Kerry L. Dearfield scite author profile

Genetic toxicology data have traditionally been employed for qualitative, rather than quantitative evaluations of hazard. As a continuation of our earlier report that analyzed ethyl methanesulfonate (EMS) and methyl methanesulfonate (MMS) dose-response data (Gollapudi et al., 2013), here we present analyses of 1-ethyl-1-nitrosourea (ENU) and 1-methyl-1-nitrosourea (MNU) dose-response data and additional approaches for the determination of genetic toxicity point-of-departure (PoD) metrics. We previously described methods to determine the noobserved-genotoxic-effect-level (NOGEL), the breakpoint-dose (BPD; previously named Td), and the benchmark dose (BMD 10 ) for genetic toxicity endpoints. In this study we employed those methods, along with a new approach, to determine the non-linear slope-transition-dose (STD), and alternative methods to determine the BPD and BMD, for the analyses of nine ENU and 22 MNU datasets across a range of in vitro and in vivo endpoints. The NOGEL, BMDL 10 and BMDL 1SD PoD metrics could be readily calculated for most gene mutation and chromosomal damage studies; however, BPDs and STDs could not always be derived due toDisclaimer: This manuscript has been reviewed by the agencies and companies of the authors and approved for publication. The views expressed in the manuscript do not necessarily reflect the policy of these agencies and companies.

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Quantitative approaches for assessing dose–response relationships in genetic toxicology studies

Gollapudi

Johnson

Hernández

et al. 2012

Environ and Mol Mutagen

132

130

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Genetic toxicology studies are required for the safety assessment of chemicals. Data from these studies have historically been interpreted in a qualitative, dichotomous ''yes'' or ''no'' manner without analysis of doseresponse relationships. This article is based upon the work of an international multi-sector group that examined how quantitative dose-response relationships for in vitro and in vivo genetic toxicology data might be used to improve human risk assessment. The group examined three quantitative approaches for analyzing dose-response curves and deriving point-of-departure (POD) metrics (i.e., the no-observed-genotoxic-effectlevel (NOGEL), the threshold effect level (Td), and the benchmark dose (BMD)), using data for the induction of micronuclei and gene mutations by methyl methanesulfonate or ethyl methanesulfonate in vitro and in vivo. These results suggest that the POD descriptors obtained using the different approaches are within the same order of magnitude, with more variability observed for the in vivo assays. The different approaches were found to be complementary as each has advantages and limitations. The results further indicate that the lower confidence limit of a benchmark response rate of 10% (BMDL 10 ) could be considered a satisfactory POD when analyzing genotoxicity data using the BMD approach. The models described permit the identification of POD values that could be combined with mode of action analysis to determine whether exposure(s) below a particular level constitutes a significant human risk. Subsequent analyses will expand the number of substances and endpoints investigated, and continue to evaluate the utility of quantitative approaches for analysis of genetic toxicity dose-response data. Environ. Mol. Mutagen. 54:8-18, 2013. V V C 2012 Wiley Periodicals, Inc.

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Kerry L. Dearfield

Acrylamide: a review of its genotoxicity and an assessment of heritable genetic risk

Acrylamide: its metabolism, developmental and reproductive effects, genotoxicity, and carcinogenicity

Derivation of point of departure (PoD) estimates in genetic toxicology studies and their potential applications in risk assessment

Quantitative approaches for assessing dose–response relationships in genetic toxicology studies

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