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Slide 2 of 38. Uses of Mechanistic Data in Risk Assessment . Identify Key biological (precursor) events leading to adverse toxicities (Mode of Action)InformHuman relevance of animal findingsDose response extrapolationLife stage susceptibilitiesUnderstandCommon pathways of toxicity (cumulativ
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1. Slide 1 of 38 Drs. Vicki Dellarco & Anna LowitHealth Effects DivisionOffice of Pesticide Programs Mode of Action/ Human Relevance Analysis For Incorporating Mechanistic Data in Human Health Risk
2. Slide 2 of 38 Uses of Mechanistic Data in Risk Assessment Identify
Key biological (precursor) events leading to adverse toxicities (Mode of Action)
Inform
Human relevance of animal findings
Dose response extrapolation
Life stage susceptibilities
Understand
Common pathways of toxicity (cumulative risk assessment)
Promote
Consistent harmonized approach to risk assessment for all health endpoints
3. Slide 3 of 38 II
4. Slide 4 of 38 Mode of Action Framework EPA’s Guidelines for Carcinogen Risk Assessment
1996 Proposed Revisions
put forth the notion of understanding mode of action versus mechanism of action
1999 Interim Guidance
introduced mode of action framework
2005 Final Guidance
minor rewording of MOA framework
5. Slide 5 of 38 Mode of Action Framework Postulated mode of action
Identify sequence of key events on the path to cancer
Experimental support
Concordance of dose-response for key events with that for tumors
Temporal relationships for key events & tumors
Biological plausibility & Coherence
Strength, consistency & specificity
Other modes of action
Identify uncertainties
Conclusion
6. Slide 6 of 38 Human Relevance Framework Risk Sciences Institute-ILSI
Comparability or concordance analysis of the key events & relevant biology between the laboratory species & humans
Tumor Responses: Meek et al., 2003, Critical Reviews in Toxicology Vol 33/Issue 6, 581-653
Reproductive, Developmental, Neurtoxocity Responses: Seed et al., 2005 Critical Reviews in Toxicology Vol 35/Issue 8-9, 63-781
extended human relevance analysis to include mutagenic carcinogens & noncancer end points
WHO/IPCS Human Relevance Framework (in preparation)
7. Slide 7 of 38 Human Relevance Framework Based on three analyses:
Is the Weight of Evidence sufficient to establish a MOA in animals (MOA Framework)?
Are the key events in the animal MOA plausible in humans?
Taking into account kinetic/dynamic factors, is the animal MOA plausible in humans?
8. Slide 8 of 38
9. Slide 9 of 38 Assessing an Animal Mode of Action General Points:
Applicable to all chemicals, to all endpoints, and to all modes of action
Evaluation of MOA for tumors or (other adverse effects) in different organs
MOA in different organs may or may not be the same
Site concordance between animals & humans
10. Slide 10 of 38 Assessing an Animal Mode of Action General Points:
When a substance operates via a novel MOA, the analysis is focused on the chemical & entails a detailed evaluation via the MOA Framework
When a substance produces an adverse effect consistent with an already established & peer reviewed MOA through which other chemicals have been shown to operate, the analysis is focused on the established MOA & a determination of whether the substance operates via the same key events established for the pathway
11. Slide 11 of 38 Assessing an Animal Mode of Action for Human Relevance General Points:
Concordance Analysis of key events is for the MOA & is not necessarily a chemical specific evaluation.
Chemical specific & generic information relevant to the toxicity process can be valuable
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14. Slide 14 of 38 Case StudyCacodylic Acid (Dimethylarsinic acid)
15. Slide 15 of 38 DMAV Mode of Action Science Issue Paper: “Mode of Carcinogenic Action for Cacodylic Acid (Dimethylarsinic Acid, DMAV) and Recommendations for Dose Response Extrapolation” (July 26, 2005)
http://www.epa.gov/oppsrrd1/reregistration/cacodylic_acid/
Revised issue paper will be publicly available this spring.
EPA’s Science Advisory Board (SAB) reviewed the special issue paper in September, 2005
Draft SAB report December 27, 2005
16. Metabolism of Arsenic
17. Slide 17 of 38 DMAV: MODE OF ACTION ANALYSIS Extensive experimental cellular and laboratory animal data
18. Slide 18 of 38 DMAV: Available Cancer Data No epidemiology data
Standard rodent bioassay
Bladder carcinogen in rats
via feed -100 ppm (9.4 mg/kg bw per day)
via drinking water- 50 & 200 ppm
females more sensitive than males
Not carcinogenic in mice
Up to 500 ppm in B6C3F (Gurr et al., 1989)
121 ppm in C57 XC3H/Anf or AKR (NCI 1969)
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22. Slide 22 of 38 Cacodylic Acid: Key Events Temporal Relationship
23. Slide 23 of 38 Cacodylic Acid: Key EventsCytotoxicity/Regenerative Proliferation Strength, Consistency & Specificity
Consistency of association found in repeated experiments within a lab & among different labs
Inhibition of DMAV ?DMAIII reduced cytotoxicity
Cessation of exposure to DMAV results in recovery of tissue (i.e., hyperplasia)
Biological Plausibility & Coherence
Regenerative proliferation associated with persistent toxicity appears to be a risk factor for bladder cancer in humans
24. Slide 24 of 38 Characterization of Cacodylic Acid’s Genotoxicity Neither DMAV or DMAIII are direct acting point/gene mutagens
Both are clastogenic but DMAIII is the more potent
In vitro data only
DNA damage appears to result from an indirect mechanism (ROS/oxidative damage)
DMAIII ? DMAV
25. Slide 25 of 38 Chromosomal Aberrations For the oxidative DNA damage to be relevant to the carcinogenic process (i.e., clonally expanded), stable chromosomal mutations must be formed
Formation of chromosomal mutations requires DNA replication because chromosomal alterations are produced by errors of replication on a damaged DNA template.
frequency of chromosomal mutations will be a function of the regenerative proliferative response.
All these events--genetic errors, cytotoxicity, stimulation in cell proliferaiton -- must occur to result in bladder tumors.
26. Slide 26 of 38 Other Modes of Action or Key Events No other MOA with sufficient scientific support
Direct DNA reactivity
Formation of solids
Changes in urinary chemistry & physiology
27. Slide 27 of 38 Mode of Action Conclusions Sequence of key events leading to bladder tumors measurable & supported by robust data
Biologically plausible
Uncertainties do not discount scientific support
cellular target for cytotoxicity not understood
unknown cytotoxic metabolites found in urine (after drinking water exposure)
28. Slide 28 of 38 Human Relevance of DMAV’s Mode of Action
29. Slide 29 of 38 Concordance Analysis of Key Events in Rats & Humans: Qualitative & Quantitative Plausibility
30. Slide 30 of 38 DMAV Mode of Action (MOA)
The SAB concurred with EPA’s conclusions
Rat data developed for DMAV most appropriate data for quantifying cancer risk
MOA for the development of bladder tumors in rats established
The rat MOA is expected to be plausible in humans
The MOA supports nonlinear extrapolation of cancer risk to DMAV
31. Slide 31 of 38 Dose response extrapolation approach Dose response extrapolation should be based on considerations of MOA which supports nonlinearity
Must be sufficient DMAIII to produce cell killing & sufficient cell killing to lead to regenerative proliferation
Cytotoxicity & enhanced proliferation need to be sustained
Frequency of chromosomal mutations dependent on enhanced proliferation & on generation of ROS (DMAIII ?DMAV)
Point of Departure based on cell proliferation should be protective of DMA’s carcinogenic & promoting effects
32. Slide 32 of 38 Dose Response Considerations Cancer Guidelines describe a two-step dose-response process which separates
Modeling the observable range of data
Extrapolation to lower doses
Nonlinear extrapolation
Preferred approaches
PBPK Model--internal dosimetry at the target tissue
e.g. DMAIII
BBDR Model—predict biological effect
e.g., two stage clonal growth
Interim approach
Identify a point of departure (POD) based on benchmark dose modeling
Apply uncertainty and safety factors
33. Slide 33 of 38
34. Slide 34 of 38 Benchmark Dose Modeling: Regenerative Proliferation
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37. Slide 37 of 38 Summary Human Relevance Framework
Identify key events
Assist in dose response assessment
Assist in rodent to human extrapolation
Promote harmonization of risk assessment for all endpoints