Literature review and appraisal on alternative neurotoxicity testing methods

Masjosthusmann, Stefan; Barenys, Marta; El‐Gamal, Mohammed I.; Geerts, Lieve; Gerosa, Laura; Gorreja, Adriana; Kühne, Britta Anna; Marchetti, Natalia; Tigges, Julia; Viviani, Bárbara; Witters, Hilda; Fritsche, Ellen

doi:10.2903/sp.efsa.2018.en-1410

Cited by 21 publications

(27 citation statements)

References 125 publications

(107 reference statements)

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“…In a large study of about 900 chemicals, C. elegans was nearly as good at predicting developmental toxicity in rats or rabbits as those two species were at predicting each other ( Boyd et al, 2016 ). Additionally, the toxicodynamics and apical effects of many types of chemicals are similar in C. elegans and mammals, indicating that the C. elegans model has the potential to contribute useful information to human predictive integrated testing strategies ( Hartman et al, 2021 , Masjosthusmann et al, 2018 , Parish et al, 2020 ).…”

Section: Discussionmentioning

confidence: 99%

“…A single C. elegans technician can assess a dozen or more compounds or concentrations in a week for endpoints such as viability, locomotor activity, developmental timing, or pathway of toxicity specific transgene expression. While this type of low-to-medium-throughput C. elegans screening cannot replace a descriptive toxicology study in lab mammals, it is very rapid and inexpensive by comparison, and can provide useful information on conserved modes of toxic action and apical endpoint responses ( Avila et al, 2020 , Hartman et al, 2021 , Masjosthusmann et al, 2018 , Parish et al, 2020 ). Several studies have demonstrated that toxicity ranking screens in C. elegans can predict developmental toxicity or LD50 ranking in mammals ( Boyd et al, 2010 , Boyd et al, 2016 , Hunt et al, 2012 , Li et al, 2013 ), indicating that C. elegans has the potential to provide a bridge between in vitro human cell based assays and mammalian in vivo oral toxicity testing ( Lagido et al, 2015 ).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Assessment of the effects of organic vs. inorganic arsenic and mercury in Caenorhabditis elegans

Camacho

Conti

Pogribny

et al. 2022

Current Research in Toxicology

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Assessment of the effects of organic vs. inorganic arsenic and mercury in Caenorhabditis elegans

Camacho

Conti

Pogribny

et al. 2022

Current Research in Toxicology

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“…The European Food Safety Agency (EFSA) is responsible for the registration of pesticides and all other substances that can contact or occur in food and are not assessed under REACH. Until now, the active compounds in pesticides need to be assessed for potential neurotoxic effects in mammals using the same rodent studies as under REACH (TG 424 and TG 426) only if it is indicative from their intended MoA or other information, like chemical structure, that the substance could be neurotoxic [23]. Neurotoxic effects on non-target species in the environment are not assessed.…”

Section: Current Role Of Eco-neurotoxicology In Risk Assessment For Rmentioning

confidence: 99%

An ecotoxicological view on neurotoxicity assessment

et al. 2018

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The numbers of potential neurotoxicants in the environment are raising and pose a great risk for humans and the environment. Currently neurotoxicity assessment is mostly performed to predict and prevent harm to human populations. Despite all the efforts invested in the last years in developing novel in vitro or in silico test systems, in vivo tests with rodents are still the only accepted test for neurotoxicity risk assessment in Europe. Despite an increasing number of reports of species showing altered behaviour, neurotoxicity assessment for species in the environment is not required and therefore mostly not performed. Considering the increasing numbers of environmental contaminants with potential neurotoxic potential, eco-neurotoxicity should be also considered in risk assessment. In order to do so novel test systems are needed that can cope with species differences within ecosystems. In the field, online-biomonitoring systems using behavioural information could be used to detect neurotoxic effects and effect-directed analyses could be applied to identify the neurotoxicants causing the effect. Additionally, toxic pressure calculations in combination with mixture modelling could use environmental chemical monitoring data to predict adverse effects and prioritize pollutants for laboratory testing. Cheminformatics based on computational toxicological data from in vitro and in vivo studies could help to identify potential neurotoxicants. An array of in vitro assays covering different modes of action could be applied to screen compounds for neurotoxicity. The selection of in vitro assays could be guided by AOPs relevant for eco-neurotoxicity. In order to be able to perform risk assessment for eco-neurotoxicity, methods need to focus on the most sensitive species in an ecosystem. A test battery using species from different trophic levels might be the best approach. To implement eco-neurotoxicity assessment into European risk assessment, cheminformatics and in vitro screening tests could be used as first approach to identify eco-neurotoxic pollutants. In a second step, a small species test battery could be applied to assess the risks of ecosystems.

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“…This aspect was further verified by predicting a series of known neurotoxicants with the models predicting MIEs. The mode of action for these neurotoxicants was reported in a review by Masjosthusmann and coworkers [ 36 ] who gathered information from the literature about the targets upstream of the neurotoxicological pathway of these chemicals [ 11 , 12 , 37 ]. Interestingly, QSARs for the prediction of MIEs were able to identify the correct mode of action of several neurotoxicants.…”

Section: Discussionmentioning

confidence: 99%

Prediction of the Neurotoxic Potential of Chemicals Based on Modelling of Molecular Initiating Events Upstream of the Adverse Outcome Pathways of (Developmental) Neurotoxicity

Gadaleta

Spînu

Roncaglioni

et al. 2022

IJMS

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Developmental and adult/ageing neurotoxicity is an area needing alternative methods for chemical risk assessment. The formulation of a strategy to screen large numbers of chemicals is highly relevant due to potential exposure to compounds that may have long-term adverse health consequences on the nervous system, leading to neurodegeneration. Adverse Outcome Pathways (AOPs) provide information on relevant molecular initiating events (MIEs) and key events (KEs) that could inform the development of computational alternatives for these complex effects. We propose a screening method integrating multiple Quantitative Structure–Activity Relationship (QSAR) models. The MIEs of existing AOP networks of developmental and adult/ageing neurotoxicity were modelled to predict neurotoxicity. Random Forests were used to model each MIE. Predictions returned by single models were integrated and evaluated for their capability to predict neurotoxicity. Specifically, MIE predictions were used within various types of classifiers and compared with other reference standards (chemical descriptors and structural fingerprints) to benchmark their predictive capability. Overall, classifiers based on MIE predictions returned predictive performances comparable to those based on chemical descriptors and structural fingerprints. The integrated computational approach described here will be beneficial for large-scale screening and prioritisation of chemicals as a function of their potential to cause long-term neurotoxic effects.

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Literature review and appraisal on alternative neurotoxicity testing methods

Cited by 21 publications

References 125 publications

Assessment of the effects of organic vs. inorganic arsenic and mercury in Caenorhabditis elegans

Assessment of the effects of organic vs. inorganic arsenic and mercury in Caenorhabditis elegans

An ecotoxicological view on neurotoxicity assessment

Prediction of the Neurotoxic Potential of Chemicals Based on Modelling of Molecular Initiating Events Upstream of the Adverse Outcome Pathways of (Developmental) Neurotoxicity

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