Accounting for data variability, a key factor in in vivo/in vitro relationships: application to the skin sensitization potency (in vivo LLNA versus in vitro DPRA) example

Abstract: When searching for alternative methods to animal testing, confidently rescaling an in vitro result to the corresponding in vivo classification is still a challenging problem. Although one of the most important factors affecting good correlation is sample characteristics, they are very rarely integrated into correlation studies. Usually, in these studies, it is implicitly assumed that both compared values are error-free numbers, which they are not. In this work, we propose a general methodology to analyze and i… Show more

“…Kolle et al (2013) defined a range around the classification threshold of the LLNA, within which discordant outcomes can be expected, by determining coefficients of variation based on individual animal data. This range is called the "borderline range" (BR) (Kolle et al, 2013) or "grey zone" (Dimitrov et al, 2016). The percentage of substances that fall into the BR of a test method's prediction model reflects how limited a test method's precision is.…”

The borderline range of toxicological methods: Quantification and implications for evaluating precision

“…Kolle et al (2013) defined a range around the classification threshold of the LLNA, within which discordant outcomes can be expected, by determining coefficients of variation based on individual animal data. This range is called the "borderline range" (BR) (Kolle et al, 2013) or "grey zone" (Dimitrov et al, 2016). The percentage of substances that fall into the BR of a test method's prediction model reflects how limited a test method's precision is.…”

The borderline range of toxicological methods: Quantification and implications for evaluating precision

“…As shown for the case of skin sensitisation potential assessment, technical and biological variability can lead to misclassifications (Kolle et al, 2013;Hoffmann, 2015;Dimitrov et al, 2016;Dumont et al, 2016). The impact of biological and technical variability of the LLNA on the misclassification of substances, is associated with the fact that the classification of substances as "sensitisers/non-sensitisers" is based on clear-cut thresholds (Hoffmann, 2015).…”

“…The uncertainty of information derived from toxicity testing has been frequently discussed in the toxicology literature (Paparella et al, 2013;Heringa et al, 2015). For example, the impact of technical and biological variability on test results derived from testing methods (Kolle et al, 2013;Hoffmann, 2015;Dimitrov et al, 2016;Dumont et al, 2016;Leontaridou et al, 2017a), and the effect of overfitting experimental data from testing (Kopp-Schneider et al, 2013) have been discussed. However, the estimation of non-animal testing methods' borderline range and the identification of substances yielding borderline test results provide a novel approach to classify substances, to identify discordant test results and to decide if additional information is needed.…”

“…Specifically, we analyse limitations with regard to the reproducibility of results when continuous dose-response data are transformed into "toxic/ non-toxic" outcomes. Kolle et al (2013), Hoffmann (2015), Dumont et al, (2016), and Dimitrov et al (2016) analysed the intra-assay variability of the LLNA. Kolle et al (2013), showed that outcomes of repeated testing of a substance are not always concordant.…”

“…This may lead to erroneous hazard classifications and to over-or underestimation errors of a testing method's predictive capacity. Again, using skin sensitisation as an illustrative case we showed that ambiguity of hazard classification is a general problem that applies to both animal tests (Kolle et al, 2013;Hoffmann, 2015;Dimitrov et al, 2016) and non-animal testing methods. Defining a quantifiable measure for this ambiguity, called "borderline range", Chapter 4 allows assessing its impact on the predictive accuracy of (non-animal) testing methods, i.e.…”

An economic approach to non-animal toxicity testing for skin sensitisation

A convenient spectrophotometric test for screening skin-sensitizing chemicals using reactivity with glutathione in chemico