Appendix C to Part 132 - Great Lakes Water Quality Initiative Methodologies for Development of Human Health Criteria and Values
40:24.0.1.1.21.0.16.7.23 : Appendix C
Appendix C to Part 132 - Great Lakes Water Quality Initiative
Methodologies for Development of Human Health Criteria and Values
Great Lakes States and Tribes shall adopt provisions consistent
with (as protective as) this appendix.
I. Introduction
Great Lakes States and Tribes shall adopt provisions consistent
with this appendix C to ensure protection of human health.
A. Goal. The goal of the human health criteria for the
Great Lakes System is the protection of humans from unacceptable
exposure to toxicants via consumption of contaminated fish and
drinking water and from ingesting water as a result of
participation in water-oriented recreational activities.
B. Definitions.
Acceptable daily exposure (ADE). An estimate of the
maximum daily dose of a substance which is not expected to result
in adverse noncancer effects to the general human population,
including sensitive subgroups.
Adverse effect. Any deleterious effect to organisms due
to exposure to a substance. This includes effects which are or may
become debilitating, harmful or toxic to the normal functions of
the organism, but does not include non-harmful effects such as
tissue discoloration alone or the induction of enzymes involved in
the metabolism of the substance.
Carcinogen. A substance which causes an increased
incidence of benign or malignant neoplasms, or substantially
decreases the time to develop neoplasms, in animals or humans. The
classification of carcinogens is discussed in section II.A of
appendix C to part 132.
Human cancer criterion (HCC). A Human Cancer Value (HCV)
for a pollutant that meets the minimum data requirements for Tier I
specified in appendix C.
Human cancer value (HCV). The maximum ambient water
concentration of a substance at which a lifetime of exposure from
either: drinking the water, consuming fish from the water, and
water-related recreation activities; or consuming fish from the
water, and water-related recreation activities, will represent a
plausible upper-bound risk of contracting cancer of one in 100,000
using the exposure assumptions specified in the Methodologies for
the Development of Human Health Criteria and Values in appendix C
of this part.
Human noncancer criterion (HNC). A Human Noncancer Value
(HNV) for a pollutant that meets the minimum data requirements for
Tier I specified in appendix C of this part.
Human noncancer value (HNV). The maximum ambient water
concentration of a substance at which adverse noncancer effects are
not likely to occur in the human population from lifetime exposure
via either: drinking the water, consuming fish from the water, and
water-related recreation activities; or consuming fish from the
water, and water-related recreation activities using the
Methodologies for the Development of Human Health criteria and
Values in appendix C of this part.
Linearized multi-stage model. A conservative mathematical
model for cancer risk assessment. This model fits linear
dose-response curves to low doses. It is consistent with a
no-threshold model of carcinogenesis, i.e., exposure to even a very
small amount of the substance is assumed to produce a finite
increased risk of cancer.
Lowest observed adverse effect level (LOAEL). The lowest
tested dose or concentration of a substance which resulted in an
observed adverse effect in exposed test organisms when all higher
doses or concentrations resulted in the same or more severe
effects.
No observed adverse effect level (NOAEL). The highest
tested dose or concentration of a substance which resulted in no
observed adverse effect in exposed test organisms where higher
doses or concentrations resulted in an adverse effect.
Quantitative structure activity relationship (OSAR) or
structure activity relationship (SAR). A mathematical
relationship between a property (activity) of a chemical and a
number of descriptors of the chemical. These descriptors are
chemical or physical characteristics obtained experimentally or
predicted from the structure of the chemical.
Relative source contribution (RSC). The factor
(percentage) used in calculating an HNV or HNC to account for all
sources of exposure to a contaminant. The RSC reflects the percent
of total exposure which can be attributed to surface water through
water intake and fish consumption.
Risk associated dose (RAD). A dose of a known or presumed
carcinogenic substance in (mg/kg/day) which, over a lifetime of
exposure, is estimated to be associated with a plausible upper
bound incremental cancer risk equal to one in 100,000.
Slope factor. Also known as q1*, slope factor is the
incremental rate of cancer development calculated through use of a
linearized multistage model or other appropriate model. It is
expressed in (mg/kg/day) of exposure to the chemical in
question.
Threshold effect. An effect of a substance for which
there is a theoretical or empirically established dose or
concentration below which the effect does not occur.
Uncertainty factor (UF). One of several numeric factors
used in operationally deriving criteria from experimental data to
account for the quality or quantity of the available data.
C. Level of Protection. The criteria developed shall
provide a level of protection likely to be without appreciable risk
of carcinogenic and/or noncarcinogenic effects. Criteria are a
function of the level of designated risk or no adverse effect
estimation, selection of data and exposure assumptions. Ambient
criteria for single carcinogens shall not be set at a level
representing a lifetime upper-bound incremental risk greater than
one in 100,000 of developing cancer using the hazard assessment
techniques and exposure assumptions described herein. Criteria
affording protection from noncarcinogenic effects shall be
established at levels that, taking into account uncertainties, are
considered likely to be without an appreciable risk of adverse
human health effects (i.e., acute, subchronic and chronic toxicity
including reproductive and developmental effects) during a lifetime
of exposure, using the risk assessment techniques and exposure
assumptions described herein.
D. Two-tiered Classification. Chemical concentration
levels in surface water protective of human health shall be derived
based on either a Tier I or Tier II classification. The two Tiers
are primarily distinguished by the amount of toxicity data
available for deriving the concentration levels and the quantity
and quality of data on bioaccumulation.
II. Minimum Data Requirements
The best available toxicity data on the adverse health effects
of a chemical and the best data on bioaccumulation factors shall be
used when developing human health Tier I criteria or Tier II
values. The best available toxicity data shall include data from
well-conducted epidemiologic and/or animal studies which provide,
in the case of carcinogens, an adequate weight of evidence of
potential human carcinogenicity and, in the case of noncarcinogens,
a dose-response relationship involving critical effects
biologically relevant to humans. Such information should be
obtained from the EPA Integrated Risk Information System (IRIS)
database, the scientific literature, and other informational
databases, studies and/or reports containing adverse health effects
data of adequate quality for use in this procedure. Strong
consideration shall be given to the most currently available
guidance provided by IRIS in deriving criteria or values,
supplemented with any recent data not incorporated into IRIS. When
deviations from IRIS are anticipated or considered necessary, it is
strongly recommended that such actions be communicated to the EPA
Reference Dose (RfD) and/or the Cancer Risk Assessment Verification
Endeavor (CRAVE) workgroup immediately. The best available
bioaccumulation data shall include data from field studies and
well-conducted laboratory studies.
A. Carcinogens. Tier I criteria and Tier II values shall
be derived using the methodologies described in section III.A of
this appendix when there is adequate evidence of potential human
carcinogenic effects for a chemical. It is strongly recommended
that the EPA classification system for chemical carcinogens, which
is described in the 1986 EPA Guidelines for Carcinogenic Risk
Assessment (U.S. EPA, 1986), or future modifications thereto, be
used in determining whether adequate evidence of potential
carcinogenic effects exists. Carcinogens are classified, depending
on the weight of evidence, as either human carcinogens, probable
human carcinogens, or possible human carcinogens. The human
evidence is considered inadequate and therefore the chemical cannot
be classified as a human carcinogen, if one of two conditions
exists: (a) there are few pertinent data, or (b) the available
studies, while showing evidence of association, do not exclude
chance, bias, or confounding and therefore a casual interpretation
is not credible. The animal evidence is considered inadequate, and
therefore the chemical cannot be classified as a probable or
possible human carcinogen, when, because of major qualitative or
quantitative limitations, the evidence cannot be interpreted as
showing either the presence or absence of a carcinogenic
effect.
Chemicals are described as “human carcinogens” when there is
sufficient evidence from epidemiological studies to support a
causal association between exposure to the chemicals and cancer.
Chemicals described as “probable human carcinogens” include
chemicals for which the weight of evidence of human carcinogenicity
based on epidemiological studies is limited. Limited human evidence
is that which indicates that a causal interpretation is credible,
but that alternative explanations, such as chance, bias, or
confounding, cannot adequately be excluded. Probable human
carcinogens are also agents for which there is sufficient evidence
from animal studies and for which there is inadequate evidence or
no data from epidemiologic studies. Sufficient animal evidence is
data which indicates that there is an increased incidence of
malignant tumors or combined malignant and benign tumors: (a) in
multiple species or strains; (b) in multiple experiments (e.g.,
with different routes of administration or using different dose
levels); or (c) to an unusual degree in a single experiment with
regard to high incidence, unusual site or type of tumor, or early
age at onset. Additional evidence may be provided by data on
dose-response effects, as well as information from short-term tests
(such as mutagenicity/genotoxicity tests which help determine
whether the chemical interacts directly with DNA) or on chemical
structure, metabolism or mode of action.
“Possible human carcinogens” are chemicals with limited evidence
of carcinogenicity in animals in the absence of human data. Limited
animal evidence is defined as data which suggests a carcinogenic
effect but are limited because: (a) The studies involve a single
species, strain, or experiment and do not meet criteria for
sufficient evidence (see preceding paragraph); or (b) the
experiments are restricted by inadequate dosage levels, inadequate
duration of exposure to the agent, inadequate period of follow-up,
poor survival, too few animals, or inadequate reporting; or (c) the
studies indicate an increase in the incidence of benign tumors
only. More specifically, this group can include a wide variety of
evidence, e.g., (a) a malignant tumor response in a single
well-conducted experiment that does not meet conditions for
sufficient evidence, (b) tumor response of marginal statistical
significance in studies having inadequate design or reporting, (c)
benign but not malignant tumors with an agent showing no response
in a variety of short-term tests for mutagenicity, and (d) response
of marginal statistical significance in a tissue known to have a
high or variable background rate.
1. Tier I: Weight of evidence of potential human
carcinogenic effects sufficient to derive a Tier I HCC shall
generally include human carcinogens, probable human carcinogens and
can include, on a case-by-case basis, possible human carcinogens if
studies have been well-conducted albeit based on limited evidence,
when compared to studies used in classifying human and probable
human carcinogens. The decision to use data on a possible human
carcinogen for deriving Tier I criteria shall be a case-by-case
determination. In determining whether to derive a Tier I HCC,
additional evidence that shall be considered includes but is not
limited to available information on mode of action, such as
mutagenicity/genotoxicity (determinations of whether the chemical
interacts directly with DNA), structure activity, and
metabolism.
2. Tier II: Weight of evidence of possible human
carcinogenic effects sufficient to derive a Tier II human cancer
value shall include those possible human carcinogens for which
there are at a minimum, data sufficient for quantitative risk
assessment, but for which data are inadequate for Tier I criterion
development due to a tumor response of marginal statistical
significance or inability to derive a strong dose-response
relationship. In determining whether to derive Tier II human cancer
values, additional evidence that shall be considered includes but
is not limited to available information on mode of action such as
mutagenicity/genotoxicity (determinations of whether the chemical
interacts directly with DNA), structure activity and metabolism. As
with the use of data on possible human carcinogens in developing
Tier I criteria, the decision to use data on possible human
carcinogens to derive Tier II values shall be made on a
case-by-case basis.
B. Noncarcinogens. All available toxicity data shall be
evaluated considering the full range of possible health effects of
a chemical, i.e., acute/subacute, chronic/subchronic and
reproductive/developmental effects, in order to best describe the
dose-response relationship of the chemical, and to calculate human
noncancer criteria and values which will protect against the most
sensitive endpoint(s) of toxicity. Although it is desirable to have
an extensive database which considers a wide range of possible
adverse effects, this type of data exists for a very limited number
of chemicals. For many others, there is a range in quality and
quantity of data available. To assure minimum reliability of
criteria and values, it is necessary to establish a minimum
database with which to develop Tier I criteria or Tier II values.
The following represent the minimum data sets necessary for this
procedure.
1. Tier I: The minimum data set sufficient to derive a
Tier I human HNC shall include at least one well-conducted
epidemiologic study or animal study. A well-conducted epidemiologic
study for a Tier I HNC must quantify exposure level(s) and
demonstrate positive association between exposure to a chemical and
adverse effect(s) in humans. A well-conducted study in animals must
demonstrate a dose response relationship involving one or more
critical effect(s) biologically relevant to humans. (For example,
study results from an animal whose pharmacokinetics and
toxicokinetics match those of a human would be considered most
biologically relevant.) Ideally, the duration of a study should
span multiple generations of exposed test species or at least a
major portion of the lifespan of one generation. This type of data
is currently very limited. By the use of uncertainty adjustments,
shorter term studies (such as 90-day subchronic studies) with
evaluation of more limited effect(s) may be used to extrapolate to
longer exposures or to account for a variety of adverse effects.
For Tier I criteria developed pursuant to this procedure, such a
limited study must be conducted for at least 90 days in rodents or
10 percent of the lifespan of other appropriate test species and
demonstrate a no observable adverse effect level (NOAEL). Chronic
studies of one year or longer in rodents or 50 percent of the
lifespan or greater in other appropriate test species that
demonstrate a lowest observable adverse effect level (LOAEL) may be
sufficient for use in Tier I criterion derivation if the effects
observed at the LOAEL were relatively mild and reversible as
compared to effects at higher doses. This does not preclude the use
of a LOAEL from a study (of chronic duration) with only one or two
doses if the effects observed appear minimal when compared to
effect levels observed at higher doses in other studies.
2. Tier II: When the minimum data for deriving Tier I
criteria are not available to meet the Tier I data requirements, a
more limited database may be considered for deriving Tier II
values. As with Tier I criteria, all available data shall be
considered and ideally should address a range of adverse health
effects with exposure over a substantial portion of the lifespan
(or multiple generations) of the test species. When such data are
lacking it may be necessary to rely on less extensive data in order
to establish a Tier II value. With the use of appropriate
uncertainty factors to account for a less extensive database, the
minimum data sufficient to derive a Tier II value shall include a
NOAEL from at least one well-conducted short-term repeated dose
study. This study shall be of at least 28 days duration, in animals
demonstrating a dose-response, and involving effects biologically
relevant to humans. Data from studies of longer duration (greater
than 28 days) and LOAELs from such studies (greater than 28 days)
may be more appropriate in some cases for derivation of Tier II
values. Use of a LOAEL should be based on consideration of the
following information: severity of effect, quality of the study and
duration of the study.
C. Bioaccumulation factors (BAFs).
1. Tier I for Carcinogens and Noncarcinogens: To be
considered a Tier I cancer or noncancer human health criterion,
along with satisfying the minimum toxicity data requirements of
sections II.A.1 and II.B.1 of this appendix, a chemical must have
the following minimum bioaccumulation data. For all organic
chemicals either: (a) a field-measured BAF; (b) a BAF derived using
the BSAF methodology; or (c) a chemical with a BAF less than 125
regardless of how the BAF was derived. For all inorganic chemicals,
including organometals such as mercury, either: (a) a
field-measured BAF or (b) a laboratory-measured BCF.
2. Tier II for Carcinogens and Noncarcinogens: A chemical
is considered a Tier II cancer or noncancer human health value if
it does not meet either the minimum toxicity data requirements of
sections II.A.1 and II.B.1 of this appendix or the minimum
bioaccumulation data requirements of section II.C.1 of this
appendix.
III. Principles for Development of Tier I Criteria or Tier II
Values
The fundamental components of the procedure to calculate Tier I
criteria or Tier II values are the same. However, certain of the
aspects of the procedure designed to account for short-duration
studies or other limitations in data are more likely to be relevant
in deriving Tier II values than Tier I criteria.
A. Carcinogens.
1. A non-threshold mechanism of carcinogenesis shall be assumed
unless biological data adequately demonstrate the existence of a
threshold on a chemical-specific basis.
2. All appropriate human epidemiologic data and animal cancer
bioassay data shall be considered. Data specific to an
environmentally appropriate route of exposure shall be used. Oral
exposure should be used preferentially over dermal and inhalation
since, in most cases, the exposure routes of greatest concern are
fish consumption and drinking water/incidental ingestion. The risk
associated dose shall be set at a level corresponding to an
incremental cancer risk of one in 100,000. If acceptable human
epidemiologic data are available for a chemical, it shall be used
to derive the risk associated dose. If acceptable human
epidemiologic data are not available, the risk associated dose
shall be derived from available animal bioassay data. Data from a
species that is considered most biologically relevant to humans
(i.e., responds most like humans) is preferred where all other
considerations regarding quality of data are equal. In the absence
of data to distinguish the most relevant species, data from the
most sensitive species tested, i.e., the species showing a
carcinogenic effect at the lowest administered dose, shall
generally be used.
3. When animal bioassay data are used and a non-threshold
mechanism of carcinogenicity is assumed, the data are fitted to a
linearized multistage computer model (e.g., Global '86 or
equivalent model). Global '86 is the linearized multistage model,
derived by Howe, Crump and Van Landingham (1986), which EPA uses to
determine cancer potencies. The upper-bound 95 percent confidence
limit on risk (or, the lower 95 percent confidence limit on dose)
at the one in 100,000 risk level shall be used to calculate a risk
associated dose (RAD). Other models, including modifications or
variations of the linear multistage model which are more
appropriate to the available data may be used where scientifically
justified.
4. If the duration of the study is significantly less than the
natural lifespan of the test animal, the slope may be adjusted on a
case-by-case basis to compensate for latent tumors which were not
expressed (e.g., U.S. EPA, 1980) In the absence of alternative
approaches which compensate for study durations significantly less
than lifetime, the permitting authority may use the process
described in the 1980 National Guidelines (see 45 FR 79352).
5. A species scaling factor shall be used to account for
differences between test species and humans. It shall be assumed
that milligrams per surface area per day is an equivalent dose
between species (U.S. EPA, 1986). All doses presented in mg/kg
bodyweight will be converted to an equivalent surface area dose by
raising the mg/kg dose to the 2/3 power. However, if adequate
pharmacokinetic and metabolism studies are available, these data
may be factored into the adjustment for species differences on a
case-by-case basis.
6. Additional data selection and adjustment decisions must also
be made in the process of quantifying risk. Consideration must be
given to tumor selection for modeling, e.g., pooling estimates for
multiple tumor types and identifying and combining benign and
malignant tumors. All doses shall be adjusted to give an average
daily dose over the study duration. Adjustments in the rate of
tumor response must be made for early mortality in test species.
The goodness-of-fit of the model to the data must also be
assessed.
7. When a linear, non-threshold dose response relationship is
assumed, the RAD shall be calculated using the following
equation:
Where: RAD = risk associated dose in milligrams
of toxicant per kilogram body weight per day (mg/kg/day). 0.00001
(1 × 10−5) = incremental risk of developing cancer equal to one in
100,000. q1* = slope factor (mg/kg/day)−1.
8. If human epidemiologic data and/or other biological data
(animal) indicate that a chemical causes cancer via a threshold
mechanism, the risk associated dose may, on a case-by-case basis,
be calculated using a method which assumes a threshold mechanism is
operative.
B. Noncarcinogens.
1. Noncarcinogens shall generally be assumed to have a threshold
dose or concentration below which no adverse effects should be
observed. Therefore, the Tier I criterion or Tier II value is the
maximum water concentration of a substance at or below which a
lifetime exposure from drinking the water, consuming fish caught in
the water, and ingesting water as a result of participating in
water-related recreation activities is likely to be without
appreciable risk of deleterious effects.
For some noncarcinogens, there may not be a threshold dose below
which no adverse effects should be observed. Chemicals acting as
genotoxic teratogens and germline mutagens are thought to possibly
produce reproductive and/or developmental effects via a genetically
linked mechanism which may have no threshold. Other chemicals also
may not demonstrate a threshold. Criteria for these types of
chemicals will be established on a case-by-case basis using
appropriate assumptions reflecting the likelihood that no threshold
exists.
2. All appropriate human and animal toxicologic data shall be
reviewed and evaluated. To the maximum extent possible, data most
specific to the environmentally relevant route of exposure shall be
used. Oral exposure data should be used preferentially over dermal
and inhalation since, in most cases, the exposure routes of
greatest concern are fish consumption and drinking water/incidental
ingestion. When acceptable human data are not available (e.g.,
well-conducted epidemiologic studies), animal data from species
most biologically relevant to humans shall be used. In the absence
of data to distinguish the most relevant species, data from the
most sensitive animal species tested, i.e., the species showing a
toxic effect at the lowest administered dose (given a relevant
route of exposure), should generally be used.
3. Minimum data requirements are specified in section II.B of
this appendix. The experimental exposure level representing the
highest level tested at which no adverse effects were demonstrated
(NOAEL) from studies satisfying the provisions of section II.B of
this appendix shall be used for criteria calculations. In the
absence of a NOAEL, the LOAEL from studies satisfying the
provisions of section II.B of this appendix may be used if it is
based on relatively mild and reversible effects.
4. Uncertainty factors shall be used to account for the
uncertainties in predicting acceptable dose levels for the general
human population based upon experimental animal data or limited
human data.
a. An uncertainty factor of 10 shall generally be used when
extrapolating from valid experimental results from studies on
prolonged exposure to average healthy humans. This 10-fold factor
is used to protect sensitive members of the human population.
b. An uncertainty factor of 100 shall generally be used when
extrapolating from valid results of long-term studies on
experimental animals when results of studies of human exposure are
not available or are inadequate. In comparison to a, above, this
represents an additional 10-fold uncertainty factor in
extrapolating data from the average animal to the average
human.
c. An uncertainty factor of up to 1000 shall generally be used
when extrapolating from animal studies for which the exposure
duration is less than chronic, but greater than subchronic (e.g.,
90 days or more in length), or when other significant deficiencies
in study quality are present, and when useful long-term human data
are not available. In comparison to b, above, this represents an
additional UF of up to 10-fold for less than chronic, but greater
than subchronic, studies.
d. An UF of up to 3000 shall generally be used when
extrapolating from animal studies for which the exposure duration
is less than subchronic (e.g., 28 days). In comparison to b above,
this represents an additional UF of up to 30-fold for less than
subchronic studies (e.g., 28-day). The level of additional
uncertainty applied for less than chronic exposures depends on the
duration of the study used relative to the lifetime of the
experimental animal.
e. An additional UF of between one and ten may be used when
deriving a criterion from a LOAEL. This UF accounts for the lack of
an identifiable NOAEL. The level of additional uncertainty applied
may depend upon the severity and the incidence of the observed
adverse effect.
f. An additional UF of between one and ten may be applied when
there are limited effects data or incomplete sub-acute or chronic
toxicity data (e.g., reproductive/developmental data). The level of
quality and quantity of the experimental data available as well as
structure-activity relationships may be used to determine the
factor selected.
g. When deriving an UF in developing a Tier I criterion or Tier
II value, the total uncertainty, as calculated following the
guidance of sections 4.a through f, cited above, shall not exceed
10,000 for Tier I criteria and 30,000 for Tier II values.
5. All study results shall be converted, as necessary, to the
standard unit for acceptable daily exposure of milligrams of
toxicant per kilogram of body weight per day (mg/kg/day). Doses
shall be adjusted for continuous exposure (i.e., seven days/week,
24 hours/day, etc.).
C. Criteria and Value Derivation.
1. Standard Exposure Assumptions. The following represent
the standard exposure assumptions used to calculate Tier I criteria
and Tier II values for carcinogens and noncarcinogens. Higher
levels of exposure may be assumed by States and Tribes pursuant to
Clean Water Act (CWA) section 510, or where appropriate in deriving
site-specific criteria pursuant to procedure 1 in appendix F to
part 132.
BW = body weight of an average human (BW = 70kg).
WCd = per capita water consumption (both drinking and incidental
exposure) for surface waters classified as public water supplies =
two liters/day.
- or -
WCr = per capita incidental daily water ingestion for surface
waters not used as human drinking water sources = 0.01
liters/day.
FC = per capita daily consumption of regionally caught
freshwater fish = 0.015kg/day (0.0036 kg/day for trophic level 3
and 0.0114 kg/day for trophic level 4).
BAF = bioaccumulation factor for trophic level 3 and trophic
level 4, as derived using the BAF methodology in appendix B to part
132.
2. Carcinogens. The Tier I human cancer criteria or Tier
II values shall be calculated as follows:
Where: HCV = Human Cancer Value in milligrams
per liter (mg/L). RAD = Risk associated dose in milligrams toxicant
per kilogram body weight per day (mg/kg/day) that is associated
with a lifetime incremental cancer risk equal to one in 100,000. BW
= weight of an average human (BW = 70 kg). WCd = per capita water
consumption (both drinking and incidental exposure) for surface
waters classified as public water supplies = two liters/day. or WCr
= per capita incidental daily water ingestion for surface waters
not used as human drinking water sources = 0.01 liters/day. FCTL3 =
mean consumption of trophic level 3 of regionally caught freshwater
fish = 0.0036 kg/day. FCTL4 = mean consumption of trophic level 4
of regionally caught freshwater fish = 0.0114 kg/day. BAF HHTL3 =
bioaccumulation factor for trophic level 3 fish, as derived using
the BAF methodology in appendix B to part 132. BAF HHTL4 =
bioaccumulation factor for trophic level 4 fish, as derived using
the BAF methodology in appendix B to part 132.
3. Noncarcinogens. The Tier I human noncancer criteria or
Tier II values shall be calculated as follows:
Where: HNV = Human noncancer value in
milligrams per liter (mg/L). ADE = Acceptable daily exposure in
milligrams toxicant per kilogram body weight per day (mg/kg/day).
RSC = Relative source contribution factor of 0.8. An RSC derived
from actual exposure data may be developed using the methodology
outlined by the 1980 National Guidelines (see 45 FR 79354). BW =
weight of an average human (BW = 70 kg). WCd = per capita water
consumption (both drinking and incidental exposure) for surface
waters classified as public water supplies = two liters/day. or WCr
= per capita incidental daily water ingestion for surface waters
not used as human drinking water sources = 0.01 liters/day. FCTL3 =
mean consumption of trophic level 3 fish by regional sport fishers
of regionally caught freshwater fish = 0.0036 kg/day. FCTL4 = mean
consumption of trophic level 4 fish by regional sport fishers of
regionally caught freshwater fish = 0.0114 kg/day. BAF HHTL3 =
human health bioaccumulation factor for edible portion of trophic
level 3 fish, as derived using the BAF methodology in appendix B to
part 132. BAF HHTL4 = human health bioaccumulation factor for
edible portion of trophic level 4 fish, as derived using the BAF
methodology in appendix B to part 132. IV. References
A. Howe, R.B., K.S. Crump and C. Van Landingham. 1986. Computer
Program to Extrapolate Quantitative Animal Toxicity Data to Low
Doses. Prepared for EPA under subcontract #2-251U-2745 to Research
Triangle Institute.
B. U.S. Environmental Protection Agency. 1980. Water Quality
Criteria Availability, Appendix C Guidelines and Methodology Used
in the Preparation of Health Effects Assessment Chapters of the
Consent Decree Water Quality Criteria Documents. Available from
U.S. Environmental Protection Agency, Office of Water Resource
Center (WH-550A), 1200 Pennsylvania Ave., NW., Washington, DC
20460.
C. U.S. Environmental Protection Agency. 1986. Guidelines for
Carcinogen Risk Assessment. Available from U.S. Environmental
Protection Agency, Office of Water Resource Center (WH-550A), 1200
Pennsylvania Ave., NW., Washington, DC 20460.