Draft Charge to the Science Advisory Board for the IRIS Toxicological Review of Hexahydro-1,3,5-trinitro-1,3,5-triazine (RDX)


Draft Charge to the Science Advisory Board for the
IRIS Toxicological Review of Hexahydro-l,3,5-trinitro-l,3,5-triazine (RDX)
March 2016
Introduction
The U.S. Environmental Protection Agency (EPA) is seeking a scientific peer review of a draft
Toxicological Review of Hexahydro-l,3,5-trinitro-l,3,5-triazine (RDX) developed in support of the
Agency's online database, the Integrated Risk Information System (IRIS). IRIS is prepared and
maintained by EPA's National Center for Environmental Assessment (NCEA) within the Office of
Research and Development (ORD).
IRIS is a human health assessment program that evaluates scientific information on effects that may
result from exposure to specific chemicals in the environment Through IRIS, EPA provides high
quality science-based human health assessments to support the Agency's regulatory activities and
decisions to protect public health. IRIS assessments contain information for chemicals that can be
used to support hazard identification and dose-response assessment, two of the four steps in the
human health risk assessment process. When supported by available data, IRIS provides health
effects information and toxicity values for health effects (including cancer and effects other than
cancer) resulting from chronic exposure. IRIS toxicity values may be combined with exposure
information to characterize public health risks of chemicals; this risk characterization information
can then be used to support risk management decisions.
An existing assessment for RDX includes a reference dose (RfD) posted on the IRIS database in
1988 and oral slope factor (OSF) and a cancer descriptor posted in 1990. The IRIS Program is
conducting a reassessment of RDX. The draft Toxicological Review of RDX is based on a
comprehensive review of the available scientific literature on the noncancer and cancer health
effects in humans and experimental animals exposed to RDX. Additionally, appendices for chemical
and physical properties, toxicokinetic information, summaries of toxicity studies, and other
supporting materials are provided as Supplemental Information (see Appendices A to D) to the draft
Toxicological Review.
The draft assessment was developed according to guidelines and technical reports published by
EPA (see Preamble), and contains both qualitative and quantitative characterizations of the human
health hazards for RDX, including a cancer descriptor of the chemical's human carcinogenic
potential, a noncancer toxicity value for chronic oral exposure (RfD), and a cancer risk estimate for
oral exposure.
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Charge questions on the draft Toxicological Review of RDX
1. Literature search/study selection and evaluation. The section on Literature Search Strategy
1 Study Selection and Evaluation describes the process for identifying and selecting pertinent
studies. Please comment on whether the literature search strategy, study selection
considerations, and study evaluation considerations are appropriate and clearly described.
Please identify additional peer-reviewed studies that the assessment should consider.
2. Toxicokinetic modeling. In Appendix C, Section C.1.5, the draft assessment presents a
summary, evaluation, and further development of published PBPK models for RDX in rats, mice,
and humans (Sweeney etal., 2012a, b).
2 a. Are the conclusions reached based on EPA's evaluation of the models scientifically
supported? Do the revised PBPK models adequately represent RDX toxicokinetics? Are the
model assumptions and parameters clearly presented and scientifically supported? Are the
uncertainties in the model appropriately considered and discussed?
2b. The average concentration of RDX in arterial blood (expressed as area under the curve) was
selected over peak concentration as the dose metric for interspecies extrapolation for oral
points of departure (PODs) derived from rat data. Is the choice of dose metric for each
hazard sufficiently explained and appropriate? The mouse PBPK model was not used to
derive PODs for noncancer or cancer endpoints because of uncertainties in the model and
because of uncertainties associated with selection of a dose metric for cancer endpoints. Is
this decision scientifically supported?
2c. In Section 2.1.3 of the draft assessment, an uncertainty factor of 10 for human variation is
applied in the derivation of the RfD. Does the toxicokinetic modeling support the use of a
different factor instead?
3. Hazard identification and dose-response assessment. In Chapter 1, the draft assessment
evaluates the available human, animal, and mechanistic studies to identify health outcomes that
may result from exposure to RDX. In Chapter 2, the draft assessment develops organ/system-
specific reference values for the health outcomes identified in Chapter 1, then selects overall
reference values for each route of exposure. The draft assessment uses EPA's guidance
documents (see http://www.epa.gov/iris/basic-information-about-integrated-risk-
information-svstem#guidancel to reach the following conclusions.
[Note: As suggested by the Chemical Assessment Advisory Committee panel that reviewed the
draft IRIS assessment of benzo[a]pyrene, the charge questions in this section are organized by
health outcome, with a question on each hazard identification followed by questions on the
corresponding organ/system-specific toxicity values. This suggestion, however, entails some
redundancy, as some questions apply equally to multiple health outcomes.]
3a. Nervous system effects.
(i) Nervous system hazard (Sections 1.2.1,1.3.1). The draft assessment concludes that
nervous system toxicity is a human hazard of RDX exposure. Please comment on
whether the available human, animal, and mechanistic studies support this
conclusion. Please comment on whether the selection of convulsions as the endpoint
to represent this hazard is scientifically supported and clearly described.
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(ii) Nervous system-specific toxicity values (Section 2.1.1). Please comment on
whether the selection of studies reporting nervous system effects is scientifically
supported and clearly described. Considering the difference in toxicokinetics between
gavage and dietary administration (described in Appendix C, Section C.l, and in the
context of specific hazards in the toxicological review), is it appropriate to consider
the Crouse et al. (2006) study, which used gavage administration? Please comment on
whether the characterization of convulsions as a severe endpoint, and the potential
relationship to mortality, is appropriately described.
(iii) Points of departure for nervous system endpoints (Section 2.1.2). Please comment
on whether the calculation of PODs for these studies is scientifically supported and
clearly described. Does the severity of convulsions warrant the use of a benchmark
response level of 1% extra risk? Is calculation of the lower bound on the benchmark
dose (BMDL) for convulsions appropriate and consistent with the EPA's Benchmark
Dose Guidance?
(iv) Uncertainty factors for nervous system endpoints (Section 2.1.3). Please comment
on whether the application of uncertainty factors to these PODs is scientifically
supported and clearly described. The subchronic and database uncertainty factors
incorporate multiple considerations; please comment specifically on the scientific
rationale for the application of a subchronic uncertainty factor of 1 and a database
uncertainty factor of 3.1
(v) Nervous system-specific reference dose (Section 2.1.4). Please comment on
whether the organ/system-specific reference dose derived for nervous system effects
is scientifically supported and clearly characterized.
3b. Kidney and other urogenital system effects.
(i) Kidney and other urogenital system hazard (Sections 1.2.2,1.3.1). The draft
assessment concludes that kidney and other urogenital system toxicity is a potential
human hazard of RDX exposure. Please comment on whether the available human,
animal, and mechanistic studies support this conclusion. Please comment on whether
the selection of suppurative prostatitis as the endpoint to represent this hazard is
scientifically supported and clearly described.
(ii) Kidney and other urogenital system-specific toxicity values (Section 2.1.1). Please
comment on whether the selection of the Levine et al. (1983) study that describes
kidney and other urogenital system effects is scientifically supported and clearly
described.
(iii) Points of departure for kidney and other urogenital system endpoints (Section
2.1.2). Please comment on whether the calculation of a POD for this study is
scientifically supported and clearly described.
1 Note that the database uncertainty factor applies to each of the hazards identified in the toxicological
review.
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(iv) Uncertainty factors for kidney and other urogenital system endpoints (Section
2.1.3). Please comment on whether the application of uncertainty factors to the POD is
scientifically supported and clearly described.
(v) Kidney and other urogenital system-specific reference dose (Section 2.1.4).
Please comment on whether the organ/system-specific reference dose derived for
kidney and other urogenital system effects is scientifically supported and clearly
characterized.
3c. Developmental and reproductive system effects.
(i) Developmental and reproductive system hazard (Sections 1.2.3,1.3.1). The draft
assessment concludes that there is suggestive evidence of male reproductive effects
associated with RDX exposure, based on evidence of testicular degeneration in male
mice. The draft assessment did not draw any conclusions as to whether
developmental effects are a human hazard of RDX exposure. Please comment on
whether the available human, animal, and mechanistic studies support these
conclusions.
(ii) Reproductive system-specific toxicity values (Section 2.1.1). Please comment on
whether the selection of the Lish et al. (1984) study that describes male reproductive
system effects is scientifically supported and clearly described.
(iii) Points of departure for reproductive system endpoints (Section 2.1.2). Please
comment on whether the calculation of a POD for this study is scientifically supported
and clearly described.
(iv) Uncertainty factors for reproductive system endpoints (Section 2.1.3). Please
comment on whether the application of uncertainty factors to the POD is scientifically
supported and clearly described.
(v) Reproductive system-specific reference dose (Section 2.1.4). Please comment on
whether the organ/system-specific reference dose derived for reproductive system
effects is scientifically supported and clearly characterized.
3d. Other noncancer hazards (Sections 1.2.4,1.2.6,1.3.1). The draft assessment did not draw
any conclusions as to whether liver, ocular, musculoskeletal, cardiovascular, immune, or
gastrointestinal effects are human hazards of RDX exposure. Please comment on whether
the available human, animal, and mechanistic studies support this conclusion.
3e. Cancer.
(i) Cancer hazard (Sections 1.2.5,1.3.2). There are plausible scientific arguments for
more than one hazard descriptor as discussed in Section 1.3.2. The draft assessment
concludes that there is suggestive evidence of carcinogenic potential for RDX, and that
this descriptor applies to all routes of human exposure. Please comment on whether
the available human, animal, and mechanistic studies support this conclusion.
(ii) Cancer-specific toxicity values (Section 2.3.1). As noted in EPA's 2005 Guidelines for
Carcinogen Risk Assessment, "When there is suggestive evidence, the Agency generally
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would not attempt a dose-response assessment, as the nature of the data generally
would not support one; however, when the evidence includes a well-conducted study,
quantitative analyses may be useful for some purposes, for example, providing a sense
of the magnitude and uncertainty of potential risks, ranking potential hazards, or
setting research priorities." Does the draft assessment adequately explain the
rationale for quantitative analysis, considering the uncertainty in the data and the
suggestive nature of the weight of evidence, and is the selection of the Lish et al.
(1984) study for this purpose scientifically supported and clearly described?
(iii) Points of departure for cancer endpoints (Section 2.3.2, 2.3.3). Please comment on
whether the calculation of PODs and oral slope factors is scientifically supported and
clearly described.
4. Dose-response analysis. In Chapter 2, the draft assessment uses the available human, animal,
and mechanistic studies to derive candidate toxicity values for each hazard that is credibly
associated with RDX exposure in Chapter 1, identify an organ/system-specific RfD, then selects
an overall toxicity value for each route of exposure. The draft assessment uses EPA's guidance
documents (see http://www.epa.gov/iris/basic-information-about-integrated-risk-
information-system#guidance) in the following analyses.
4a. Oral reference dose for effects other than cancer (Sections 2.1.5-2.1.8). The draft
assessment presents an overall oral reference dose of 3 x 10 3 mg/kg-day, based on nervous
system effects as described in the Crouse et al. (2006) study. Please comment on whether
this selection is scientifically supported and clearly described, including consideration of
mortality as described in Section 2.1.6, and consideration of the organ/system-specific
reference dose derived from the toxicity study by Cholakis et al. (1980) that is lower (by
approximately fivefold) as described in Section 2.1.4.
4b. Inhalation reference concentration for effects other than cancer (Section 2.2). The
draft assessment does not derive an inhalation reference concentration as the available
studies were insufficient to characterize inhalation hazard and conduct dose-response
analysis, and no toxicokinetic studies of RDX were available to support development of a
PBPK inhalation model. If you believe that the available data might support an inhalation
reference concentration, please describe how one might be derived.
4c. Oral slope factor for cancer (Section 2.3.3-2.3.4). The draft assessment presents an
overall oral slope factor of 0.038 per mg/kg-day based the combination of liver and lung
tumors in female mice. Please comment on whether this derivation is scientifically
supported and clearly described.
4d. Inhalation unit risk for cancer (Section 2.4). The draft assessment does not derive an
inhalation unit risk because inhalation carcinogenicity data were not available, nor were
toxicokinetic studies of inhalation of RDX available to support development of an inhalation
PBPK model. If you believe that the available data might support an inhalation unit risk,
please describe how one might be derived.
5. Executive summary. Does the executive summary clearly and appropriately present the major
conclusions of the assessment?
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