Modern methodologies and tools for human hazard assessment of chemicals

,

doi:10.2903/j.efsa.2014.3638

Cited by 42 publications

(16 citation statements)

References 269 publications

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“…As part of the DG‐Sante, EURL ECVAM has a specific mandate specified in EU legislation and includes a number of duties to advance the 3Rs principles of animal testing. In this context and based on the internationally established principles of the 3Rs, EFSA is committed to promote use of data derived from alternative approaches or NAMs, where possible (EFSA, 2014 ). The commitment also applies to EMA, having established a specific WG on the Application of the 3Rs in Regulatory Testing of Medicinal Products (EMA, 2017a , b ) and to ECHA ( 2017 ).…”

Section: Recommendations For the Futurementioning

confidence: 99%

Scientific Opinion of the Scientific Panel on Plant Protection Products and their Residues (PPR Panel) on testing and interpretation of comparative in vitro metabolism studies

Hernández‐Jerez¹,

Adriaanse²,

Aldrich³

et al. 2021

EFS2

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EFSA asked the Panel on Plant Protection Products and their residues to deliver a Scientific Opinion on testing and interpretation of comparative in vitro metabolism studies for both new active substances and existing ones. The main aim of comparative in vitro metabolism studies of pesticide active substances is to evaluate whether all significant metabolites formed in the human in vitro test system, as a surrogate of the in vivo situation, are also present at comparable level in animal species tested in toxicological studies and, therefore, if their potential toxicity has been appropriately covered by animal studies. The studies may also help to decide which animal model, with regard to a particular compound, is the most relevant for humans. In the experimental strategy, primary hepatocytes in suspension or culture are recommended since hepatocytes are considered the most representative in vitro system for prediction of in vivo metabolites. The experimental design of 3 9 3 9 3 (concentrations, time points, technical replicates, on pooled hepatocytes) will maximise the chance to identify unique (UHM) and disproportionate (DHM) human metabolites. When DHM and UHM are being assessed, test item-related radioactivity recovery and metabolite profile are the most important parameters. Subsequently, structural characterisation of the assigned metabolites is performed with appropriate analytical techniques. In toxicological assessment of metabolites, the uncertainty factor approach is the first alternative to testing option, followed by new approach methodologies (QSAR, read-across, in vitro methods), and only if these fail, in vivo animal toxicity studies may be performed. Knowledge of in vitro metabolites in human and animal hepatocytes would enable toxicological evaluation of all metabolites of concern, and, furthermore, add useful pieces of information for detection and evaluation of metabolites in different matrices (crops, livestock, environment), improve biomonitoring efforts via better toxicokinetic understanding, and ultimately, develop regulatory schemes employing physiologically based or physiology-mimicking in silico and/or in vitro test systems to anticipate the exposure of humans to potentially hazardous substances in plant protection products.

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Section: Recommendations For the Futurementioning

confidence: 99%

Scientific Opinion of the Scientific Panel on Plant Protection Products and their Residues (PPR Panel) on testing and interpretation of comparative in vitro metabolism studies

Hernández‐Jerez¹,

Adriaanse²,

Aldrich³

et al. 2021

EFS2

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“…As the field of toxicology is moving away from "black box" animal experimentation towards approaches to better understand the internal concentrations of compounds in relation to their mecha-nisms of toxicity in humans (NRC, 2007;Thomas et al, 2017), the potential of NAMs for biokinetics is increasingly recognized by regulatory bodies (ECHA, 2014;EFSA, 2014;EMA, 2018;FDA, 2020). Formal incorporation of these approaches in regulatory toxicology (for, e.g., plant protection products, pharmaceuticals, chemicals or food additives) is, however, still limited (Gellatly and Sewell, 2019;Punt, 2018;Tan et al, 2018;Zhuang and Lu, 2016).…”

Section: Opportunities For Nams For Biokinetics In Current and Next Generation Risk Evaluations That Move Away From Animal Experimentatiomentioning

confidence: 99%

“…Table 1 provides a summary of ADME considerations within regulatory risk evaluations that can be addressed with NAMs for biokinetics. This overview was obtained by exploring EU guidelines for chemical risk evaluations within different domains (e.g., pharmaceuticals, chemical substances, food additives, cosmetics) (ECHA, 2013(ECHA, , 2014(ECHA, , 2016(ECHA, , 2017aEFSA, 2010EFSA, , 2014EMA, 2018;EU, 2010;SCCS, 2018).…”

Section: Opportunities In Current Risk Evaluationsmentioning

confidence: 99%

New approach methodologies (NAMs) for human-relevant biokinetics predictions

Punt

Bouwmeester

Blaauboer

et al. 2020

ALTEX

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Whereas much work has been devoted to the development of in vitro screening methods to capture biological effects (toxicodynamics) of chemicals, insight into the absorption, distribution, metabolism and excretion (i.e., ADME/biokinetics) of chemi- IntroductionThere are clear societal and scientific needs for the development and validation of predictive animal-free methods for safety evaluations to prevent adverse effects in humans caused by exposure

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“…The traditional use of animal models to identify potential effects of chemicals has been criticized in terms of scientific relevance, time, and costdriving the quest for suitable alternatives − Quantitative structure–activity relationship (QSAR) modeling is a widely used approach for predicting properties of chemicals, predicated on a mathematical relationship being derived between a chemical’s structure and its physicochemical or biological (toxicological) properties. Acceptance of QSAR methods is increasing with the European Chemicals Agency (ECHA) reporting that, for information on endpoints concerning vertebrate animals, 34% contain one or more QSAR predictions (6290 substances analyzed).…”

Section: Introductionmentioning

confidence: 99%

Assessment and Reproducibility of Quantitative Structure–Activity Relationship Models by the Nonexpert

Patel

Chilton

Sartini

et al. 2018

J. Chem. Inf. Model.

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Model reliability is generally assessed and reported as an intrinsic component of quantitative structure-activity relationship (QSAR) publications; it can be evaluated using defined quality criteria such as the Organisation for Economic Cooperation and Development (OECD) principles for the validation of QSARs. However, less emphasis is afforded to the assessment of model reproducibility, particularly by users who may wish to use model outcomes for decision making, but who are not QSAR experts. In this study we identified a range of QSARs in the area of absorption, distribution, metabolism, and elimination (ADME) prediction and assessed their adherence to the OECD principles, as well as investigating their reproducibility by scientists without expertise in QSAR. Here, 85 papers were reviewed, reporting over 80 models for 31 ADME-related endpoints. Of these, 12 models were identified that fulfilled at least 4 of the 5 OECD principles and 3 of these 12 could be readily reproduced. Published QSAR models should aim to meet a standard level of quality and be clearly communicated, ensuring their reproducibility, to progress the uptake of the models in both research and regulatory landscapes. A pragmatic workflow for implementing published QSAR models and recommendations to modellers, for publishing models with greater usability, are presented herein.

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Modern methodologies and tools for human hazard assessment of chemicals

Cited by 42 publications

References 269 publications

Scientific Opinion of the Scientific Panel on Plant Protection Products and their Residues (PPR Panel) on testing and interpretation of comparative in vitro metabolism studies

Scientific Opinion of the Scientific Panel on Plant Protection Products and their Residues (PPR Panel) on testing and interpretation of comparative in vitro metabolism studies

New approach methodologies (NAMs) for human-relevant biokinetics predictions

Assessment and Reproducibility of Quantitative Structure–Activity Relationship Models by the Nonexpert

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