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Quantitative in vitro to in vivo Extrapolation (IVIVE) of Genotoxicity Data Provides Protective Estimates of in vivo Dose
  • +15
  • Marc Beal,
  • Marc Audebert,
  • Tara Barton-Maclaren,
  • Hannah Battaion,
  • Jeffrey Bemis,
  • Xuefei Cao,
  • Connie Chen,
  • Stephen Dertinger,
  • Roland Froetschl,
  • Xiaoqing Guo,
  • George Johnson,
  • Giel Hendriks,
  • Laure Khoury,
  • Alexandra Long,
  • Stefan Pfuhler,
  • Raja Settivari,
  • Shamika Wickramasuriya,
  • Paul White
Marc Beal
Health Canada

Corresponding Author:[email protected]

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Marc Audebert
INRAE
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Tara Barton-Maclaren
Health Canada Healthy Environments and Consumer Safety Branch
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Hannah Battaion
Health Canada Healthy Environments and Consumer Safety Branch
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Jeffrey Bemis
Litron Laboratories
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Xuefei Cao
USFDA-NCTR
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Connie Chen
Health and Environmental Sciences Institute
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Stephen Dertinger
Litron Laboratories
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Roland Froetschl
BfArM Bundesinsitut für Arzneimittel und Medizinprodukte (Federal Institute for Drug and Medical Devices)
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Xiaoqing Guo
NCTR/FDA
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George Johnson
Swansea University
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Giel Hendriks
Toxys
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Laure Khoury
Preditox
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Alexandra Long
Health Canada
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Stefan Pfuhler
Procter & Gamble, Cosmital SA
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Raja Settivari
Corteva Agriscience
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Shamika Wickramasuriya
Health Canada Healthy Environments and Consumer Safety Branch
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Paul White
Health Canada
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Abstract

Genotoxicity assessment is a critical component in the development and evaluation of chemicals. Traditional genotoxicity assays (i.e., mutagenicity, clastogenicity, aneugenicity) have been limited to dichotomous hazard classification, while other toxicity endpoints are assessed through quantitative determination of points-of-departure (PODs) for setting exposure limits. The more recent higher-throughput in vitro genotoxicity assays, many of which also provide mechanistic information, offer a powerful approach for determining high-precision PODs for potency ranking and risk assessment. In order to obtain relevant human dose context from the in vitro assays, in vitro to in vivo extrapolation (IVIVE) models are required to determine what dose would elicit a concentration in the body demonstrated to be genotoxic using in vitro assays. Previous work has demonstrated that application of IVIVE models to in vitro bioactivity data can provide PODs that are protective of human health, but there has been no evaluation of how these models perform with in vitro genotoxicity data. Thus, the Genetic Toxicology Technical Committee, under the Health and Environmental Sciences Institute, conducted a case study on 31 reference chemicals to evaluate the performance of IVIVE application to genotoxicity data. The results demonstrate that for most chemicals (20/31), the PODs derived from in vitro data and IVIVE are highly health protective relative to in vivo PODs from animal studies. PODs were also protective by individual assay type: mutations (8/13 chemicals), micronuclei (9/12) and aneugenicity markers (4/4). It is envisioned that this novel testing strategy could enhance prioritization, rapid screening, and risk assessment of genotoxic chemicals.
12 Oct 2022Reviewer(s) Assigned
19 Nov 2022Review(s) Completed, Editorial Evaluation Pending
21 Nov 2022Editorial Decision: Revise Minor
30 Nov 20221st Revision Received
30 Nov 2022Review(s) Completed, Editorial Evaluation Pending
30 Nov 2022Submission Checks Completed
30 Nov 2022Assigned to Editor
30 Nov 2022Editorial Decision: Accept