agency.
(2008b) Plan for Review of the National
Ambient Air Quality Standards for Carbon
Monoxide. Also known as Integrated
Review Plan. National Center for
Environmental Assessment and Office of
Air Quality Planning and Standards,
Research Triangle Park, NC. EPA–452/R–
08–005. Available at: https://www.epa.gov/
ttn/naaqs/standards/co/s_co_cr_pd.html.
U.S. Environmental Protection Agency.
(2008c) Risk and Exposure Assessment to
Support the Review of the NO2 Primary
National Ambient Air Quality Standard.
Office of Air Quality Planning and
Standards, Research Triangle Park, NC.
EPA–452/R–08–008a.
U.S. Environmental Protection Agency.
(2008d) Integrated Science Assessment for
Oxides of Nitrogen—Health Criteria (Final
Report). EPA/600/R–08/071.
U.S. Environmental Protection Agency.
(2009a) Integrated Science Assessment for
Carbon Monoxide, First External Review
Draft. National Center for Environmental
Assessment, Research Triangle Park, NC.
EPA/600/R–00/019. Available at: https://
www.epa.gov/ttn/naaqs/standards/co/s_
co_cr_isa.html
U.S. Environmental Protection Agency.
(2009b) Integrated Science Assessment for
Carbon Monoxide, Second External Review
Draft. National Center for Environmental
Assessment, Research Triangle Park, NC.
EPA/600/R–09/019B. Available at: https://
www.epa.gov/ttn/naaqs/standards/co/s_
co_cr_isa.html
U.S. Environmental Protection Agency.
(2009c) Carbon Monoxide National
Ambient Air Quality Standards: Scope and
Methods Plan for Health Risk and
Exposure Assessment. Draft. Office of Air
Quality Planning and Standards, Research
Triangle Park, NC. EPA–452/R–09–004.
Available at: https://www.epa.gov/ttn/
naaqs/standards/co/s_co_cr_pd.html
U.S. Environmental Protection Agency.
(2009d) Risk and Exposure Assessment to
Support the Review of the Carbon
Monoxide Primary National Ambient Air
Quality Standards, First External Review
Draft. Office of Air Quality Planning and
Standards, Research Triangle Park, NC.
EPA–452/P–09–008. Available at: https://
www.epa.gov/ttn/naaqs/standards/co/s_
co_cr_rea.html
U.S. Environmental Protection Agency.
(2009e) Risk and Exposure Assessment to
Support the Review of the SO2 Primary
National Ambient Air Quality Standard.
Office of Air Quality Planning and
Standards, Research Triangle Park, NC.
EPA–452/R–09–007. August 2009.
Available at https://www.epa.gov/ttn/naaqs/
standards/so2/data/
200908SO2REAFinalReport.pdf.
U.S. Environmental Protection Agency.
(2009f) Integrated Science Assessment for
Particulate Matter (Final Report). National
Center for Environmental Assessment,
Research Triangle Park, NC. EPA/600/R–
08/139F.
U.S. Environmental Protection Agency.
(2010a) Integrated Science Assessment for
VerDate Mar<15>2010
20:50 Feb 10, 2011
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Carbon Monoxide. National Center for
Environmental Assessment, Research
Triangle Park, NC. EPA/600/R–09/019F.
Available at: https://www.epa.gov/ttn/
naaqs/standards/co/s_co_cr_isa.html
U.S. Environmental Protection Agency.
(2010b) Quantitative Risk and Exposure
Assessment for Carbon Monoxide—
Amended. Office of Air Quality Planning
and Standards, Research Triangle Park, NC.
EPA–452/R–10–009. Available at: https://
www.epa.gov/ttn/naaqs/standards/co/s_
co_cr_rea.html
U.S. Environmental Protection Agency.
(2010c) Policy Assessment for the Review
of the Carbon Monoxide National Ambient
Air Quality Standards. Office of Air
Quality Planning and Standards, Research
Triangle Park, NC. EPA 452/R–10–007.
Available at: https://www.epa.gov/ttn/
naaqs/standards/co/s_co_cr_pa.html
U.S. Environmental Protection Agency.
(2010d) Risk and Exposure Assessment to
Support the Review of the Carbon
Monoxide Primary National Ambient Air
Quality Standards, Second External
Review Draft, U.S Environmental
Protection Agency, Research Triangle Park,
NC, report no. EPA–452/P–10–004.
Available at: https://www.epa.gov/ttn/
naaqs/standards/co/s_co_cr_rea.html
U.S. Environmental Protection Agency.
(2010e) Policy Assessment for the Review
of the Carbon Monoxide National Ambient
Air Quality Standards, External Review
Draft. Office of Air Quality Planning and
Standards, Research Triangle Park, NC.
EPA–452/P–10–005. Available at: https://
www.epa.gov/ttn/naaqs/standards/co/
s_co_cr_pa.html
U.S. Environmental Protection Agency.
(2010f) Analyzer Use in U.S. Monitoring
Networks. Spreadsheet of air monitoring
method utilization in U.S. monitoring
networks by year. Office of Air Quality
Planning and Standards.
U.S. Environmental Protection Agency.
(2010g) Modern CO Instrument
Performance Data. Spreadsheet of
performance data for existing FRM
analyzers. Office of Research and
Development.
Watkins N. and Thompson R. (2010) CO
Monitoring Network Background and
Review. Memorandum to the Carbon
Monoxide NAAQS Review Docket. EPA–
HQ–OAR–2008–0015.
Wellenius G.A.; Bateson T.F.; Mittleman
M.A.; Schwartz J. (2005) Particulate air
pollution and the rate of hospitalization for
congestive heart failure among Medicare
beneficiaries in Pittsburgh, Pennsylvania.
Am J Epidemiol 161:1030–1036.
WHO (2008). Harmonization Project
Document No. 6. Part 1: Guidance
document on characterizing and
communicating uncertainty in exposure
assessment. Available at: https://
www.who.int/ipcs/methods/
harmonization/areas/exposure/en/.
Zanobetti A. and Schwartz J. (2001) Are
diabetics more susceptible to the health
effects of airborne particles? Am J Respir.
Crit. Care Med. 164:831–833.
Zhou, Y and Levy J.I. (2007) Factors
influencing the spatial extent of mobile
PO 00000
Frm 00042
Fmt 4701
Sfmt 4702
source air pollution impacts: A metaanalysis. BMC Public Health, 7:89.
Zhu Y.; Hinds W.C.; Kim S.; Shen S.; Sioutas
C. (2002) Study of ultrafine particles near
a major highway with heavy-duty diesel
traffic. Atmos Environ, 36: 4323–4335.
List of Subjects
40 CFR Part 50
Environmental protection, Air
pollution control, Carbon monoxide,
Lead, Nitrogen dioxide, Ozone,
Particulate matter, Sulfur oxides.
40 CFR Part 53
Environmental protection,
Administrative practice and procedure,
Air pollution control, Intergovernmental
relations, Reporting and recordkeeping
requirements.
40 CFR Part 58
Environmental protection,
Administrative practice and procedure,
Air pollution control, Intergovernmental
relations, Reporting and recordkeeping
requirements.
Dated: January 28, 2011.
Lisa P. Jackson,
Administrator.
For the reasons stated in the
preamble, title 40, chapter I of the Code
of Federal Regulations is proposed to be
amended as follows:
PART 50—NATIONAL PRIMARY AND
SECONDARY AMBIENT AIR QUALITY
STANDARDS
1. The authority citation for part 50
continues to read as follows:
Authority: 42 U.S.C. 7401, et seq.
2. Appendix C to Part 50 is revised to
read as follows:
Appendix C to Part 50—Measurement
Principle and Calibration Procedure for
the Measurement of Carbon Monoxide
in the Atmosphere (Non-Dispersive
Infrared Photometry)
1.0 Applicability
1.1 This non-dispersive infrared
photometry (NDIR) Federal Reference
Method (FRM) provides measurements
of the concentration of carbon monoxide
(CO) in ambient air for determining
compliance with the primary and
secondary National Ambient Air Quality
Standards (NAAQS) for CO as specified
in § 50.8 of this chapter. The method is
applicable to continuous sampling and
measurement of ambient CO
concentrations suitable for determining
1-hour or longer average measurements.
The method may also provide
measurements of shorter averaging
times, subject to specific analyzer
performance limitations. Additional CO
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monitoring quality assurance
procedures and guidance are provided
in part 58, appendix A, of this chapter
and in reference 1 of this appendix C.
2.0 Measurement Principle
2.1 Measurements of CO in ambient
air are based on automated
measurement of the absorption of
infrared radiation by CO in an ambient
air sample drawn into an analyzer
employing non-wavelength-dispersive,
infrared photometry (NDIR method).
Infrared energy from a source in the
photometer is passed through a cell
containing the air sample to be
analyzed, and the quantitative
absorption of energy by CO in the
sample cell is measured by a suitable
detector. The photometer is sensitized
specifically to CO by employing CO gas
in a filter cell in the optical path, which,
when compared to a differential optical
path without a CO filter cell, limits the
measured absorption to one or more of
the characteristic wavelengths at which
CO strongly absorbs. However, to meet
measurement performance
requirements, various optical filters,
reference cells, rotating gas filter cells,
dual-beam configurations, moisture
traps, or other means may also be used
to further enhance sensitivity and
stability of the photometer and to
minimize potential measurement
interference from water vapor, carbon
dioxide (CO2), or other species. Also,
various schemes may be used to provide
a suitable zero reference for the
photometer, and optional automatic
compensation may be provided for the
actual pressure and temperature of the
air sample in the measurement cell. The
measured infrared absorption, converted
to a digital reading or an electrical
output signal, indicates the measured
CO concentration.
2.2 The measurement system is
calibrated by referencing the analyzer’s
CO measurements to CO concentration
standards traceable to a National
Institute of Standards and Technology
(NIST) primary standard for CO, as
described in the associated calibration
procedure specified in section 4 of this
reference method.
2.3 An analyzer implementing this
measurement principle will be
considered a reference method only if it
has been designated as a reference
method in accordance with part 53 of
this chapter.
2.4 Sampling considerations. The
use of a particle filter in the sample inlet
line of a CO FRM analyzer is optional
and left to the discretion of the user
unless such a filter is specified or
recommended by the analyzer
manufacturer in the analyzer’s
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associated operation or instruction
manual.
3.0
Interferences
3.1 The NDIR measurement
principle is potentially susceptible to
interference from water vapor and CO2,
which have some infrared absorption at
wavelengths in common with CO and
normally exist in the atmosphere.
Various instrumental techniques can be
used to effectively minimize these
interferences.
4.0
Calibration Procedures
4.1 Principle. Either of two methods
may be selected for dynamic multipoint
calibration of FRM CO analyzers, using
test gases of accurately known CO
concentrations obtained from one or
more compressed gas cylinders certified
as CO transfer standards:
4.1.1 Dilution method: A single
certified standard cylinder of CO is
quantitatively diluted as necessary with
zero air to obtain the various calibration
concentration standards needed.
4.1.2 Multiple-cylinder method:
Multiple, individually certified standard
cylinders of CO are used for each of the
various calibration concentration
standards needed.
4.1.3 Additional information on
calibration may be found in Section 12
of reference 1.
4.2 Apparatus. The major
components and typical configurations
of the calibration systems for the two
calibration methods are shown in
Figures 1 and 2. Either system may be
made up using common laboratory
components, or it may be a
commercially manufactured system. In
either case, the principal components
are as follows:
4.2.1 CO standard gas flow control
and measurement devices (or a
combined device) capable of regulating
and maintaining the standard gas flow
rate constant to within ± 2 percent and
measuring the gas flow rate accurate to
within ± 2 percent, properly calibrated
to a NIST-traceable standard.
4.2.2 For the dilution method
(Figure 1), dilution air flow control and
measurement devices (or a combined
device) capable of regulating and
maintaining the air flow rate constant to
within ± 2 percent and measuring the
air flow rate accurate to within ± 2
percent, properly calibrated to a NISTtraceable standard.
4.2.3 Standard gas pressure
regulator(s) for the standard CO
cylinder(s), suitable for use with a highpressure CO gas cylinder and having a
non-reactive diaphragm and internal
parts and a suitable delivery pressure.
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4.2.4 Mixing chamber for the
dilution method, of an inert material
and of proper design to provide
thorough mixing of CO standard gas and
diluent air streams.
4.2.5 Output sampling manifold,
constructed of an inert material and of
sufficient diameter to ensure an
insignificant pressure drop at the
analyzer connection. The system must
have a vent designed to ensure nearly
atmospheric pressure at the analyzer
connection port and to prevent ambient
air from entering the manifold.
4.3 Reagents.
4.3.1 CO gas concentration transfer
standard(s) of CO in air, containing an
appropriate concentration of CO
suitable for the selected operating range
of the analyzer under calibration and
traceable to a NIST standard reference
material (SRM). If the CO analyzer has
significant sensitivity to CO2, the CO
standard(s) should also contain 350 to
400 ppm CO2 to replicate the typical
CO2 concentration in ambient air.
However, if the zero air dilution ratio
used for the dilution method is not less
than 100:1 and the zero air contains
ambient levels of CO2, then the CO
standard may be contained in nitrogen
and need not contain CO2.
4.3.2 For the dilution method, clean
zero air, free of contaminants that could
cause a detectable response on or a
change in sensitivity of the CO analyzer.
The zero air should contain < 0.1 ppm
CO.
4.4 Procedure Using the Dilution
Method.
4.4.1 Assemble or obtain a suitable
dynamic dilution calibration system
such as the one shown schematically in
Figure 1. Generally, all calibration gases
including zero air must be introduced
into the sample inlet of the analyzer.
However, if the analyzer has special,
approved zero and span inlets and
automatic valves to specifically allow
introduction of calibration standards at
near atmospheric pressure, such inlets
may be used for calibration in lieu of the
sample inlet. For specific operating
instructions, refer to the manufacturer’s
manual.
4.4.2 Ensure that there are no leaks
in the calibration system and that all
flowmeters are properly and accurately
calibrated, under the conditions of use,
if appropriate, against a reliable volume
or flow rate standard such as a soapbubble meter or wet-test meter traceable
to a NIST standard. All volumetric flow
rates should be corrected to the same
temperature and pressure such as
298.15 K (25 °C) and 760 mm Hg (101
kPa), using a correction formula such as
the following:
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Where:
Fc = corrected flow rate (L/min at 25 °C and
760 mm Hg),
Fm = measured flow rate (at temperature Tm
and pressure Pm),
Pm = measured pressure in mm Hg (absolute),
and
Tm = measured temperature in degrees
Celsius.
5.0
Reference
1. QA Handbook for Air Pollution
Measurement Systems—Volume II.
Ambient Air Quality Monitoring
Program. U.S. EPA. EPA–454/B–08–003
(2008).
BILLING CODE 6560–50–P
EP11FE11.155</GPH>
Sample this CO concentration until a
stable response is obtained. Adjust the
analyzer span control to obtain the
desired analyzer response reading
equivalent to the calculated standard
concentration. If substantial adjustment
of the analyzer span control is required,
it may be necessary to recheck the zero
and span adjustments by repeating steps
4.4.5 and 4.4.6. Record the CO
concentration and the analyzer’s final
response.
4.4.7 Generate several additional
concentrations (at least three evenly
spaced points across the remaining scale
are suggested to verify linearity) by
decreasing FCO or increasing FD. Be sure
the total flow exceeds the analyzer’s
total flow demand. For each
concentration generated, calculate the
exact CO concentration using equation
(2). Record the concentration and the
analyzer’s stable response for each
concentration. Plot the analyzer
responses (vertical or y-axis) versus the
corresponding CO concentrations
(horizontal or x-axis). Calculate the
linear regression slope and intercept of
the calibration curve and verify that no
point deviates from this line by more
than 2 percent of the highest
concentration tested.
4.5 Procedure Using the MultipleCylinder Method. Use the procedure for
the dilution method with the following
changes:
4.5.1 Use a multi-cylinder, dynamic
calibration system such as the typical
one shown in Figure 2.
4.5.2 The flowmeter need not be
accurately calibrated, provided the flow
in the output manifold can be verified
to exceed the analyzer’s flow demand.
4.5.3 The various CO calibration
concentrations required in Steps 4.4.5,
4.4.6, and 4.4.7 are obtained without
dilution by selecting zero air or the
appropriate certified standard cylinder.
4.6 Frequency of Calibration. The
frequency of calibration, as well as the
number of points necessary to establish
the calibration curve and the frequency
of other performance checking, will vary
by analyzer. However, the minimum
frequency, acceptance criteria, and
subsequent actions are specified in
reference 1, appendix D, ‘‘Measurement
Quality Objectives and Validation
Template for CO’’ (page 5 of 30). The
user’s quality control program should
provide guidelines for initial
establishment of these variables and for
subsequent alteration as operational
experience is accumulated.
Manufacturers of CO analyzers should
include in their instruction/operation
manuals information and guidance as to
these variables and on other matters of
operation, calibration, routine
maintenance, and quality control.
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4.4.3 Select the operating range of
the CO analyzer to be calibrated.
4.4.4 Connect the inlet of the CO
analyzer to the output-sampling
manifold of the calibration system.
4.4.5 Adjust the calibration system
to deliver zero air to the output
manifold. The total air flow must exceed
the total demand of the analyzer(s)
connected to the output manifold to
ensure that no ambient air is pulled into
the manifold vent. Allow the analyzer to
sample zero air until a stable response
is obtained. After the response has
stabilized, adjust the analyzer zero
reading.
4.4.6 Adjust the zero air flow rate
and the CO gas flow rate from the
standard CO cylinder to provide a
diluted CO concentration of
approximately 80 percent of the
measurement upper range limit (URL) of
the operating range of the analyzer. The
total air flow rate must exceed the total
demand of the analyzer(s) connected to
the output manifold to ensure that no
ambient air is pulled into the manifold
vent. The exact CO concentration is
calculated from:
Where:
[CO]OUT = diluted CO concentration at the
output manifold (ppm),
[CO]STD = concentration of the undiluted CO
standard (ppm),
FCO = flow rate of the CO standard (L/min),
and
FD = flow rate of the dilution air (L/min).
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Federal Register / Vol. 76, No. 29 / Friday, February 11, 2011 / Proposed Rules
8202
Federal Register / Vol. 76, No. 29 / Friday, February 11, 2011 / Proposed Rules
PART 53—AMBIENT AIR QUALITY
REFERENCE AND EQUIVALENT
METHODS
3. The authority citation for part 53
continues to read as follows:
Authority: 42 U.S.C. 7401, et seq.
4. Subpart B of Part 53 is revised to
read as follows:
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Subpart B—Procedures for Testing
Performance Characteristics of Automated
Methods for SO2, CO, O3, and NO2
Sec.
53.20 General provisions.
53.21 Test conditions.
53.22 Generation of test atmospheres.
53.23 Test procedure.
Appendix A to Subpart B—Optional Forms
for Reporting Test Results
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Subpart B—Procedures for Testing
Performance Characteristics of
Automated Methods for SO2, CO, O3,
and NO2
§ 53.20
General provisions.
(a) The test procedures given in this
subpart shall be used to test the
performance of candidate automated
methods against the performance
requirement specifications given in
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BILLING CODE 6560–50–C
8203
Federal Register / Vol. 76, No. 29 / Friday, February 11, 2011 / Proposed Rules
table B–1. A test analyzer representative
of the candidate automated method
must exhibit performance better than, or
not outside, the specified limit or limits
for each such performance parameter
specified (except range) to satisfy the
requirements of this subpart. Except as
provided in paragraph (b) of this
section, the measurement range of the
candidate method must be the standard
range specified in table B–1 to satisfy
the requirements of this subpart.
(b) Measurement ranges. For a
candidate method having more than one
selectable measurement range, one
range must be the standard range
specified in table B–1, and a test
analyzer representative of the method
must pass the tests required by this
subpart while operated in that range.
(1) Higher ranges. The tests may be
repeated for one or more higher
(broader) ranges (i.e., ranges extending
to higher concentrations) than the
standard range specified in table B–1,
provided that the range does not extend
to concentrations more than four times
the upper range limit of the standard
range specified in table B–1. For such
higher ranges, only the tests for range
(calibration), noise at 80% of the upper
range limit, and lag, rise and fall time
are required to be repeated. For the
purpose of testing a higher range, the
test procedure of § 53.23(e) may be
abridged to include only those
components needed to test lag, rise and
fall time.
(2) Lower ranges. The tests may be
repeated for one or more lower
(narrower) ranges (i.e., ones extending
to lower concentrations) than the
standard range specified in table B–1.
For methods for some pollutants, table
B–1 specifies special performance limit
requirements for lower ranges. If special
low-range performance limit
requirements are not specified in table
B–1, then the performance limit
requirements for the standard range
apply. For lower ranges for any method,
only the tests for range (calibration),
noise at 0% of the measurement range,
lower detectable limit, (and nitric oxide
interference for SO2 UVF methods) are
required to be repeated, provided the
tests for the standard range shows the
applicable limit specifications are met
for the other test parameters.
(3) If the tests are conducted and
passed only for the specified standard
range, any FRM or FEM determination
with respect to the method will be
limited to that range. If the tests are
passed for both the specified range and
one or more higher or lower ranges, any
such determination will include the
additional higher or lower range(s) as
well as the specified standard range.
Appropriate test data shall be submitted
for each range sought to be included in
a FRM or FEM method determination
under this paragraph (b).
(c) For each performance parameter
(except range), the test procedure shall
be initially repeated seven (7) times to
yield 7 test results. Each result shall be
compared with the corresponding
performance limit specification in table
B–1; a value higher than or outside the
specified limit or limits constitutes a
failure. These 7 results for each
parameter shall be interpreted as
follows:
(1) Zero (0) failures: The candidate
method passes the test for the
performance parameter.
(2) Three (3) or more failures: The
candidate method fails the test for the
performance parameter.
(3) One (1) or two (2) failures: Repeat
the test procedures for the performance
parameter eight (8) additional times
yielding a total of fifteen (15) test
results. The combined total of 15 test
results shall then be interpreted as
follows:
(i) One (1) or two (2) failures: The
candidate method passes the test for the
performance parameter.
(ii) Three (3) or more failures: The
candidate method fails the test for the
performance parameter.
(d) The tests for zero drift, span drift,
lag time, rise time, fall time, and
precision shall be carried out in a single
integrated procedure conducted at
various line voltages and ambient
temperatures specified in § 53.23(e). A
temperature-controlled environmental
test chamber large enough to contain the
test analyzer is recommended for this
test. The tests for noise, lower detectable
limit, and interference equivalent shall
be conducted at any ambient
temperature between 20 °C and 30 °C,
at any normal line voltage between 105
and 125 volts, and shall be conducted
such that not more than three (3) test
results for each parameter are obtained
in any 24-hour period.
(e) If necessary, all measurement
response readings to be recorded shall
be converted to concentration units or
adjusted according to the calibration
curve constructed in accordance with
§ 53.21(b).
(f) All recorder chart tracings (or
equivalent data plots), records, test data
and other documentation obtained from
or pertinent to these tests shall be
identified, dated, signed by the analyst
performing the test, and submitted.
Note to § 53.20: Suggested formats for
reporting the test results and calculations are
provided in Figures B–2, B–3, B–4, B–5, and
B–6 in appendix A to this subpart. Symbols
and abbreviations used in this subpart are
listed in table B–5 of appendix A to this
subpart.
TABLE B–1—PERFORMANCE LIMIT SPECIFICATIONS FOR AUTOMATED METHODS
SO2
Performance parameter
Units 1
Range ............................................................
Noise ..............................................................
Lower detectable limit ....................................
Interference equivalent:
Each interferent ..........................................
Total, all interferents ...................................
5. Zero drift, 12 and 24 hour .............................
6. Span drift, 24 hour:
20% of upper range limit ............................
80% of upper range limit ............................
7. Lag time .........................................................
8. Rise time ........................................................
9. Fall time .........................................................
10. Precision:
20% of upper range limit ............................
ppm ..........
ppm ..........
ppm ..........
0–0.5
0.001
0.002
ppm ..........
ppm ..........
ppm ..........
± 0.005
..............
± 0.004
Percent
Percent
Minutes
Minutes
Minutes
.....
.....
.....
.....
.....
ppm ..........
Percent .....
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1.
2.
3.
4.
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Std.
range 3
Lower
range 2 3
CO
Std.
range 3
Lower
range 2 3
NO2
(Std.
range)
Definitions
and test
procedures
0–0.5
0.005
0.010
0–50
0.2
0.4
< 50
0.1
0.2
0–0.5
0.005
0.010
Sec. 53.23(a).
Sec. 53.23(b).
Sec. 53.23(c).
4±
0.005
..............
± 0.002
± 0.02
0.06
± 0.02
± 1.0
..............
± 0.5
± 0.5
..............
± 0.3
± 0.02
0.04
± 0.02
Sec. 53.23(d).
Sec. 53.23(d).
Sec. 53.23(e).
..............
± 3.0
2
2
2
± 3.0
..............
2
2
2
± 20.0
± 5.0
20
15
15
..............
± 2.0
2.0
2.0
2.0
± 2.0
..............
2.0
2.0
2.0
± 20.0
± 5.0
20
15
15
Sec.
Sec.
Sec.
Sec.
Sec.
..............
2
..............
2
0.010
..............
..............
1.0
..............
1.0
0.020
..............
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< 0.5
0.0005
0.001
O3
(Std.
range)
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53.23(e).
53.23(e).
53.23(e).
53.23(e).
53.23(e).
Sec. 53.23(e).
Sec. 53.23(e).
8204
Federal Register / Vol. 76, No. 29 / Friday, February 11, 2011 / Proposed Rules
TABLE B–1—PERFORMANCE LIMIT SPECIFICATIONS FOR AUTOMATED METHODS—Continued
SO2
Performance parameter
Units 1
80% of upper range limit ............................
Std.
range 3
ppm ..........
Percent .....
..............
2
CO
Lower
range 2 3
O3
(Std.
range)
Std.
range 3
Lower
range 2 3
NO2
(Std.
range)
Definitions
and test
procedures
..............
2
0.010
..............
..............
1.0
..............
1.0
0.030
..............
Sec. 53.23(e).
Sec. 53.23(e).
1 To convert from parts per million (ppm) to μg/m3 at 25 °C and 760 mm Hg, multiply by M/0.02447, where M is the molecular weight of the
gas. Percent means percent of the upper measurement range limit.
2 Tests for interference equivalent and lag time do not need to be repeated for any lower range provided the test for the standard range shows
that the lower range specification (if applicable) is met for each of these test parameters.
3 For candidate analyzers having automatic or adaptive time constants or smoothing filters, describe their functional nature, and describe and
conduct suitable tests to demonstrate their function aspects and verify that performances for calibration, noise, lag, rise, fall times, and precision
are within specifications under all applicable conditions. For candidate analyzers with operator-selectable time constants or smoothing filters, conduct calibration, noise, lag, rise, fall times, and precision tests at the highest and lowest settings that are to be included in the FRM or FEM designation.
4 For nitric oxide interference for the SO UVF method, interference equivalent is ± 0.0003 ppm for the lower range.
2
jlentini on DSKJ8SOYB1PROD with PROPOSALS4
§ 53.21
Test conditions.
(a) Set-up and start-up of the test
analyzer shall be in strict accordance
with the operating instructions specified
in the manual referred to in § 53.4(b)(3).
Allow adequate warm-up or
stabilization time as indicated in the
operating instructions before beginning
the tests. The test procedures assume
that the test analyzer has a conventional
analog measurement signal output that
is connected to a suitable strip chart
recorder of the servo, null-balance type.
This recorder shall have a chart width
of a least 25 centimeters, chart speeds
up to 10 cm per hour, a response time
of 1 second or less, a deadband of not
more than 0.25 percent of full scale, and
capability either of reading
measurements at least 5 percent below
zero or of offsetting the zero by at least
5 percent. If the test analyzer does not
have an analog signal output, or if a
digital or other type of measurement
data output is used for the tests, an
alternative measurement data recording
device (or devices) may be used for
recording the test data, provided that
the device is reasonably suited to the
nature and purposes of the tests, and an
analog representation of the analyzer
measurements for each test can be
plotted or otherwise generated that is
reasonably similar to the analog
measurement recordings that would be
produced by a conventional chart
recorder connected to a conventional
analog signal output.
(b) Calibration of the test analyzer
shall be carried out prior to conducting
the tests described in this subpart. The
calibration shall be as indicated in the
manual referred to in § 53.4(b)(3) and as
follows: If the chart recorder or
alternative data recorder does not have
below zero capability, adjust either the
controls of the test analyzer or the chart
or data recorder to obtain a + 5% offset
zero reading on the recorder chart to
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facilitate observing negative response or
drift. If the candidate method is not
capable of negative response, the test
analyzer (not the data recorder) shall be
operated with a similar offset zero.
Construct and submit a calibration
curve showing a plot of recorder scale
readings or other measurement output
readings (vertical or y-axis) against
pollutant concentrations presented to
the analyzer for measurement
(horizontal or x-axis). If applicable, a
plot of base analog output units (volts,
millivolts, milliamps, etc.) against
pollutant concentrations shall also be
obtained and submitted. All such
calibration plots shall consist of at least
seven (7) approximately equally spaced,
identifiable points, including 0 and
90 ± 5 percent of the upper range limit
(URL).
(c) Once the test analyzer has been set
up and calibrated and the tests started,
manual adjustment or normal periodic
maintenance is permitted only every 3
days. Automatic adjustments which the
test analyzer performs by itself are
permitted at any time. The submitted
records shall show clearly when any
manual adjustment or periodic
maintenance was made during the tests
and describe the specific operations
performed.
(d) If the test analyzer should
malfunction during any of the
performance tests, the tests for that
parameter shall be repeated. A detailed
explanation of the malfunction,
remedial action taken, and whether
recalibration was necessary (along with
all pertinent records and charts) shall be
submitted. If more than one malfunction
occurs, all performance test procedures
for all parameters shall be repeated.
(e) Tests for all performance
parameters shall be completed on the
same test analyzer; however, use of
multiple test analyzers to accelerate
testing is permissible for testing
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additional ranges of a multi-range
candidate method.
§ 53.22
Generation of test atmospheres.
(a) Table B–2 specifies preferred
methods for generating test atmospheres
and suggested methods of verifying their
concentrations. Only one means of
establishing the concentration of a test
atmosphere is normally required,
provided that that means is adequately
accurate and credible. If the method of
generation can produce accurate,
reproducible concentrations,
verification is optional. If the method of
generation is not reproducible or
reasonably quantifiable, then
establishment of the concentration by
some credible verification method is
required.
(b) The test atmosphere delivery
system shall be designed and
constructed so as not to significantly
alter the test atmosphere composition or
concentration during the period of the
test. The system shall be vented to
insure that test atmospheres are
presented to the test analyzer at very
nearly atmospheric pressure. The
delivery system shall be fabricated from
borosilicate glass, FEP Teflon, or other
material that is inert with regard to the
gas or gases to be used.
(c) The output of the test atmosphere
generation system shall be sufficiently
stable to obtain stable response readings
from the test analyzer during the
required tests. If a permeation device is
used for generation of a test atmosphere,
the device, as well as the air passing
over it, shall be controlled to 0.1 °C.
(d) All diluent air shall be zero air free
of contaminants likely to react with the
test atmospheres or cause a detectable
response on the test analyzer.
(e) The concentration of each test
atmosphere used shall be quantitatively
established and/or verified before or
during each series of tests. Samples for
verifying test concentrations shall be
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collected from the test atmosphere
delivery system as close as feasible to
the sample intake port of the test
analyzer.
(f) The accuracy of all flow
measurements used to calculate test
atmosphere concentrations shall be
documented and referenced to a
primary flow rate or volume standard
(such as a spirometer, bubble meter,
etc.). Any corrections shall be clearly
shown. All flow measurements given in
volume units shall be standardized to
25 °C. and 760 mm Hg.
8205
(g) Schematic drawings, photos,
descriptions, and other information
showing complete procedural details of
the test atmosphere generation,
verification, and delivery system shall
be provided. All pertinent calculations
shall be clearly indicated.
TABLE B–2—TEST ATMOSPHERES
Test gas
Generation
Ammonia ..................
Permeation device. Similar to system described in references 1 and 2.
Cylinder of zero air or nitrogen containing CO2 as required
to obtain the concentration specified in table B–3.
Carbon dioxide .........
Carbon monoxide .....
Ethane ......................
Ethylene ...................
Hydrogen chloride ....
Hydrogen sulfide ......
Methane ...................
Verification
Cylinder of zero air or nitrogen containing CO as required
to obtain the concentration specified in table B–3.
Cylinder of zero air or nitrogen containing ethane as required to obtain the concentration specified in table B–3.
Cylinder of pre-purified nitrogen containing ethylene as required to obtain the concentration specified in table B–3.
Cylinder 1 of pre-purified nitrogen containing approximately
100 ppm of gaseous HCl. Dilute with zero air to concentration specified in table B–3.
Permeation device system described in references 1 and 2
Nitrogen dioxide .......
Cylinder of zero air containing methane as required to obtain the concentration specified in table B–3.
Cylinder 1 of pre-purified nitrogen containing approximately
100 ppm NO. Dilute with zero air to required concentration.
1. Gas phase titration as described in reference 6 ..............
Ozone .......................
2. Permeation device, similar to system described in reference 6.
Calibrated ozone generator as described in reference 9 .....
Sulfur dioxide ...........
1. Permeation device as described in references 1 and 2 ...
Nitric oxide ...............
Water ........................
Xylene ......................
Zero air .....................
2. Dynamic dilution of a cylinder containing approximately
100 ppm SO2 as described in Reference 7.
Pass zero air through distilled water at a fixed known temperature between 20° and 30° C such that the air stream
becomes saturated. Dilute with zero air to concentration
specified in table B–3.
Cylinder of pre-purified nitrogen containing 100 ppm xylene. Dilute with zero air to concentration specified in
table B–3.
Indophenol method, reference 3.
Use NIST-certified standards whenever possible. If NIST
standards are not available, obtain 2 standards from
independent sources which agree within 2 percent, or
obtain one standard and submit it to an independent laboratory for analysis, which must agree within 2 percent
of the supplier’s nominal analysis.
Use an FRM CO analyzer as described in reference 8.
Gas chromatography, ASTM D2820, reference 10. Use
NIST-traceable gaseous methane or propane standards
for calibration.
Do.
Collect samples in bubbler containing distilled water and
analyze by the mercuric thiocyanate method, ASTM
(D612), p. 29, reference 4.
Tentative method of analysis for H2S content of the atmosphere, p. 426, reference 5.
Gas chromatography ASTM D2820, reference 10. Use
NIST-traceable methane standards for calibration.
Gas phase titration as described in reference 6, section
7.1.
1. Use an FRM NO2 analyzer calibrated with a gravimetrically calibrated permeation device.
2. Use an FRM NO2 analyzer calibrated by gas-phase titration as described in reference 6.
Use an FEM ozone analyzer calibrated as described in reference 9.
Use an SO2 FRM or FEM analyzer as described in reference 7.
Measure relative humidity by means of a dew-point indicator, calibrated electrolytic or piezo electric hygrometer,
or wet/dry bulb thermometer.
Use NIST-certified standards whenever possible. If NIST
standards are not available, obtain 2 standards from
independent sources which agree within 2 percent, or
obtain one standard and submit it to an independent laboratory for analysis, which must agree within 2 percent
of the supplier’s nominal analysis.
1. Ambient air purified by appropriate scrubbers or other
devices such that it is free of contaminants likely to
cause a detectable response on the analyzer.
2. Cylinder of compressed zero air certified by the supplier
or an independent laboratory to be free of contaminants
likely to cause a detectable response on the analyzer.
jlentini on DSKJ8SOYB1PROD with PROPOSALS4
1 Use
stainless steel pressure regulator dedicated to the pollutant measured.
Reference 1. O’Keefe, A. E., and Ortaman, G. C. ‘‘Primary Standards for Trace Gas Analysis,’’ Anal. Chem. 38, 760 (1966).
Reference 2. Scaringelli, F. P., A. E. Rosenberg, E*, and Bell, J. P., ‘‘Primary Standards for Trace Gas Analysis.’’ Anal. Chem. 42, 871 (1970).
Reference 3. ‘‘Tentative Method of Analysis for Ammonia in the Atmosphere (Indophenol Method)’’, Health Lab Sciences, vol. 10, No. 2, 115–
118, April 1973.
Reference 4. 1973 Annual Book of ASTM Standards, American Society for Testing and Materials, 1916 Race St., Philadelphia, PA.
Reference 5. Methods for Air Sampling and Analysis, Intersociety Committee, 1972, American Public Health Association, 1015.
Reference 6. 40 CFR 50 Appendix F, ‘‘Measurement Principle and Calibration Principle for the Measurement of Nitrogen Dioxide in the Atmosphere (Gas Phase Chemiluminescence).’’
Reference 7. 40 CFR 50 Appendix A–1, ‘‘Measurement Principle and Calibration Procedure for the Measurement of Sulfur Dioxide in the Atmosphere (Ultraviolet Fluorscence).’’
Reference 8. 40 CFR 50 Appendix C, ‘‘Measurement Principle and Calibration Procedure for the Measurement of Carbon Monoxide in the Atmosphere’’ (Non-Dispersive Infrared Photometry)’’.
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Federal Register / Vol. 76, No. 29 / Friday, February 11, 2011 / Proposed Rules
§ 53.23
Test procedures.
(a) Range—(1) Technical definition.
The nominal minimum and maximum
concentrations that a method is capable
of measuring.
Note to § 53.23(a)(1): The nominal range is
given as the lower and upper range limits in
concentration units, for example, 0–0.5 parts
per million (ppm).
(2) Test procedure. Determine and
submit a suitable calibration curve, as
specified in § 53.21(b), showing the test
analyzer’s measurement response over
at least 95 percent of the required or
indicated measurement range.
Note to § 53.23(a)(2): A single calibration
curve for each measurement range for which
an FRM or FEM designation is sought will
normally suffice.
(b) Noise—(1) Technical definition.
Spontaneous, short duration deviations
in measurements or measurement signal
output, about the mean output, that are
not caused by input concentration
changes. Measurement noise is
determined as the standard deviation of
a series of measurements of a constant
concentration about the mean and is
expressed in concentration units.
(2) Test procedure. (i) Allow sufficient
time for the test analyzer to warm up
and stabilize. Determine measurement
noise at each of two fixed
concentrations, first using zero air and
then a pollutant test gas concentration
as indicated below. The noise limit
specification in table B–1 shall apply to
both of these tests.
(ii) For an analyzer with an analog
signal output, connect an integratingtype digital meter (DM) suitable for the
test analyzer’s output and accurate to
three significant digits, to determine the
analyzer’s measurement output signal.
jlentini on DSKJ8SOYB1PROD with PROPOSALS4
Note to § 53.23(b)(2): Use of a chart
recorder in addition to the DM is optional.
(iii) Measure zero air with the test
analyzer for 60 minutes. During this 60minute interval, record twenty-five (25)
test analyzer concentration
measurements or DM readings at 2minute intervals. (See Figure B–2 in
appendix A of this subpart.)
(iv) If applicable, convert each DM
test reading to concentration units
(ppm) or adjust the test readings (if
necessary) by reference to the test
analyzer’s calibration curve as
determined in § 53.21(b). Label and
record the test measurements or
converted DM readings as r1, r2, r3 * * *
ri * * * r25.
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(v) Calculate measurement noise as
the standard deviation, S, as follows:
where i indicates the i-th test measurement
or DM reading in ppm.
(vi) Let S at 0 ppm be identified as S0;
compare S0 to the noise limit
specification given in table B–1.
(vii) Repeat steps in Paragraphs
(b)(2)(iii) through (v) of this section
using a pollutant test atmosphere
concentration of 80 ± 5 percent of the
URL instead of zero air, and let S at 80
percent of the URL be identified as S80.
Compare S80 to the noise limit
specification given in table B–1 of this
subpart.
(viii) Both S0 and S80 must be less
than or equal to the table B–1 noise
limit specification to pass the test for
the noise parameter.
(c) Lower detectable limit—(1)
Technical definition. The minimum
pollutant concentration that produces a
measurement or measurement output
signal of at least twice the noise level.
(2) Test procedure. (i) Allow sufficient
time for the test analyzer to warm up
and stabilize. Measure zero air and
record the stable measurement reading
in ppm as BZ. (See Figure B–3 in
appendix A of this subpart.)
(ii) Generate and measure a pollutant
test concentration equal to the value for
the lower detectable limit specified in
table B–1.
Note to § 53.23(c)(2): If necessary, the test
concentration may be generated or verified at
a higher concentration, then quantitatively
and accurately diluted with zero air to the
final required test concentration.
(iii) Record the test analyzer’s stable
measurement reading, in ppm, as BL.
(iv) Determine the lower detectable
limit (LDL) test result as LDL = BL ¥ BZ.
Compare this LDL value with the noise
level, S0, determined in § 53.23(b), for
the 0 concentration test atmosphere.
LDL must be equal to or higher than 2
× S0 to pass this test.
(d) Interference equivalent—(1)
Technical definition. Positive or
negative measurement response caused
by a substance other than the one being
measured.
(2) Test procedure. The test analyzer
shall be tested for all substances likely
to cause a detectable response. The test
analyzer shall be challenged, in turn,
with each potential interfering agent
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(interferent) specified in table B–3. In
the event that there are substances likely
to cause a significant interference which
have not been specified in table B–3,
these substances shall also be tested, in
a manner similar to that for the
specified interferents, at a concentration
substantially higher than that likely to
be found in the ambient air. The
interference may be either positive or
negative, depending on whether the test
analyzer’s measurement response is
increased or decreased by the presence
of the interferent. Interference
equivalents shall be determined by
mixing each interferent, one at a time,
with the pollutant at an interferent test
concentration not lower than the test
concentration specified in table B–3 (or
as otherwise required for unlisted
interferents), and comparing the test
analyzer’s measurement response to the
response caused by the pollutant alone.
Known gas-phase reactions that might
occur between a listed interferent and
the pollutant are designated by footnote
3 in table B–3. In these cases, the
interference equivalent shall be
determined without mixing with the
pollutant.
(i) Allow sufficient time for warm-up
and stabilization of the test analyzer.
(ii) For a candidate method using a
prefilter or scrubber device based upon
a chemical reaction to derive part of its
specificity and which device requires
periodic service or maintenance, the test
analyzer shall be ‘‘conditioned’’ prior to
conducting each interference test series.
This requirement includes conditioning
for the NO2 converter in
chemiluminescence NO/NO2/NOX
analyzers and for the ozone scrubber in
UV-absorption ozone analyzers.
Conditioning is as follows:
(A) Service or perform the indicated
maintenance on the scrubber or prefilter
device, as if it were due for such
maintenance, as directed in the manual
referred to in § 53.4(b)(3).
(B) Before testing for each potential
interferent, allow the test analyzer to
sample through the prefilter or scrubber
device a test atmosphere containing the
interferent at a concentration not lower
than the value specified in table B–3 (or,
for unlisted potential interferents, at a
concentration substantially higher than
likely to be found in ambient air).
Sampling shall be at the normal flow
rate and shall be continued for 6
continuous hours prior to the
interference test series. Conditioning for
all applicable interferents prior to any of
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Reference 9. 40 CFR 50 Appendix D, ‘‘Measurement Principle and Calibration Procedure for the Measurement of Ozone in the Atmosphere’’.
Reference 10. ‘‘Standard Test Method for C, through C5 Hydrocarbons in the Atmosphere by Gas Chromatography’’, D 2820, 1987 Annual
Book of Aston Standards, vol 11.03, American Society for Testing and Materials, 1916 Race St., Philadelphia, PA 19103.
Federal Register / Vol. 76, No. 29 / Friday, February 11, 2011 / Proposed Rules
jlentini on DSKJ8SOYB1PROD with PROPOSALS4
the interference tests is permissible.
Also permissible is simultaneous
conditioning with multiple interferents,
provided no interferent reactions are
likely to occur in the conditioning
system.
(iii) Generate three test atmosphere
streams as follows:
(A) Test atmosphere P: Pollutant test
concentration.
(B) Test atmosphere I: Interferent test
concentration.
(C) Test atmosphere Z: Zero air.
(iv) Adjust the individual flow rates
and the pollutant or interferent
generators for the three test atmospheres
as follows:
(A) The flow rates of test atmospheres
I and Z shall be equal.
(B) The concentration of the pollutant
in test atmosphere P shall be adjusted
such that when P is mixed (diluted)
with either test atmosphere I or Z, the
resulting concentration of pollutant
shall be as specified in table B–3.
(C) The concentration of the
interferent in test atmosphere I shall be
adjusted such that when I is mixed
(diluted) with test atmosphere P, the
resulting concentration of interferent
shall be not less than the value specified
in table B–3 (or as otherwise required
for unlisted potential interferents).
(D) To minimize concentration errors
due to flow rate differences between I
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and Z, it is recommended that, when
possible, the flow rate of P be from 10
to 20 times larger than the flow rates of
I and Z.
(v) Mix test atmospheres P and Z by
passing the total flow of both
atmospheres through a (passive) mixing
component to insure complete mixing of
the gases.
(vi) Sample and measure the mixture
of test atmospheres P and Z with the test
analyzer. Allow for a stable
measurement reading, and record the
reading, in concentration units, as R (see
Figure B–3).
(vii) Mix test atmospheres P and I by
passing the total flow of both
atmospheres through a (passive) mixing
component to insure complete mixing of
the gases.
(viii) Sample and measure this
mixture of P and I with the test
analyzer. Record the stable
measurement reading, in concentration
units, as RI.
(ix) Calculate the interference
equivalent (IE) test result as:
IE = RI ¥ R.
IE must be within the limits (inclusive)
specified in table B–1 for each
interferent tested to pass the
interference equivalent test.
(x) Follow steps (iii) through (ix) of
this section, in turn, to determine the
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interference equivalent for each listed
interferent as well as for any other
potential interferents identified.
(xi) For those potential interferents
which cannot be mixed with the
pollutant, as indicated by footnote (3) in
table B–3, adjust the concentration of
test atmosphere I to the specified value
without being mixed or diluted by the
pollutant test atmosphere. Determine IE
as follows:
(A) Sample and measure test
atmosphere Z (zero air). Allow for a
stable measurement reading and record
the reading, in concentration units, as R.
(B) Sample and measure the
interferent test atmosphere I. If the test
analyzer is not capable of negative
readings, adjust the analyzer (not the
recorder) to give an offset zero. Record
the stable reading in concentration units
as RI, extrapolating the calibration
curve, if necessary, to represent negative
readings.
(C) Calculate IE = RI ¥ R. IE must be
within the limits (inclusive) specified in
table B–1 for each interferent tested to
pass the interference equivalent test.
(xii) Sum the absolute value of all the
individual interference equivalent test
results. This sum must be equal to or
less than the total interferent limit given
in table B–1 to pass the test.
BILLING CODE 6560–50–P
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BILLING CODE 6560–50–C
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(e) Zero drift, span drift, lag time, rise
time, fall time, and precision—(1)
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Technical definitions—(i) Zero drift.
The change in measurement response to
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zero pollutant concentration over 12and 24-hour periods of continuous
unadjusted operation.
(ii) Span drift. The percent change in
measurement response to an up-scale
pollutant concentration over a 24-hour
period of continuous unadjusted
operation.
(iii) Lag time. The time interval
between a step change in input
concentration and the first observable
corresponding change in measurement
response.
(iv) Rise time. The time interval
between initial measurement response
and 95 percent of final response after a
step increase in input concentration.
(v) Fall time. The time interval
between initial measurement response
and 95 percent of final response after a
step decrease in input concentration.
(vi) Precision. Variation about the
mean of repeated measurements of the
same pollutant concentration, expressed
as one standard deviation.
(2) Tests for these performance
parameters shall be accomplished over
a period of seven (7) or fifteen (15) test
days. During this time, the line voltage
supplied to the test analyzer and the
ambient temperature surrounding the
analyzer shall be changed from day to
day, as required in paragraph(e)(4) of
this section. One test result for each
performance parameter shall be
obtained each test day, for seven (7) or
fifteen (15) test days, as determined
from the test results of the first seven
days. The tests for each test day are
performed in a single integrated
procedure.
(3) The 24-hour test day may begin at
any clock hour. The first approximately
12 hours of each test day are required
for testing 12-hour zero drift. Tests for
the other parameters shall be conducted
any time during the remaining 12 hours.
(4) Table B–4 of this section specifies
the line voltage and room temperature
to be used for each test day. The
applicant may elect to specify a wider
temperature range (minimum and
maximum temperatures) than the range
specified in table B–4 and to conduct
these tests over that wider temperature
range in lieu of the specified
temperature range. If the test results
show that all test parameters of this
section § 53.23(e) are passed over this
wider temperature range, a subsequent
FRM or FEM designation for the
candidate method based in part on this
test shall indicate approval for operation
of the method over such wider
temperature range. The line voltage and
temperature shall be changed to the
specified values (or to the alternative,
wider temperature values, if applicable)
at the start of each test day (i.e., at the
start of the 12-hour zero test). Initial
adjustments (day zero) shall be made at
a line voltage of 115 volts (rms) and a
room temperature of 25 °C.
(5) The tests shall be conducted in
blocks consisting of 3 test days each
until 7 (or 15, if necessary) test results
have been obtained. (The final block
may contain fewer than three test days.)
Test days need not be contiguous days,
but during any idle time between tests
or test days, the test analyzer must
operate continuously and measurements
must be recorded continuously at a low
chart speed (or equivalent data
recording) and included with the test
data. If a test is interrupted by an
occurrence other than a malfunction of
the test analyzer, only the block during
which the interruption occurred shall be
repeated.
(6) During each test block, manual
adjustments to the electronics, gas, or
reagent flows or periodic maintenance
shall not be permitted. Automatic
adjustments that the test analyzer
performs by itself are permitted at any
time.
(7) At least 4 hours prior to the start
of the first test day of each test block,
the test analyzer may be adjusted and/
or serviced according to the periodic
maintenance procedures specified in the
manual referred to in § 53.4(b)(3). If a
new block is to immediately follow a
previous block, such adjustments or
servicing may be done immediately after
completion of the day’s tests for the last
day of the previous block and at the
voltage and temperature specified for
that day, but only on test days 3, 6, 9,
and 12.
Note to § 53.23(e)(7): If necessary, the
beginning of the test days succeeding such
maintenance or adjustment may be delayed
as required to complete the service or
adjustment operation.
(8) All measurement response
readings to be recorded shall be
converted to concentration units or
adjusted (if necessary) according to the
calibration curve. Whenever a test
atmosphere is to be measured but a
stable reading is not required, the test
atmosphere shall be sampled and
measured long enough to cause a change
in measurement response of at least
10% of full scale. Identify all readings
and other pertinent data on the strip
chart (or equivalent test data record).
(See Figure B–1 illustrating the pattern
of the required readings.)
TABLE B–4—LINE VOLTAGE AND ROOM TEMPERATURE TEST CONDITIONS
Line voltage,1 rms
jlentini on DSKJ8SOYB1PROD with PROPOSALS4
Test day
0 ...................................................................
1 ...................................................................
2 ...................................................................
3 ...................................................................
4 ...................................................................
5 ...................................................................
6 ...................................................................
7 ...................................................................
8 ...................................................................
9 ...................................................................
10 .................................................................
11 .................................................................
12 .................................................................
13 .................................................................
14 .................................................................
15 .................................................................
1 Voltage
Room temperature,2
°C
115
125
105
125
105
125
105
125
105
125
105
125
105
125
105
125
25
20
20
30
30
20
20
30
30
20
20
30
30
20
20
30
Comments
Initial set-up and adjustments.
Adjustments and/or periodic maintenance permitted at end of tests.
Adjustments and/or periodic maintenance permitted at end of tests.
Examine test results to ascertain if further testing is required.
Adjustments and/or periodic maintenance permitted at end of tests.
Adjustments and/or periodic maintenance permitted at end of tests.
specified shall be controlled to ± 1 volt.
shall be controlled to ±1 °C.
2 Temperatures
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jlentini on DSKJ8SOYB1PROD with PROPOSALS4
BILLING CODE 6560–60–C
(9) Test procedure. (i) Arrange to
generate pollutant test atmospheres as
follows. Test atmospheres A0, A20, and
A80 shall be maintained consistent
during the tests and reproducible from
test day to test day.
Test
atmosphere
A0 .............
A20 ...........
A30 ...........
A80 ...........
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Pollutant concentration
(percent)
Zero air.
20±5 of the upper range limit.
30±5 of the upper range limit.
80±5 of the upper range limit.
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Test
atmosphere
A90 ...........
Pollutant concentration
(percent)
90±5 of the upper range limit.
(ii) For steps within paragraphs
(e)(9)(xxv) through (e)(9)(xxxi) of this
section, a chart speed of at least 10
centimeters per hour (or equivalent
resolution for a digital representation)
shall be used to clearly show changes in
measurement responses. The actual
chart speed, chart speed changes, and
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time checks shall be clearly marked on
the chart.
(iii) Test day 0. Allow sufficient time
for the test analyzer to warm up and
stabilize at a line voltage of 115 volts
and a room temperature of 25 °C. Adjust
the zero baseline to 5 percent of chart
(see § 53.21(b)) and recalibrate, if
necessary. No further adjustments shall
be made to the analyzer until the end of
the tests on the third, sixth, ninth, or
twelfth test day.
(iv) Measure test atmosphere A0 until
a stable measurement reading is
obtained and record this reading (in
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(B) SD must be within the span drift
limits (inclusive) specified in table B–1
to pass the test for span drift.
(iii) Lag time. Determine, from the
strip chart (or alternative test data
record), the elapsed time in minutes
between the change in test
concentration (or mark) made in step
(xxvi) and the first observable (two
times the noise level) measurement
response. This time must be equal to or
less than the lag time limit specified in
table B–1 to pass the test for lag time.
(iv) Rise time. Calculate 95 percent of
measurement reading P9 and determine,
from the recorder chart (or alternative
test data record), the elapsed time
between the first observable (two times
noise level) measurement response and
a response equal to 95 percent of the P9
reading. This time must be equal to or
less than the rise time limit specified in
table B–1 to pass the test for rise time.
(v) Fall time. Calculate five percent of
(P10 ¥ L2) and determine, from the strip
chart (or alternative test record), the
elapsed time in minutes between the
first observable decrease in
measurement response following
reading P10 and a response equal to L2
+ five percent of (P10 ¥ L2). This time
must be equal to or less than the fall
time limit specification in table B–1 to
pass the test for fall time.
(vi) Precision. Calculate precision
(both P20 and P80) for each test day as
follows:
(A)
TABLE B–5—SYMBOLS AND
ABBREVIATIONS
or if a span adjustment was made on the
previous test day,
BL ........
Bz .........
DM ......
Cmax. ...
where
Cmin. ....
i ...........
n indicates the n-th test day, and i indicates
the i-th measurement reading on the nth test day.
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IE .........
L1 ........
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Analyzer reading at the specified
LDL test concentration for the
LDL test.
Analyzer reading at 0 concentration
for the LDL test.
Digital meter.
Maximum analyzer reading during
the 12ZD test period.
Minimum analyzer reading during
the 12ZD test period.
Subscript indicating the i-th quantity
in a series.
Interference equivalent.
First analyzer zero reading for the
24ZD test.
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(C) Both P20 and P80 must be equal to
or less than the precision limits
specified in table B–1 to pass the test for
precision.
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(B)
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(xxxi) Measure test atmosphere A80
and record the stable reading as P11.
(xxxii) Sample test atmosphere A90; a
stable reading is not required.
(xxxiii) Measure test atmosphere A80
and record the stable reading as P12.
(xxxiv) Repeat steps within
paragraphs (e)(9)(viii) through
(e)(9)(xxxiii) of this section, each test
day.
(xxxv) If zero and span adjustments
are made after the readings are taken on
test days 3, 6, 9, or 12, complete all
adjustments; then measure test
atmospheres A0 and A80. Allow for a
stable reading on each, and record the
readings as Z’n and S’n, respectively,
where n = the test day number (3, 6, 9,
or 12). These readings must be made at
least 4 hours prior to the start of the
next test day.
(10) Determine the results of each
day’s tests as follows. Mark the recorder
chart to show readings and
determinations.
(i) Zero drift. (A) Determine the 12hour zero drift by examining the strip
chart pertaining to the 12-hour
continuous zero air test. Determine the
minimum (Cmin.) and maximum (Cmax.)
measurement readings (in ppm) during
this period of 12 consecutive hours,
extrapolating the calibration curve to
negative concentration units if
necessary. Calculate the 12-hour zero
drift (12ZD) as 12ZD = Cmax.—Cmin. (See
Figure B–5 in appendix A.)
(B) Calculate the 24-hour zero drift
(24ZD) for the n-th test day as 24ZDn =
Zn ¥ Zn-1, or 24ZDn = Zn ¥ Z’n-1 if zero
adjustment was made on the previous
test day, where Zn = 1⁄2(L1+L2) for L1 and
L2 taken on the n-th test day.
(C) Compare 12ZD and 24ZD to the
zero drift limit specifications in table B–
1. Both 12ZD and 24ZD must be within
the specified limits (inclusive) to pass
the test for zero drift.
(ii) Span drift.
(A) Calculate the span drift (SD) as:
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ppm) as Z’n, where n = 0 (see Figure B–
4 in appendix A of this subpart).
(v) [Reserved]
(vi) Measure test atmosphere A80.
Allow for a stable measurement reading
and record it as S’n, where n = 0.
(vii) The above readings for Z’0 and
S’0 should be taken at least four (4)
hours prior to the beginning of test day
1.
(viii) At the beginning of each test
day, adjust the line voltage and room
temperature to the values given in table
B–4 of this subpart (or to the
corresponding alternative temperature if
a wider temperature range is being
tested).
(ix) Measure test atmosphere A0
continuously for at least twelve (12)
continuous hours during each test day.
(x) After the 12-hour zero drift test
(step ix) is complete, sample test
atmosphere A0. A stable reading is not
required.
(xi) Measure test atmosphere A20 and
record the stable reading (in ppm) as P1.
(See Figure B–4 in appendix A.)
(xii) Sample test atmosphere A30; a
stable reading is not required.
(xiii) Measure test atmosphere A20
and record the stable reading as P2.
(xiv) Sample test atmosphere A0; a
stable reading is not required.
(xv) Measure test atmosphere A20 and
record the stable reading as P3.
(xvi) Sample test atmosphere A30; a
stable reading is not required.
(xvii) Measure test atmosphere A20
and record the stable reading as P4.
(xviii) Sample test atmosphere A0; a
stable reading is not required.
(xix) Measure test atmosphere A20 and
record the stable reading as P5.
(xx) Sample test atmosphere A30; a
stable reading is not required.
(xxi) Measure test atmosphere A20 and
record the stable reading as P6.
(xxii) Measure test atmosphere A80
and record the stable reading as P7.
(xxiii) Sample test atmosphere A90; a
stable reading is not required.
(xxiv) Measure test atmosphere A80
and record the stable reading as P8.
Increase the chart speed to at least 10
centimeters per hour.
(xxv) Measure test atmosphere A0.
Record the stable reading as L1.
(xxvi) Quickly switch the test
analyzer to measure test atmosphere A80
and mark the recorder chart to show, or
otherwise record, the exact time when
the switch occurred.
(xxvii) Measure test atmosphere A80
and record the stable reading as P9.
(xxviii) Sample test atmosphere A90; a
stable reading is not required.
(xxix) Measure test atmosphere A80
and record the stable reading as P10.
(xxx) Measure test atmosphere A0 and
record the stable reading as L2.
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TABLE B–5—SYMBOLS AND
ABBREVIATIONS—Continued
L2 ........
n ..........
P ..........
Pi .........
P20 ......
P80 ......
ppb ......
ppm .....
jlentini on DSKJ8SOYB1PROD with PROPOSALS4
R .........
TABLE B–5—SYMBOLS AND
ABBREVIATIONS—Continued
Second analyzer zero reading for
the 24ZD test.
Subscript indicating the test day
number.
Analyzer reading for the span drift
and precision tests.
The i-th analyzer reading for the
span drift and precision tests.
Precision at 20 percent of URL.
Precision at 80 percent of URL.
Parts per billion of pollutant gas
(usually in air), by volume.
Parts per million of pollutant gas
(usually in air), by volume.
Analyzer reading of pollutant alone
for the IE test.
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RI ........
ri ..........
S ..........
S0 ........
S80 ......
Sn ........
S′n .......
SD .......
URL .....
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Analyzer reading with interferent
added for the IE test.
The i-th analyzer or DM reading for
the noise test.
Standard deviation of the noise test
readings.
Noise value (S) measured at 0 concentration.
Noise value (S) measured at 80
percent of the URL.
Average of P7 * * * P12 for the n-th
test day of the SD test.
Adjusted span reading on the n-th
test day.
Span drift
Upper range limit of the analyzer’s
measurement range.
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TABLE B–5—SYMBOLS AND
ABBREVIATIONS—Continued
Z ..........
Zn ........
Z′n ........
ZD .......
12ZD ...
24ZD ...
Average of L1 and L2 readings for
the 24ZD test.
Average of L1 and L2 readings on
the n-th test day for the 24ZD
test.
Adjusted analyzer zero reading on
the n-th test day for the 24ZD
test.
Zero drift.
12-hour zero drift.
24-hour zero drift.
Appendix A to Subpart B of Part 53—
Optional Forms for Reporting Test
Results
BILLING CODE 6560–50–P
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8218
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§ 58.10 Annual monitoring network plan
and periodic network assessment.
PART 58—AMBIENT AIR QUALITY
SURVEILLANCE
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5. The authority citation for part 58
continues to read as follows:
Authority: 42 U.S.C. 7403, 7410, 7601(a),
7611, and 7619.
Subpart B—[Amended]
6. Section 58.10, is amended by
adding paragraph (a)(7) to read as
follows:
(a) * * *
(7) A plan for establishing CO
monitoring sites in accordance with the
requirements of appendix D to this part
shall be submitted to the Administrator
by July 1, 2012. The plan shall provide
for all required monitoring stations to be
operational by January 1, 2013.
*
*
*
*
*
7. Section 58.13 is amended by
adding paragraph (e) to read as follows:
§ 58.13
*
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*
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(e) The network of CO monitors must
be physically established no later than
January 1, 2013, and at that time, must
be operating under all of the
requirements of this part, including the
requirements of appendices A, C, D, and
E to this part.
8. Appendix D to Part 58 is amended
by revising section 4.2 to read as
follows:
Appendix D to Part 58—Network
Design Criteria for Ambient Air Quality
Monitoring
*
*
*
*
*
4.2 Carbon Monoxide (CO) Design
Criteria.
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4.2.1 General Requirements. (a) One CO
monitor is required to operate co-located
with any required near-road NO2 monitor, as
required in Section 4.3.2 of this part, in
CBSAs having a population of 1,000,000 or
more persons. Continued operation of
existing, but non-required SLAMS CO sites
using an FRM or FEM is required until
discontinuation is approved by the EPA
Regional Administrator, per section § 58.14
of this part.
4.2.2 Regional Administrator Required
Monitoring.
(a) The Regional Administrators, in
collaboration with states, may require
additional CO monitors above the minimum
number of monitors required in 4.2.1 of this
part, where the minimum monitoring
requirements are not sufficient to meet
monitoring objectives. The Regional
Administrator may require, at his/her
discretion, additional monitors in situations
where data or other information suggest that
CO concentrations may be approaching or
exceeding the NAAQS. Such situations
include, but are not limited to, (1)
Characterizing impacts on ground-level
concentrations due to stationary CO sources,
(2) characterizing CO concentrations in urban
downtown areas or urban street canyons, and
(3) characterizing CO concentrations in areas
that are subject to high ground level CO
concentrations particularly due or enhanced
by topographical and meteorological impacts.
(b) The Regional Administrator and the
responsible State or local air monitoring
agency should work together to design and/
or maintain the most appropriate CO network
to address the data needs for an area, and
include all monitors under this provision in
the annual monitoring network plan.
4.2.3 CO Monitoring Spatial Scales. (a)
Microscale and middle scale measurements
are the most useful site classifications for CO
monitoring sites since most people have the
potential for exposure on these scales.
Carbon monoxide maxima occur primarily in
areas near major roadways and intersections
with high traffic density and often in areas
with poor atmospheric ventilation.
(1) Microscale—Microscale measurements
typically represent areas in close proximity
to major roadways, within street canyons,
over sidewalks, and in some cases, point and
area sources. Emissions from roadways result
in high ground level CO concentrations at the
microscale, where concentration gradients
generally exhibit a marked decrease with
increasing downwind distance from major
roads, or within urban downtown areas
including urban street canyons. Emissions
from stationary point and area sources, and
non-road sources may, under certain plume
conditions, result in high ground level
concentrations at the microscale.
(2) Middle scale—Middle scale
measurements are intended to represent areas
with dimensions from 100 meters to 0.5
kilometer. In certain cases, middle scale
measurements may apply to areas that have
a total length of several kilometers, such as
‘‘line’’ emission source areas. This type of
emission sources areas would include air
quality along a commercially developed
street or shopping plaza, freeway corridors,
parking lots and feeder streets.
*
*
*
*
*
9. Appendix E to Part 58 is amended
by revising sections 2 and 6.2(a), 6.2(b),
6.2(c), and Table E–4 to read as follows:
Appendix E to Part 58—Probe and
Monitoring Path Siting Criteria for
Ambient Air Quality Monitoring
*
*
*
*
*
2. Horizontal and Vertical Placement
The probe or at least 80 percent of the
monitoring path must be located between
2 and 15 meters above ground level for all
ozone and sulfur dioxide monitoring sites,
and for neighborhood or larger spatial scale
Pb, PM10, PM10¥2.5, PM2.5, NO2, and carbon
monoxide sites. Middle scale PM10¥2.5 sites
are required to have sampler inlets between
2 and 7 meters above ground level.
Microscale Pb, PM10, PM10¥2.5, and PM2.5
sites are required to have sampler inlets
between 2 and 7 meters above ground level.
Microscale near-road NO2 monitoring sites
are required to have sampler inlets between
2 and 7 meters above ground level. The inlet
probes for microscale carbon monoxide
monitors that are being used to measure
concentrations near roadways must be
between 2 and 7 meters above ground level.
The probe or at least 90 percent of the
monitoring path must be at least 1 meter
vertically or horizontally away from any
supporting structure, walls, parapets,
penthouses, etc., and away from dusty or
dirty areas. If the probe or a significant
portion of the monitoring path is located near
the side of a building or wall, then it should
be located on the windward side of the
building relative to the prevailing wind
direction during the season of highest
concentration potential for the pollutant
being measured.
*
*
*
*
*
6. * * *
6.2 Spacing for Carbon Monoxide Probes
and Monitoring Paths. (a) Near-road or urban
street canyon CO monitoring microscale sites
are intended to provide a measurement of the
influence of the immediate source on the
pollution exposure on the adjacent area. In
order to provide some reasonable consistency
and comparability in the air quality data from
microscale sites, the CO monitor probe shall
be as near as practicable to the outside
nearest edge of the traffic lanes of the target
road segment; but shall not be located at a
distance greater than 50 meters, in the
horizontal, from the outside nearest edge of
the traffic lanes of the target road segment.
(b) Downtown urban area or urban street
canyon (microscale) CO monitor inlet probes
must be located at least
10 meters from an intersection and preferably
at a midblock location. Midblock locations
are preferable to intersection locations
because intersections represent a much
smaller portion of downtown space than do
the streets between them. Pedestrian
exposure is probably also greater in street
canyon/corridors than at intersections.
(c) In determining the minimum separation
between a neighborhood scale monitoring
site and a specific roadway, the presumption
is made that measurements should not be
substantially influenced by any one roadway.
Computations were made to determine the
separation distance, and Table E–2 of this
appendix provides the required minimum
separation distance between roadways and a
probe or
90 percent of a monitoring path. Probes or
monitoring paths that are located closer to
roads than this criterion allows should not be
classified as neighborhood scale, since the
measurements from such a site would closely
represent the middle scale. Therefore, sites
not meeting this criterion should be
classified as middle scale.
*
*
*
*
*
TABLE E–4 OF APPENDIX E TO PART 58—SUMMARY OF PROBE AND MONITORING PATH SITING CRITERIA
Scale (maximum
monitoring path
length, meters)
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Pollutant
SO2 3,4,5,6 ..................
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Height from ground
to probe, inlet or
80% of monitoring
path 1
Middle (300 m) .......
Neighborhood
Urban, and Regional (1 km).
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Horizontal and
vertical distance
from supporting
structures 2 to
probe, inlet or 90%
of monitoring path 1
(meters)
Distance from trees
to probe, inlet or
90% of monitoring
path 1 (meters)
2–15
>1
>10
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Distance from roadways to
probe, inlet or monitoring
path 1 (meters)
N/A.
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TABLE E–4 OF APPENDIX E TO PART 58—SUMMARY OF PROBE AND MONITORING PATH SITING CRITERIA—Continued
Height from ground
to probe, inlet or
80% of monitoring
path 1
Scale (maximum
monitoring path
length, meters)
Pollutant
Horizontal and
vertical distance
from supporting
structures 2 to
probe, inlet or 90%
of monitoring path 1
(meters)
Distance from trees
to probe, inlet or
90% of monitoring
path 1 (meters)
Distance from roadways to
probe, inlet or monitoring
path 1 (meters)
CO 4,5,7 .....................
Micro, middle (300
m).
Neighborhood (1
km).
2–7: 2–15
>1
>10
O3 3,4,5 ......................
Middle (300 m) .......
Neighborhood,
Urban, and Regional (1 km).
Micro (Near-road
[50–300]).
Middle (300m) ........
Neighborhood,
Urban, and Regional (1 km).
Neighborhood and
Urban (1 km).
Micro: Middle,
Neighborhood,
Urban and Regional.
2–15
>1
>10
2–7 (micro); 2–15
(all other scales)
>1
>10
≤50 meters for near-road
microscale;
See Table E–1 of this appendix for all other scales.
2–15
>1
>10
2–7 (micro);
2–7 (middle
PM10–2.5);
2–15 (all other
scales)
>2 (all scales, horizontal distance
only)
>10 (all scales)
See Table E–4 of this appendix for all scales.
2–10 (micro); see Figure E–1
of this appendix for all other
scales.
NO2 3,4,5 ....................
Ozone precursors
(for PAMS) 3,4,5.
PM,Pb 3,4,5,6,8 ...........
2–10 for downtown urban
area or street canyon
microscale; ≤50 for nearroad microscale; see Table
E–2 of this appendix for
middle and neighborhood
scales.
See Table E–1 of this appendix for all scales.
N/A—Not applicable.
1 Monitoring path for open path analyzers is applicable only to middle or neighborhood scale CO monitoring, middle, neighborhood, urban, and
regional scale NO2 monitoring, and all applicable scales for monitoring SO2,O3, and O3 precursors.
2 When probe is located on a rooftop, this separation distance is in reference to walls, parapets, or penthouses located on roof.
3 Should be >20 meters from the drip-line of tree(s) and must be 10 meters from the drip-line when the tree(s) act as an obstruction.
4 Distance from sampler, probe, or 90% of monitoring path to obstacle, such as a building, must be at least twice the height the obstacle protrudes above the sampler, probe, or monitoring path. Sites not meeting this criterion may be classified as middle scale (see text).
5 Must have unrestricted airflow 270 degrees around the probe or sampler; 180 degrees if the probe is on the side of a building or a wall.
6 The probe, sampler, or monitoring path should be away from minor sources, such as furnace or incineration flues. The separation distance is
dependent on the height of the minor source’s emission point (such as a flue), the type of fuel or waste burned, and the quality of the fuel (sulfur,
ash, or lead content). This criterion is designed to avoid undue influences from minor sources.
7 For microscale CO monitoring sites in downtown areas or street canyons (not at near-road NO monitoring sites), the probe must be >10 me2
ters from a street intersection and preferably at a midblock location.
8 Collocated monitors must be within 4 meters of each other and at least 2 meters apart for flow rates greater than 200 liters/min or at least 1
meter apart for samplers having flow rates less than 200 liters/min to preclude airflow interference.
*
*
*
*
*
[FR Doc. 2011–2404 Filed 2–10–11; 8:45 am]
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]]>Agencies
[Federal Register Volume 76, Number 29 (Friday, February 11, 2011)]
[Proposed Rules]
[Pages 8158-8220]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: 2011-2404]
[[Page 8157]]
Vol. 76
Friday,
No. 29
February 11, 2011
Part VI
Environmental Protection Agency
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40 CFR Parts 50, 53 and 58
National Ambient Air Quality Standards for Carbon Monoxide; Proposed
Rule
��Federal Register / Vol. 76, No. 29 / Friday, February 11, 2011 /
Proposed Rules��
[[Page 8158]]
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ENVIRONMENTAL PROTECTION AGENCY
40 CFR Parts 50, 53 and 58
[EPA-HQ-OAR-2008-0015; FRL-9261-4; 2060-AI43]
National Ambient Air Quality Standards for Carbon Monoxide
AGENCY: Environmental Protection Agency (EPA).
ACTION: Proposed rule.
-----------------------------------------------------------------------
SUMMARY: Based on its review of the air quality criteria and the
national ambient air quality standards (NAAQS) for carbon monoxide
(CO), EPA is proposing to retain the current standards. EPA is also
proposing changes to the ambient air monitoring requirements for CO
including those related to network design.
DATES: Comments must be received on or before April 12, 2011.
Public Hearings: If, by February 18, 2011, EPA receives a request
from a member of the public to speak at a public hearing concerning the
proposed regulation, we will hold a public hearing on February 28, 2011
in Arlington, Virginia.
ADDRESSES: Submit your comments, identified by Docket ID No. EPA-HQ-
OAR-2008-0015 by one of the following methods:
https://www.regulations.gov: Follow the on-line
instructions for submitting comments.
E-mail: a-and-r-Docket@epa.gov.
Fax: 202-566-9744.
Mail: Docket No. EPA-HQ-OAR-2008-0015, Environmental
Protection Agency, Mail code 6102T, 1200 Pennsylvania Ave., NW.,
Washington, DC 20460. Please include a total of two copies.
Hand Delivery: Docket No. EPA-HQ-OAR-2008-0015,
Environmental Protection Agency, EPA West, Room 3334, 1301 Constitution
Ave., NW., Washington, DC. Such deliveries are only accepted during the
Docket's normal hours of operation, and special arrangements should be
made for deliveries of boxed information.
Instructions: Direct your comments to Docket ID No. EPA-HQ-OAR-
2008-0015. EPA's policy is that all comments received will be included
in the public docket without change and may be made available online at
https://www.regulations.gov, including any personal information
provided, unless the comment includes information claimed to be
Confidential Business Information (CBI) or other information whose
disclosure is restricted by statute. Do not submit information that you
consider to be CBI or otherwise protected through https://www.regulations.gov or e-mail. The https://www.regulations.gov Web site
is an ``anonymous access'' system, which means EPA will not know your
identity or contact information unless you provide it in the body of
your comment. If you send an e-mail comment directly to EPA without
going through www.regulations.gov your e-mail address will be
automatically captured and included as part of the comment that is
placed in the public docket and made available on the Internet. If you
submit an electronic comment, EPA recommends that you include your name
and other contact information in the body of your comment and with any
disk or CD-ROM you submit. If EPA cannot read your comment due to
technical difficulties and cannot contact you for clarification, EPA
may not be able to consider your comment. Electronic files should avoid
the use of special characters, any form of encryption, and be free of
any defects or viruses. For additional information about EPA's public
docket visit the EPA Docket Center homepage at https://www.epa.gov/epahome/dockets.htm.
Public Hearing. If a public hearing is held, it will be held at the
U.S. Environmental Protection Agency Conference Center, First Floor
Conference Center South, One Potomac Yard, 2777 S. Crystal Drive,
Arlington, VA 22202. All visitors will need to go through security and
present a valid photo identification, such as a driver's license. To
request a public hearing or information pertaining to a public hearing,
contact Ms. Jan King, Health and Environmental Impacts Division, Office
of Air Quality Planning and Standards (C504-02), Environmental
Protection Agency, Research Triangle Park, North Carolina 27711;
telephone number (919) 541- 5665; fax number (919) 541-2664; e-mail
address: king.jan@epa.gov. See the SUPPLEMENTARY INFORMATION for
further information about a possible public hearing.
Docket: All documents in the docket are listed in the https://www.regulations.gov index. Although listed in the index, some
information is not publicly available, e.g., CBI or other information
whose disclosure is restricted by statute. Certain other material, such
as copyrighted material, will be publicly available only in hard copy.
Publicly available docket materials are available either electronically
in https://www.regulations.gov or in hard copy at the Air and Radiation
Docket and Information Center, EPA/DC, EPA West, Room 3334, 1301
Constitution Ave., NW., Washington, DC. 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 Air and Radiation Docket and
Information Center is (202) 566-1742.
FOR FURTHER INFORMATION CONTACT: Dr. Deirdre Murphy, Health and
Environmental Impacts Division, Office of Air Quality Planning and
Standards, U.S. Environmental Protection Agency, Mail code C504-06,
Research Triangle Park, NC 27711; telephone: 919-541-0729; fax: 919-
541-0237; e-mail: murphy.deirdre@epa.gov. For further information
specifically with regard to section IV of this notice, contact Mr.
Nealson Watkins, Air Quality Analysis Division, Office of Air Quality
Planning and Standards, U.S. Environmental Protection Agency, Mail code
C304-06, Research Triangle Park, NC 27711; telephone: 919-541-5522;
fax: 919-541-1903; e-mail: watkins.nealson@epa.gov. To request a public
hearing or information pertaining to a public hearing, contact Ms. Jan
King, Health and Environmental Impacts Division, Office of Air Quality
Planning and Standards (C504-02), Environmental Protection Agency,
Research Triangle Park, North Carolina 27711; telephone number (919)
541- 5665; fax number (919) 541-2664; e-mail address: king.jan@epa.gov.
SUPPLEMENTARY INFORMATION:
General Information
What should I consider as I prepare my comments for EPA?
1. Submitting CBI. Do not submit this information to EPA through
https://www.regulations.gov or e-mail. Clearly mark the part or all of
the information that you claim to be CBI. For CBI information in a disk
or CD ROM that you mail to EPA, mark the outside of the disk or CD ROM
as CBI and then identify electronically within the disk or CD ROM the
specific information that is claimed as CBI. In addition to one
complete version of the comment that includes information claimed as
CBI, a copy of the comment that does not contain the information
claimed as CBI must be submitted for inclusion in the public docket.
Information so marked will not be disclosed except in accordance with
procedures set forth in 40 CFR part 2.
2. Tips for Preparing Your Comments. When submitting comments,
remember to:
[[Page 8159]]
Identify the rulemaking by docket number and other
identifying information (subject heading, Federal Register date and
page number).
Follow directions--the agency may ask you to respond to
specific questions or organize comments by referencing a Code of
Federal Regulations (CFR) part or section number.
Explain why you agree or disagree, suggest alternatives,
and substitute language for your requested changes.
Describe any assumptions and provide any technical
information and/or data that you used.
Provide specific examples to illustrate your concerns, and
suggest alternatives.
Explain your views as clearly as possible, avoiding the
use of profanity or personal threats.
Make sure to submit your comments by the comment period
deadline identified.
Availability of Related Information
A number of the documents that are relevant to this rulemaking are
available through EPA's Office of Air Quality Planning and Standards
(OAQPS) Technology Transfer Network (TTN) Web site at https://www.epa.gov/ttn/naaqs/standards/co/s_co_index.html. These documents
include the Plan for Review of the National Ambient Air Quality
Standards for Carbon Monoxide (Integrated Review Plan or IRP, USEPA,
2008), available at https://www.epa.gov/ttn/naaqs/standards/co/s_co_cr_pd.html, the Integrated Science Assessment for Carbon Monoxide
(USEPA, 2010a), available at https://www.epa.gov/ttn/naaqs/standards/co/s_co_cr_isa.html, the Quantitative Risk and Exposure Assessment for
Carbon Monoxide--Amended (USEPA, 2010b), available at https://www.epa.gov/ttn/naaqs/standards/co/s_co_cr_rea.html, and the Policy
Assessment for the Review of the Carbon Monoxide National Ambient Air
Quality Standards (USEPA, 2010c), available at https://www.epa.gov/ttn/naaqs/standards/co/s_co_cr_pa.html. These and other related
documents are also available for inspection and copying in the EPA
docket identified above.
How can I find information about a possible public hearing?
To request a public hearing or information pertaining to a public
hearing on this document, contact Ms. Jan King, Health and
Environmental Impacts Division, Office of Air Quality Planning and
Standards (C504-02), Environmental Protection Agency, Research Triangle
Park, North Carolina 27711; telephone number (919) 541- 5665; fax
number (919) 541-2664; e-mail address: king.jan@epa.gov. If a request
for a public hearing is received by February 18, 2011, information
about the hearing will be posted prior to the hearing on EPA's Web site
for carbon monoxide regulatory actions at https://www.epa.gov/airquality/urbanair/co/.
Table of Contents
The following topics are discussed in this preamble:
I. Background
A. Legislative Requirements
B. Related Carbon Monoxide Control Programs
C. Review of the Air Quality Criteria and Standards for Carbon
Monoxide
II. Rationale for Proposed Decisions on the Primary Standards
A. Air Quality Information
1. Anthropogenic Sources and Emissions of Carbon Monoxide
2. Ambient Concentrations
B. Health Effects Information
1. Carboxyhemoglobin as Biomarker and Mechanism of Toxicity
2. Nature of Effects
3. At-Risk Populations
4. Potential Impacts on Public Health
C. Human Exposure and Dose Assessment
1. Summary of Design Aspects
2. Key Limitations and Uncertainties
D. Conclusions on Adequacy of the Current Standards
1. Approach
2. Evidence-Based and Exposure/Dose-Based Considerations in the
Policy Assessment
3. CASAC Advice
4. Administrator's Proposed Conclusions Concerning Adequacy
E. Summary of Proposed Decisions on Primary Standards
III. Consideration of a Secondary Standard
A. Background and Considerations in Previous Reviews
B. Evidence-Based Considerations in the Policy Assessment
C. CASAC Advice
D. Administrator's Proposed Conclusions Concerning a Secondary
Standard
IV. Proposed Amendments to Ambient Monitoring Requirements
A. Monitoring Methods
1. Proposed Changes to Part 50, Appendix C
2. Proposed Changes to Part 53
3. Implications for Air Monitoring Networks
B. Network Design
1. Background
2. On-Road Mobile Sources
3. Near-Road Environment
4. Urban Downtown Areas and Urban Street Canyons
5. Meteorological and Topographical Influences
6. Proposed Changes
7. Microscale Carbon Monoxide Monitor Siting Criteria
V. Statutory and Executive Order Reviews
A. Executive Order 12866: Regulatory Planning and Review
B. Paperwork Reduction Act
C. Regulatory Flexibility Act
D. Unfunded Mandates Reform Act
E. Executive Order 13132: Federalism
F. Executive Order 13175: Consultation and Coordination with
Indian Tribal Governments
G. Executive Order 13045: Protection of Children from
Environmental Health and Safety Risks
H. Executive Order 13211: Actions that Significantly Affect
Energy Supply, Distribution or Use
I. National Technology Transfer and Advancement Act
J. Executive Order 12898: Federal Actions to Address
Environmental Justice in Minority Populations and Low-Income
Populations References
I. Background
A. Legislative Requirements
Two sections of the Clean Air Act (CAA) govern the establishment
and revision of the NAAQS. Section 108 (42 U.S.C. 7408) directs the
Administrator to identify and list ``air pollutant[s]'' that in her
``judgment, cause or contribute to air pollution which may reasonably
be anticipated to endanger public health or welfare'' and satisfy two
other criteria, including ``whose presence * * * in the ambient air
results from numerous or diverse mobile or stationary sources'' and to
issue air quality criteria for those that are listed. Air quality
criteria are intended to ``accurately reflect the latest scientific
knowledge useful in indicating the kind and extent of all identifiable
effects on public health or welfare which may be expected from the
presence of [a] pollutant in the ambient air * * * .''
Section 109 (42 U.S.C. 7409) directs the Administrator to propose
and promulgate ``primary'' and ``secondary'' NAAQS for pollutants for
which air quality criteria are issued. Section 109(b)(1) defines a
primary standard as one ``the attainment and maintenance of which in
the judgment of the Administrator, based on such criteria and allowing
an adequate margin of safety, are requisite to protect the public
health.'' \1\ A secondary standard, as defined in section 109(b)(2),
must ``specify a level of air quality the attainment and maintenance of
which, in the judgment of the Administrator, based on such criteria, is
requisite to protect the public welfare from any known or anticipated
adverse effects
[[Page 8160]]
associated with the presence of such air pollutant in the ambient
air.'' \2\
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\1\ The legislative history of section 109 indicates that a
primary standard is to be set at ``the maximum permissible ambient
air level * * * which will protect the health of any [sensitive]
group of the population,'' and that for this purpose ``reference
should be made to a representative sample of persons comprising the
sensitive group rather than to a single person in such a group'' [S.
Rep. No. 91-1196, 91st Cong., 2d Sess. 10 (1970)].
\2\ Welfare effects as defined in section 302(h) (42 U.S.C.
7602(h)) include, but are not limited to, ``effects on soils, water,
crops, vegetation, man-made materials, animals, wildlife, weather,
visibility, and climate, damage to and deterioration of property,
and hazards to transportation, as well as effects on economic values
and on personal comfort and well-being.''
---------------------------------------------------------------------------
The requirement that primary standards include an adequate margin
of safety was intended to address uncertainties associated with
inconclusive scientific and technical information available at the time
of standard setting. It was also intended to provide a reasonable
degree of protection against hazards that research has not yet
identified. Lead Industries Association v. EPA, 647 F.2d 1130, 1154 (DC
Cir 1980), cert. denied, 449 U.S. 1042 (1980); American Petroleum
Institute v. Costle, 665 F.2d 1176, 1186 (DC Cir. 1981), cert. denied,
455 U.S. 1034 (1982). Both kinds of uncertainties are components of the
risk associated with pollution at levels below those at which human
health effects can be said to occur with reasonable scientific
certainty. Thus, in selecting primary standards that include an
adequate margin of safety, the Administrator is seeking not only to
prevent pollution levels that have been demonstrated to be harmful but
also to prevent lower pollution levels that may pose an unacceptable
risk of harm, even if the risk is not precisely identified as to nature
or degree. The CAA does not require the Administrator to establish a
primary NAAQS at a zero-risk level or at background concentration
levels, see Lead Industries Association v. EPA, 647 F.2d at 1156 n. 51,
but rather at a level that reduces risk sufficiently so as to protect
public health with an adequate margin of safety.
In addressing the requirement for an adequate margin of safety, EPA
considers such factors as the nature and severity of the health effects
involved, the size of the population(s) at risk, and the kind and
degree of the uncertainties that must be addressed. The selection of
any particular approach to providing an adequate margin of safety is a
policy choice left specifically to the Administrator's judgment. Lead
Industries Association v. EPA, 647 F.2d at 1161-62; Whitman v. American
Trucking Associations, 531 U.S. 457, 495 (2001).
In setting standards that are ``requisite'' to protect public
health and welfare, as provided in section 109(b), EPA's task is to
establish standards that are neither more nor less stringent than
necessary for these purposes. Whitman v. American Trucking
Associations, 531 U.S. 457, 473. In establishing ``requisite'' primary
and secondary standards, EPA may not consider the costs of implementing
the standards. Id. at 471.
Section 109(d)(1) of the CAA requires that ``[n]ot later than
December 31, 1980, and at 5-year intervals thereafter, the
Administrator shall complete a thorough review of the criteria
published under section 108 and the national ambient air quality
standards * * * and shall make such revisions in such criteria and
standards and promulgate such new standards as may be appropriate * *
*'' Section 109(d)(2) requires that an independent scientific review
committee ``shall complete a review of the criteria * * * and the
national primary and secondary ambient air quality standards * * * and
shall recommend to the Administrator any new * * * standards and
revisions of existing criteria and standards as may be appropriate. * *
*'' This independent review function is performed by the Clean Air
Scientific Advisory Committee (CASAC).
B. Related Carbon Monoxide Control Programs
States are primarily responsible for ensuring attainment and
maintenance of ambient air quality standards once EPA has established
them. Under section 110 of the Act, and related provisions, States are
to submit, for EPA approval, State implementation plans (SIPs) that
provide for the attainment and maintenance of such standards through
control programs directed to sources of the pollutants involved. The
States, in conjunction with EPA, also administer the prevention of
significant deterioration program. See CAA sections 160-169. In
addition, Federal programs provide for nationwide reductions in
emissions of these and other air pollutants through the Federal motor
vehicle and motor vehicle fuel control program under title II of the
Act, (CAA sections 202-250) which involves controls for emissions from
moving sources and controls for the fuels used by these sources; new
source performance standards under section 111; and title IV of the Act
(CAA sections 402-416), which specifically provides for major
reductions in CO emissions.
C. Review of the Air Quality Criteria and Standards for Carbon Monoxide
EPA initially established NAAQS for CO on April 30, 1971. The
primary standards were established to protect against the occurrence of
carboxyhemoglobin levels in human blood associated with health effects
of concern. The standards were set at 9 parts per million (ppm), as an
8-hour average and 35 ppm, as a 1-hour average, neither to be exceeded
more than once per year (36 FR 8186). In the 1971 decision, the
Administrator judged that attainment of these standards would provide
the requisite protection of public health with an adequate margin of
safety and would also provide requisite protection against known and
anticipated adverse effects on public welfare, and accordingly set the
secondary (welfare-based) standards identical to the primary (health-
based) standards.
In 1985, EPA concluded its first periodic review of the criteria
and standards for CO (50 FR 37484). In that review, EPA updated the
scientific criteria upon which the initial CO standards were based
through the publication of the 1979 Air Quality Criteria Document for
Carbon Monoxide (AQCD; USEPA, 1979a) and prepared a Staff Paper (USEPA,
1979b), which, along with the 1979 AQCD, served as the basis for the
development of the notice of proposed rulemaking which was published on
August 18, 1980 (45 FR 55066). Delays due to uncertainties regarding
the scientific basis for the final decision resulted in EPA's
announcing a second public comment period (47 FR 26407). Following
substantial reexamination of the scientific data, EPA prepared an
Addendum to the 1979 AQCD (USEPA, 1984a) and an updated Staff Paper
(USEPA, 1984b). Following review by CASAC (Lippmann, 1984), EPA
announced its decision not to revise the existing primary standard and
to revoke the secondary standard for CO on September 13, 1985, due to a
lack of evidence of effects on public welfare at ambient concentrations
(50 FR 37484).
On August 1, 1994, EPA concluded its second periodic review of the
criteria and standards for CO by deciding that revisions to the CO
NAAQS were not warranted at that time (59 FR 38906). This decision
reflected EPA's review of relevant scientific information assembled
since the last review, as contained in the 1991 AQCD (USEPA, 1991) and
the 1992 Staff Paper (USEPA, 1992). Thus, the primary standards were
retained at 9 ppm with an 8-hour averaging time, and 35 ppm with a 1-
hour averaging time, neither to be exceeded more than once per year (59
FR 38906).
EPA initiated the next periodic review in 1997 and the final 2000
AQCD (U.S. EPA, 2000) was released in August 2000. After release of the
AQCD, Congress requested that the National Research Council (NRC)
review the
[[Page 8161]]
impact of meteorology and topography on ambient CO concentrations in
high altitude and extreme cold regions of the U.S. The NRC convened the
Committee on Carbon Monoxide Episodes in Meteorological and
Topographical Problem Areas, which focused on Fairbanks, Alaska as a
case-study.
A final report, ``Managing Carbon Monoxide Pollution in
Meteorological and Topographical Problem Areas,'' was published in 2003
(NRC, 2003) and offered a wide range of recommendations regarding
management of CO air pollution, cold start emissions standards,
oxygenated fuels, and CO monitoring. Following completion of the NRC
report, EPA did not conduct rulemaking to complete the review.
On September 13, 2007, EPA issued a call for information from the
public (72 FR 52369) requesting the submission of recent scientific
information on specified topics. A workshop was held on January 28-29,
2008 (73 FR 2490) to discuss policy-relevant scientific and technical
information to inform EPA's planning for the CO NAAQS review. Following
the workshop, a draft Integrated Review Plan (IRP) (USEPA, 2008a) was
made available in March 2008 for public comment and was discussed by
the CASAC via a publicly accessible teleconference consultation on
April 8, 2008 (73 FR 12998; Henderson, 2008). EPA made the final IRP
available in August 2008 (USEPA, 2008b).
In preparing the Integrated Science Assessment for Carbon Monoxide
(ISA or Integrated Science Assessment), EPA held an authors'
teleconference in November 2008 with invited scientific experts to
discuss preliminary draft materials prepared as part of the ongoing
development of the CO ISA and its supplementary annexes. The first
draft ISA (USEPA, 2009a) was made available for public review on March
12, 2009 (74 FR 10734) and reviewed by CASAC at a meeting held on May
12-13, 2009 (74 FR 15265). A second draft ISA (USEPA, 2009b) was
released for CASAC and public review on September 23, 2009 (74 FR
48536), and it was reviewed by CASAC at a meeting held on November 16-
17, 2009 (74 FR 54042). The final ISA was released in January 2010
(USEPA, 2010a).
In May 2009, OAQPS released a draft planning document, the draft
Scope and Methods Plan (USEPA, 2009c), for consultation with CASAC and
public review at the CASAC meeting held on May 12-13, 2009. Taking into
consideration comments on the draft Plan from CASAC (Brain, 2009) and
the public, OAQPS staff developed and released for CASAC review and
public comment a first draft Risk and Exposure Assessment (REA) (USEPA,
2009d), which was reviewed at the CASAC meeting held on November 16-17,
2009. Subsequent to that meeting and taking into consideration comments
from CASAC (Brain and Samet, 2010a) and public comments on the first
draft REA, a second draft REA (USEPA, 2010d) was released for CASAC
review and public comment in February 2010, and reviewed at a CASAC
meeting held on March 22-23, 2010. Drawing from information in the
final CO ISA and the second draft REA, EPA released a draft Policy
Assessment (PA) (USEPA, 2010e) in early March, 2010 for CASAC review
and public comment at the same meeting. Taking into consideration
comments on the second draft REA and the draft PA from CASAC (Brain and
Samet, 2010b, 2010c) and the public, staff completed the quantitative
assessments which are presented in the final REA (USEPA, 2010b). Staff
additionally took into consideration those comments and the final REA
analyses in completing the final Policy Assessment (USEPA, 2010c) which
was released in October, 2010.
The schedule for completion of this review is governed by a court
order resolving a lawsuit filed in March 2003 by a group of plaintiffs
who alleged that EPA had failed to perform its mandatory duty, under
section 109(d)(1), to complete a review of the CO NAAQS within the
period provided by statute. The court order that governs this review,
entered by the court on November 14, 2008 and amended on August 30,
2010, provides that EPA will sign, for publication, notices of proposed
and final rulemaking concerning its review of the CO NAAQS no later
than January 28, 2011 and August 12, 2011, respectively.
This action presents the Administrator's proposed decisions on the
current CO standards. Throughout this preamble a number of conclusions,
findings, and determinations proposed by the Administrator are noted.
Although they identify the reasoning that supports this proposal, they
are not intended to be final or conclusive in nature. The EPA invites
general, specific, and technical comments on all issues involved with
this proposal, including all such proposed judgments, conclusions,
findings, and determinations.
II. Rationale for Proposed Decisions on the Primary Standards
This section presents the rationale for the Administrator's
proposed decision to retain the existing CO primary standards.\3\ As
discussed more fully below, this rationale is based on a thorough
review, in the Integrated Science Assessment, of the latest scientific
information, published through mid-2009, on human health effects
associated with the presence of CO in the ambient air. This proposal
also takes into account: (1) Staff assessments of the most policy-
relevant information in the ISA and staff analyses of air quality,
human exposure and health risks presented in the REA and the Policy
Assessment, upon which staff conclusions regarding appropriate
considerations in this review are based; (2) CASAC advice and
recommendations, as reflected in discussions of drafts of the ISA, REA
and PA at public meetings, in separate written comments, and in CASAC's
letters to the Administrator; and (3) public comments received during
the development of these documents, either in connection with CASAC
meetings or separately.
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\3\ As explained below in section IV.A, EPA is proposing to
repromulgate the Federal reference method for CO, as set forth in
Appendix C of 40 CFR part 50. Consistent with EPA's proposed
decision to retain the standards, the recodification clarifies and
updates the text of the FRM, but does not make substantive changes
to it.
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In presenting the rationale and its foundations, this section
begins with a summary of current air quality information in section
II.A. Section II.B summarizes the body of evidence supporting this
rationale, including key health endpoints associated with exposure to
ambient CO. This rationale also draws upon the results of the
quantitative exposure and risk assessments, discussed below in section
II.C. Evidence- and exposure/dose-based considerations that form the
basis for the Administrator's proposed decisions on the adequacy of the
current standard are discussed in section II.D.2.a and II.D.2.b,
respectively. CASAC advice is summarized in section II.D.3. The
Administrator's proposed conclusions are presented in section II.D.4.
A. Air Quality Information
This section provides a general overview of the current air quality
conditions to provide context for this consideration of the current
standards for carbon monoxide. A more comprehensive discussion of air
quality information is provided in the ISA (ISA, sections 3.2 and 3.4)
and summarized in the Policy Assessment, and a more detailed discussion
of aspects particularly relevant to the exposure assessment is provided
in the REA (REA, chapter 3).
[[Page 8162]]
1. Anthropogenic Sources and Emissions of Carbon Monoxide
Carbon monoxide in ambient air is formed primarily by the
incomplete combustion of carbon-containing fuels and by photochemical
reactions in the atmosphere. As a result of the combustion conditions,
CO emissions from large fossil-fueled power plants are typically very
low because optimized fuel consumption conditions make boiler
combustion highly efficient. In contrast, internal combustion engines
used in many mobile sources have widely varying operating conditions.
Therefore, higher and more varying CO formation results from the
operation of these mobile sources (ISA, section 3.2). As with previous
reviews of the CO NAAQS, mobile sources continue to be a significant
source sector for CO in ambient air, as indicated by national emissions
estimates from on-road vehicles, which accounted for approximately half
of the total CO emissions by individual source sectors in 2002 (ISA,
Figure 3-1).\4\ National-scale anthropogenic CO emissions have
decreased by approximately 45% between 1990 and 2005, with nearly all
of this national-scale reduction coming from reductions in on-road
vehicle emissions (ISA, Figure 3-2; PA, Figure 1-1; 2005 NEI \5\). The
role of mobile source emissions is evident in the spatial and temporal
patterns of ambient CO concentrations, which are heavily influenced by
the patterns associated with mobile source emissions (ISA, chapter 3).
In some metropolitan areas of the U.S., due to their greater motor
vehicle density relative to rural areas, on-road mobile source
contribution to all ambient CO emissions was estimated to be as high as
approximately 75%, based on the 2002 National Emissions Inventory (ISA,
p. 3-2). However, the mobile source contribution can vary widely in
specific areas. As an example, 2002 NEI estimates of on-road mobile
source emissions in urban Denver County, Colorado are about 74% of
total CO emissions and emissions from all mobile sources (on-road and
non-road combined) are estimated to contribute about 98% (ISA, section
3.2.1). In contrast, 2002 NEI estimates of on-road CO emissions were
just 20% of the total for rural Garfield County, Colorado\6\ (ISA,
chapter 3, Figure 3-6).
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\4\ EPA compiles CO emissions estimates for the U.S. in the
National Emissions Inventory (NEI). Estimates come from various
sources and different data sources use different data collection
methods, most of which are based on engineering calculations and
estimates rather than measurements. Although these estimates are
generated using well-established approaches, uncertainties are
inherent in the emission factors and models used to represent
sources for which emissions have not been directly measured.
Uncertainties vary by source category, season and region (ISA,
section 3.2.1). At the time of the ISA development, the 2002 NEI was
providing the most recent publicly available CO emissions estimates
for the U.S. that meet EPA's data quality assurance objectives. Such
estimates are now available from the 2005 NEI.
\5\ The emissions trends information in this statement is drawn
from recently available 2005 National Emissions Inventory estimates
(https://www.epa.gov/ttn/chief/net/2005inventory.html, Tier
Summaries) and 1990 and other estimates, available at https://www.epa.gov/ttn/chief/net/critsummary.html Figure 3-2 from the ISA
provides estimates through 2002.
\6\ The 2002 National Emissions Inventory estimate for on-road
emissions in Garfield County is 20,000 tons, and the total emissions
from all sources is estimated to be 98,831 (99K) tons. Thus, in this
example the on-road vehicles accounts for 20.2% of the total
emissions (ISA, section 3, figure 3-6). In contrast, the 2002 Denver
County on-road emissions account for 74% of the total for the county
which is estimated at approximately 180,000 tons.
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2. Ambient Concentrations
As described in section II.A.1 above, mobile source emissions are
major contributors to CO emissions in urban areas, with corresponding
influence on ambient CO concentrations and associated concentration
gradients, with highest ambient concentrations occurring on or nearest
roadways, particularly highly travelled roadways, and lowest
concentrations in more distant locations (ISA, section 3.5.1.3; REA,
section 3.1.3). For example, as described in the ISA CO concentrations
measured within 20 meters of an interstate highway can range from 2 to
10 times greater than CO concentrations measured as far as 300 meters
from a major road, possibly influenced by wind direction and on-road
vehicle density (ISA, section 3.5.1.3, Figures 3-29 and 3-30; Zhu et
al., 2002; Baldauf et al., 2008a,b). Additionally, the role of motor
vehicles in influencing ambient concentrations contributes to the
occurrence of diurnal variation in concentrations reflecting rush hour
patterns (ISA, 3.5.2.2; REA, p. 3-8). The influence of motor vehicle
emissions on ambient concentrations contributes to the important role
of in-vehicle microenvironments in influencing short-term ambient CO
exposures, as described in more detail in the REA and summarized in
sections II.C.1 and II.D.2 below.
In 2009, approximately 350 ambient monitoring stations across the
U.S. reported continuous hourly averages of CO concentrations to EPA's
Air Quality System.\7\ For the most recent period for which air quality
status relative to the CO NAAQS has been analyzed (2009), all areas of
the U.S. meet both CO NAAQS.\8\ As of September 27, 2010, there are no
areas designated as nonattainment for the CO NAAQS (75 FR 59090). Since
2005, one area (Jefferson County, Alabama) has failed to meet the 8-
hour standard during some periods. Large CO emissions sources in this
area are associated with an integrated iron and steel facility. As
described in section 1.3.3 of the Policy Assessment, 2009
concentrations of CO at most currently operating monitors are well
below the current standards, with just a few locations having
concentrations near the controlling 8-hour standard of 9 ppm as a
second maximum 8-hour average.\9\ Of the counties with monitoring sites
in 2009, sites in 3 counties reported second maximum 8-hour average
concentrations at or above 6.4 ppm (PA, Figure 1-2).
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\7\ https://www.epa.gov/ttn/airs/airsaqs/.
\8\ The air quality status in areas monitored relative to the CO
NAAQS is provided at https://www.epa.gov/air/airtrends/values.html.
\9\ As the form of the CO 8-hour standard is not-to-be-exceeded
more than once per year, the second highest 8-hour average in a year
is the design value for this standard. Based on the current rounding
convention, the standard is met if the CO concentrations over a year
result in a design value at or below 9.4 ppm. Additional information
is available at https://www.epa.gov/airtrends/values.html.
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The current levels of ambient CO across the U.S. reflect the steady
declines in ambient concentrations that have occurred over the past
several years. Both the second highest 1-hour and 8-hour concentrations
have significantly declined since the last review. At the set of sites
across the U.S. that have been continuously monitored since 1990 the
average second highest 8-hour and 1-hour concentrations have declined
by nearly 70% (PA, section 1.3.3).
B. Health Effects Information
1. Carboxyhemoglobin as Biomarker and Mechanism of Toxicity
As discussed in the Integrated Science Assessment, in this review,
as in the past (e.g., USEPA, 2000; USEPA, 1991), the best characterized
mechanism of action of CO is tissue hypoxia caused by binding of CO to
hemoglobin to form carboxyhemoglobin (COHb). Accordingly, COHb level in
blood continues to be well recognized as an important internal dose
metric and the one most commonly used in evaluating CO exposure and the
potential for health effects (ISA, p. 2-4, sections 4.1, 4.2, 5.1.1;
1991 AQCD, 2000 AQCD, 2010 ISA).
Increasing levels of COHb with subsequent decrease in oxygen
availability for organs and tissues are of
[[Page 8163]]
concern in people with pre-existing heart disease who have compromised
compensatory mechanisms (e.g., lack of capacity to increase blood flow
in response to increased CO). The integrative review of health effects
of CO indicates that ``the clearest evidence indicates that individuals
with [coronary artery disease] are most susceptible to an increase in
CO-induced health effects'' (ISA, section 5.7.8) and the evidence
continues to support levels of COHb in the blood as the most useful
indicator of CO exposure that is related to the health effects of CO of
major concern.
Carboxyhemoglobin occurs in the blood due to endogenous CO
production from biochemical reactions associated with normal breakdown
of heme proteins, as well as in response to inhaled (exogenous) CO
exposures (ISA, section 4.5). The production of endogenous CO and
levels of endogenous COHb vary with several physiological
characteristics (e.g., slower COHb elimination with increasing age), as
well as some disease states, which can lead to higher endogenous levels
in some individuals (ISA, section 4.5). The amount of COHb formed in
response to exogenous CO is dependent on the CO concentration and
duration of exposure, exercise (which increases the amount of air
removed and replaced per unit of time for gas exchange), the pulmonary
diffusing capacity for CO, ambient pressure, health status, and the
specific metabolism of the exposed individual (ISA, chapter 4; 2000
AQCD, chapter 5). The formation of COHb is a reversible process, but
the high affinity of CO for hemoglobin, which affects the elimination
half-time for COHb, can lead to increased COHb levels in some
circumstances.
As discussed in the REA, exposure to CO in ambient air can occur
outdoors as well as through infiltration of ambient air into indoor
locations (REA, section 2.3). Additionally, indoor sources such as gas
stoves and tobacco smoke can, where present, be important contributors
to total CO exposure and can result in much greater CO exposures and
associated COHb levels than those associated with ambient sources (ISA,
section 3.6.5.2).\10\ For example, indoor source-related exposures,
such as faulty furnaces or other combustion appliances, have been
estimated in the past to lead to COHb levels on the order of twice as
high as those short-term exposures to ambient CO considered more likely
to be encountered by the general public (2000 AQCD, p. 7-4). Further,
some assessments performed for previous reviews have included modeling
simulations both without and with indoor sources (gas stoves and
tobacco smoke) to provide context for the assessment of ambient CO
exposure and dose (e.g., U.S. EPA, 1992; Johnson et al., 2000), and
these assessments have found that nonambient sources have a
substantially greater impact on the highest total exposures experienced
by the simulated population than do ambient sources (Johnson et al.,
2000; REA, sections 1.2 and 6.3).\11\. However, the focus of this REA,
conducted to inform the current review of the CO NAAQS, is on sources
of ambient CO. While recognizing this information regarding the
potential for indoor sources, where present, to play a role in CO
exposures and COHb levels, the exposure modeling in the current review
(described in section II.C below) did not include indoor CO sources in
order to focus on the impact of ambient CO sources on population COHb
levels.
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\10\ A significant source of nonambient CO long recognized as
contributing to elevated COHb levels is tobacco smoking (e.g., ISA,
Figure 4-12). Further, baseline COHb levels in active smokers have
been estimated to range from 3 to 8% for one- to two-pack-per-day
smokers. As a result of their higher baseline COHb levels, smokers
may exhale more CO into the air than they inhale from the ambient
environment when not smoking. Tobacco smoking can also contribute to
increased CO exposures and associated COHb levels in nonsmokers
(2000 AQCD, p. 7-4).
\11\ As has been recognized in previous CO NAAQS reviews, such
sources cannot be effectively mitigated by setting more stringent
ambient air quality standards (59 FR 38914).
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Apart from the impaired oxygen delivery to tissues related to COHb
formation, the evidence also indicates alternative mechanisms of CO-
induced effects independent of limited oxygen availability (2000 AQCD,
section 5.9; ISA, section 5.1.3). These mechanisms are primarily
associated with CO's ability to bind heme-containing proteins other
than hemoglobin and myoglobin, and involve a wide range of molecular
targets and CO concentrations, as described in the 2000 AQCD (USEPA,
2000, section 5.6) and in the ISA (ISA, section 5.1.3). Older
toxicological studies demonstrated that exposure to high concentrations
of CO resulted in altered functions of heme proteins other than
myoglobin and hemoglobin, potentially interfering with basic cell and
molecular processes and leading to dysfunction and/or disease. More
recent toxicological in vitro and in vivo studies have provided
evidence of alteration of nitric oxide signaling, inhibition of
cytochrome C oxidase, heme loss from protein, disruption of iron
homeostasis and alteration of cellular reduction-oxidation status (ISA,
section 5.1.3.2). The ISA notes that these mechanisms may be
interrelated. The evidence for these alternative mechanisms and the
role they may play in CO-induced health effects at concentrations
relevant to the current NAAQS is not clear.
As noted in the ISA, ``CO may be responsible for a continuum of
effects from cell signaling to adaptive responses to cellular injury,
depending on intracellular concentrations of CO, heme proteins and
molecules which modulate CO binding to heme proteins'' (ISA, section
5.1.3.3). However, as noted in the Policy Assessment, new research
based on this evidence for pathways other than those related to
impaired oxygen delivery to tissues is needed to further understand
these pathways and their linkage to CO-induced effects in susceptible
populations. Thus, the evidence indicates that COHb continues to be the
most useful and well-supported indicator of CO exposures and the best
biomarker to characterize the potential for health effects associated
with exposures to ambient CO at this time (PA, section 2.2.1).
2. Nature of Effects
As observed in the Policy Assessment, the long-standing body of
evidence that has established many aspects of the biological effects of
CO continues to contribute to our understanding of the health effects
of ambient CO (PA, section 2.2.1). Binding to heme proteins and the
alteration of their function is the common mechanism underlying
biological responses to CO. Upon inhalation, CO diffuses through the
respiratory zone (alveoli) to the blood where it binds to hemoglobin,
forming COHb. Accordingly, inhaled CO elicits various health effects
through binding to, and associated alteration of the function of, a
number of heme-containing molecules, mainly hemoglobin (see e.g., ISA,
section 4.1). The best characterized health effect associated with CO
levels of concern is hypoxia (reduced oxygen availability) induced by
increased COHb levels in blood and decreased oxygen availability to
critical tissues and organs, specifically the heart (ISA, section
5.1.2). Consistent with this, medical conditions that affect the
biological mechanisms to compensate for this effect (e.g., vasodilation
and increased coronary blood flow with increased oxygen delivery to the
myocardium) can contribute to a reduced amount of oxygen available to
key body tissues, potentially affecting organ system
[[Page 8164]]
function and limiting exercise capacity (2000 AQCD, section 7.1).\12\
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\12\ For example, people with peripheral vascular diseases and
heart disease patients often have markedly reduced circulatory
capacity and reduced ability to compensate for increased circulatory
demands during exercise and other stress (2000 AQCD, p. 7-7).
---------------------------------------------------------------------------
The body of health effects evidence for CO has grown considerably
since the review completed in 1994 with the addition of numerous
epidemiological and toxicological studies (ISA; 2000 AQCD). This
evidence provides additional detail and support to our prior
understanding of CO effects and population susceptibility. Most
notably, the current evidence includes much expanded epidemiological
evidence that is consistent with previous conclusions regarding
cardiovascular disease-related susceptibility (ISA, section 5.7; 2000
AQCD, section 7.7). In this review, the clearest evidence for ambient
CO-related effects is available for cardiovascular effects. Using an
established framework to characterize the evidence as to likelihood of
causal relationships between exposure to ambient CO and specific health
effects (ISA, chapter 1) the ISA states that ``Given the consistent and
coherent evidence from epidemiologic and human clinical studies, along
with biological plausibility provided by CO's role in limiting oxygen
availability, it is concluded that a causal relationship is likely to
exist between relevant \13\ short-term CO exposures and cardiovascular
morbidity'' (ISA, p. 2-6, section 2.5.1). Additionally, as mentioned
above, the ISA judges the evidence to be suggestive of causal
relationships between relevant short- and long-term CO exposures and
CNS effects, birth outcomes and developmental effects following long-
term exposure, respiratory morbidity following short-term exposure, and
mortality following short-term exposure (ISA, section 2.5, Table 2-1).
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\13\ Relevant CO exposures are defined in the ISA as ``generally
within one or two orders of magnitude of ambient CO concentrations''
(ISA, section 2.5).
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Similar to the previous review, results from controlled human
exposure studies of individuals with coronary artery disease (CAD) \14\
(Adams et al., 1988; Allred et al., 1989a, 1989b, 1991; Anderson et
al., 1973; Kleinman et al., 1989, 1998; Sheps et al., 1987 \15\) are
the ``most compelling evidence of CO-induced effects on the
cardiovascular system'' (ISA, section 5.2). Additionally, the use of an
internal dose metric, COHb, adds to the strength of the findings in
these controlled exposure studies. As a group, these studies
demonstrate the role of short-term CO exposures in increasing the
susceptibility of people with CAD to incidents of exercise-associated
myocardial ischemia. Toxicological studies described in the current
review provide evidence of CO effects on the cardiovascular system,
including electrocardiographic effects of 1-hour exposures to 35 ppm CO
in a rat strain developed as an animal model of cardiac susceptibility
(ISA, section 5.2.5.3).
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\14\ Coronary artery disease (CAD), often also called coronary
heart disease or ischemic heart disease is a category of
cardiovascular disease associated with narrowed heart arteries.
Individuals with this disease may have myocardial ischemia, which
occurs when the heart muscle receives insufficient oxygen delivered
by the blood. Exercise-induced angina pectoris (chest pain) occurs
in many of them. Among all patients with diagnosed CAD, the
predominant type of ischemia, as identified by ST segment
depression, is asymptomatic (i.e., silent). Patients who experience
angina typically have additional ischemic episodes that are
asymptomatic (2000 AQCD, section 7.7.2.1). In addition to such
chronic conditions, CAD can lead to sudden episodes, such as
myocardial infarction (ISA, p. 5-24).
\15\ Statistical analyses of the data from Sheps et al., (1987)
by Bissette et al (1986) indicate a significant decrease in time to
onset of angina at 4.1% COHb if subjects that did not experience
exercise-induced angina during air exposure are also included in the
analyses.
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Among the controlled human exposure studies, the ISA places
principal emphasis on the study of CAD patients by Allred et al.
(1989a, 1989b, 1991) \16\ (which was also considered in the previous
review) for the following reasons: (1) Dose-response relationships were
observed; (2) effects were observed at the lowest COHb levels tested
(mean of 2-2.4% COHb \17\ following experimental CO exposure), with no
evidence of a threshold; (3) objective measures of myocardial ischemia
(ST-segment depression) \18\ were assessed, as well as the subjective
measure of decreased time to induction of angina; (4) measurements were
taken both by CO-oximetry (CO-Ox) and by gas chromatography (GC), which
provides a more accurate measurement of COHb blood levels \19\; (5) a
large number of study subjects were used; (6) a strict protocol for
selection of study subjects was employed to include only CAD patients
with reproducible exercise-induced angina; and (7) the study was
conducted at multiple laboratories around the U.S. This study evaluated
changes in time to exercise-induced onset of markers of myocardial
ischemia resulting from two short (approximately 1-hour) CO exposures
targeted to result in mean study subject COHb levels of 2% and 4%,
respectively (ISA, section 5.2.4). In this study, subjects (n=63) on
three separate occasions underwent an initial graded exercise treadmill
test, followed by 50 to 70-minute exposures under resting conditions to
room air CO concentrations or CO concentrations targeted for each
subject to achieve blood COHb levels of 2% and 4%. The exposures were
to average CO concentrations of 0.7 ppm (room air concentration range
0-2 ppm), 117 ppm (range 42-202 ppm) and 253 ppm (range 143-357 ppm).
After the 50- to 70-minute exposures, subjects underwent a second
graded exercise treadmill test, and the percent change in time to onset
of angina and time to ST endpoint between the first and second exercise
tests was determined. For the two CO exposures, the average post-
exposure COHb concentrations were reported as 2.4% and 4.7%, and the
subsequent post-exercise average COHb concentrations were reported as
2.0% and 3.9%.\20\
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\16\ Other controlled human exposure studies of CAD patients
(listed in Table 2-2 of the PA, and discussed in more detail in the
1991 and 2000 AQCDs) similarly provide evidence of reduced time to
exercise-induced angina associated with elevated COHb resulting from
controlled short-duration exposure to increased concentrations of
CO.
\17\ These levels and other COHb levels described for this study
below are based on GC analysis unless otherwise specified. Matched
measurements available for CO-oximetry (CO-Ox) and gas
chromatography (GC) in this study indicate CO-Ox measurements of
2.65% (post-exercise mean) and 3.21% (post-exposure mean)
corresponding to the GC measurement levels of 2.00% (post-exercise
mean) to 2.38% (post-exposure mean) for the lower exposure level
assessed in this study (Allred et al., 1991).
\18\ The ST-segment is a portion of the electrocardiogram,
depression of which is an indication of insufficient oxygen supply
to the heart muscle tissue (myocardial ischemia). Myocardial
ischemia can result in chest pain (angina pectoris) or such
characteristic changes in ECGs or both. In individuals with coronary
artery disease, it tends to occur at specific levels of exercise.
The duration of exercise required to demonstrate chest pain and/or a
1-mm change in the ST segment of the ECG were key measurements in
the multicenter study by Allred et al (1989a, 1989b, 1991).
\19\ As stated in the ISA, the gas chromatographic technique for
measuring COHb levels ``is known to be more accurate than
spectrophotometric measurements, particularly for samples containing
COHb concentrations < 5%'' (ISA, p. 5-41). CO-oximetry is a
spectrophotometric method commonly used to rapidly provide
approximate concentrations of COHb during controlled exposures (ISA,
p. 5-41). At the low concentrations of COHb (<5%) more relevant to
ambient CO exposures, co-oximeters are reported to overestimate COHb
levels compared to GC measurements, while at higher concentrations,
this method is reported to produce underestimates (ISA, p.4-18).
\20\ While the COHb blood level for each subject during the
exercise tests was intermediate between the post-exposure and
subsequent post-exercise measurements (e.g., mean 2.4-2.0% and 4.7-
3.9%), the study authors noted that the measurements at the end of
the exercise test represented the COHb concentrations at the
approximate time of onset of myocardial ischemia as indicated by
angina and ST segment changes. The corresponding ranges of CO-Ox
measurements for the two exposures were 2.7-3.2% and 4.7-5.6%. In
this document, we refer to the GC-measured mean of 2.0% or 2.0-2.4%
for the COHb levels resulting from the lower experimental CO
exposure.
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Across all subjects, the mean time to angina onset for control
(``room'' air) exposures was approximately 8.5 minutes, and the mean
time to ST endpoint was approximately 9.5 minutes (Allred et al.,
1989b). Relative to room-air exposure that resulted in a mean COHb
level of 0.6% (post-exercise), exposure to CO resulting in post-
exercise mean COHb concentrations of 2.0% and 3.9% were observed to
decrease the exercise time required to induce ST-segment depression by
5.1% (p=0.01) and 12.1% (p<0.001), respectively. These changes were
well correlated with the onset of exercise-induced angina, the time to
which was shortened by 4.2% (p=0.027) and 7.1% (p=0.002), respectively,
for the two experimental CO exposures (Allred et al., 1989a, 1989b,
1991).\21\ As at the time of the last review, while ST-segment
depression is recognized as an indicator of myocardial ischemia, the
exact physiological significance of the observed changes among those
with CAD is unclear (ISA, p. 5-48).
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\21\ Another indicator measured in the study was the combination
of heart rate and systolic blood pressure which provides a clinical
index of the work of the heart and myocardial oxygen consumption,
since heart rate and blood pressure are major determinants of
myocardial oxygen consumption (Allred et al., 1991). A decrease in
oxygen to the myocardium would be expected to be paralleled by
ischemia at lower heart rate and systolic blood pressure. This heart
rate-systolic blood pressure indicator at the time to ST-endpoint
was decreased by 4.4% at the 3.9% COHb dose level and by a
nonstatistically-significant, smaller amount at the 2.0% COHb dose
level.
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No controlled human exposure studies have been specifically
designed to evaluate the effect of controlled short-term exposures to
CO resulting in COHb levels lower than a study mean of 2% (ISA, section
5.2.6). However, an important finding of the multi-laboratory study was
the dose-response relationship observed between COHb and the markers of
myocardial ischemia, with effects observed at the lowest increases in
COHb tested, without evidence of a measurable threshold effect. As
reported by the authors, the results comparing ``the effects of
increasing COHb from baseline levels (0.6%) to 2 and 3.9% COHb showed
that each produced further changes in objective ECG measures of
ischemia'' implying that ``small increments in COHb could adversely
affect myocardial function and produce ischemia'' (Allred et al.,
1989b, 1991).
The epidemiological evidence has expanded considerably since the
last review including numerous additional studies that are coherent
with the evidence on markers of myocardial ischemia from controlled
human exposure studies of CAD patients (ISA, section 2.7). The most
recent set of epidemiological studies in the U.S. have evaluated the
associations between ambient concentrations of multiple pollutants
(i.e. fine particles or PM2.5, nitrogen dioxide, sulfur
dioxide, ozone, and CO) at fixed-site ambient monitors and increases in
emergency department visits and hospital admissions for specific
cardiovascular health outcomes including ischemic heart disease (IHD),
myocardial infarction (MI), congestive heart failure (CHF), and
cardiovascular diseases (CVD) as a whole (Bell et al., 2009; Koken et
al., 2003; Linn et al., 2000; Mann et al., 2002; Metzger et al., 2004;
Symons et al., 2006; Tolbert et al., 2007; Wellenius et al., 2005).
Findings of positive associations for these outcomes with metrics of
ambient CO concentrations are coherent with the evidence from
controlled human exposure studies of myocardial ischemia-related
effects resulting from elevated CO exposures (ISA, section 2.5.1; ISA,
Figure 2-1). In these studies, the ambient CO concentration averaging
time for which health outcomes were analyzed varied from 1 hour to 24
hours, with the air quality metrics based on either a selected central-
site monitor for the area or an average for multiple monitors in the
area of interest. The study areas for which positive associations of
these metrics were reported with IHD, MI and CVD outcomes include: the
Atlanta, Georgia metropolitan statistical area; the greater Los
Angeles, California area; and a group of 126 urban counties. Together
the individual study periods spanned the years from 1988 through 2005.
The risk estimates from these studies indicate statistically
significant positive associations were observed with ambient CO
concentrations based on air quality for the day of hospital admission
or based on the average of the selected ambient CO concentration metric
across that day and 2 or 3 days previous (ISA, Figures 5-2 and 5-5).
Many of the studies for these outcomes include same day or next day lag
periods, which, as noted in the ISA ``are consistent with the proposed
mechanism and biological plausibility of these CVD outcomes'' (ISA, p.
5-40).\22\
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\22\ Of the studies for which risk estimates are based on multi-
day averages (the Atlanta studies and the California study by Mann
et al., 2002), the California study by Mann et al., (2002) also
observed a significant positive association with same day CO
concentration.
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Additionally, there are U.S. studies reporting associations with
hospital admissions for CHF, a condition that affects an individual's
ability to compensate for reduced oxygen availability. These include
one in southern California which reported a significant association for
ambient CO with hospital admissions for CHF (Linn et al., 2000), as
well as studies in Allegheny County (Pittsburgh) for 1987-1999 study
period (Wellenius et al., 2005), and Denver for the months of July-
August during 1993-1997 (Koken et al., 2003; ISA, pp. 5-31 to 5-33).
Risk estimates for all three of these studies are based on the 24-hour
CO concentration, with the California and Allegheny County studies'
association with same-day air quality, while the association shown for
the Denver study was with ambient CO concentration three days prior to
health outcome (PA, Table 2-1).
As noted by the ISA, ``[s]tudies of hospital admissions and ED
visits for IHD provide the strongest [epidemiological] evidence of
ambient CO being associated with adverse CVD outcomes'' (ISA, p. 5-40,
section 5.2.3). With regard to studies for other measures of
cardiovascular morbidity, the ISA notes that ``[t]hough not as
consistent as the IHD effects, the effects for all CVD hospital
admissions (which include IHD admissions) and CHF hospital admissions
also provide evidence for an association of cardiovascular outcomes and
ambient CO concentrations'' (ISA, section 5.2.3). While noting the
difficulty in determining the extent to which CO is independently
associated with CVD outcomes in this group of studies as compared to CO
as a marker for the effects of another traffic-related pollutant or mix
of pollutants, the ISA concludes that the epidemiological evidence,
particularly when considering the copollutant analyses, provides
support to the clinical evidence for a direct effect of short-term
ambient CO exposure on CVD morbidity (ISA, pp. 5-40 to 5-41).
As discussed in detail in the ISA, additional epidemiological
studies have evaluate
