2017
DOI: 10.1016/j.yrtph.2017.02.015
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Retrospective mining of toxicology data to discover multispecies and chemical class effects: Anemia as a case study

Abstract: Predictive toxicity models rely on large amounts of accurate in vivo data. Here, we analyze the quality of in vivo data from the U.S. EPA Toxicity Reference Database (ToxRefDB), using chemical-induced anemia as an example. Considerations include variation in experimental conditions, changes in terminology over time, distinguishing negative from missing results, observer and diagnostic bias, and data transcription errors. Within ToxRefDB, we use hematological data on 658 chemicals tested in one or more of 1738 … Show more

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Cited by 15 publications
(7 citation statements)
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“…It is, therefore, often a challenge to conclude on a similar toxicological hazard of the grouped compounds mainly based on apical findings. In vivo data inherit a certain variability, because of, e.g., small differences in the study design of the animal studies [e.g., species, strains, dose selection, dose spacing, route (Judson et al 2017;Escher et al 2019)] or inter-individual variability of the tested species. A better understanding of the mechanism(s) that causes an adverse outcome will, therefore, be helpful to conclude on similarity and by this, strengthen the read-across hypothesis.…”
Section: Read-across Workflowmentioning
confidence: 99%
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“…It is, therefore, often a challenge to conclude on a similar toxicological hazard of the grouped compounds mainly based on apical findings. In vivo data inherit a certain variability, because of, e.g., small differences in the study design of the animal studies [e.g., species, strains, dose selection, dose spacing, route (Judson et al 2017;Escher et al 2019)] or inter-individual variability of the tested species. A better understanding of the mechanism(s) that causes an adverse outcome will, therefore, be helpful to conclude on similarity and by this, strengthen the read-across hypothesis.…”
Section: Read-across Workflowmentioning
confidence: 99%
“…The in vivo data showed some predominately shared toxic effects, but also a number of individual effects at several dose levels. This finding could be the result of differences in tested strains or species, study design (e.g., selection of doses and dose spacing), scope of examination or testing in different laboratories/years (Escher et al 2019;Judson et al 2017). As in vivo data do not directly indicate the underlying MoA, it is often a challenge to define categories based solely on apical in vivo findings.…”
Section: Read-across Examples and Challengesmentioning
confidence: 99%
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“…The liver is a key organ in terms of toxicology and crucial in interpreting repeated dose toxicity ( 25 27 ). Obviously the liver has a vital physiological role and is prone to toxicity due to high, first-pass, blood flow which increases the likelihood of toxicants reaching a significant concentration.…”
Section: In Silico Modelling Of Liver Toxicitymentioning
confidence: 99%
“…Read‐across requires a similarity assessment of the grouped compounds in terms of toxicokinetic and dynamic properties. It is often a challenge to reach a conclusion on the similar adverse toxicological effect pattern, as the apical findings might vary in the type, severity and lowest observed adverse effect level within the grouped compounds (Judson et al., ). Another difficulty is that, apical findings from in vivo data often do not enable a mechanistic understanding of the observed adverse outcomes.…”
Section: Moving Towards a Holistic Approach For Human Health Risk Assmentioning
confidence: 99%