Abstract
In vivo micronucleus assay is the widely used genotoxic test to determine the extent of chromosomal aberrations caused by the chemicals in human beings, which plays a significant role in the drug discovery paradigm. To reduce the uncertainties of the in vivo experiments and the expenses, we intended to develop novel machine learning-based tools to predict the toxicity of the compounds with high precision. A total of 372 compounds with known toxicity information were retrieved from the PubChem Bioassay database and literature. The fingerprints and descriptors of the compounds were generated using PaDEL and ChemSAR, respectively, for the analysis. The performance of the models was assessed using the three tires of evaluation strategies such as fivefold, tenfold, and validation by external dataset. Further, structural alerts causing genotoxicity of the compounds were identified using SARpy method. Of note, fingerprint-based random forest model built in our analysis is able to demonstrate the highest accuracy of about 0.97 during tenfold cross-validation. In essence, our study highlights that structural alerts such as chlorocyclohexane and trimethylamine are likely to be the leading cause of toxicity in humans. Indeed, we believe that random forest model generated in this study is appropriate for reduction of test animals and should be considered in the future for the good practice of animal welfare.
Highlights
Humans are confronted with various chemicals, including cosmetics, food additives, pesticides, and drugs
The 272 compounds obtained from the PubChem Bioassay database were used for model development. (ii) around 100 compounds analyzed with micronucleus assay were retrieved from the literature published between 2004 and 2020 and utilized for external validation of the generated models
Around 3481 bits of molecular fingerprints and 325 features of descriptor clusters were generated for each compound using PaDEL and ChemSAR tools, respectively
Summary
Humans are confronted with various chemicals, including cosmetics, food additives, pesticides, and drugs. These are the significant causes of mutagenicity or irreversible damage to genetic material, causing multiple negative impacts on human health, including cancer [1]. Appropriate toxicity tests are implemented by the regulatory to measure the genotoxicity of compounds causing mutations at both genetic and chromosome levels. In vitro methods were implemented for examining the toxicity of the compounds. The positive compounds were further validated through in vivo studies [2]. In vivo micronucleus assay successfully determines the genotoxicity of the compounds obtained as positive during in vitro tests
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