Litcius/Paper detail

Machine Learning for Predicting Risk of Drug-Induced Autoimmune Diseases by Structural Alerts and Daily Dose

Yue Wu, Jieqiang Zhu, Peter P. Fu, Weida Tong, Huixiao Hong, Minjun Chen

2021International Journal of Environmental Research and Public Health12 citationsDOIOpen Access PDF

Abstract

An effective approach for assessing a drug’s potential to induce autoimmune diseases (ADs) is needed in drug development. Here, we aim to develop a workflow to examine the association between structural alerts and drugs-induced ADs to improve toxicological prescreening tools. Considering reactive metabolite (RM) formation as a well-documented mechanism for drug-induced ADs, we investigated whether the presence of certain RM-related structural alerts was predictive for the risk of drug-induced AD. We constructed a database containing 171 RM-related structural alerts, generated a dataset of 407 AD- and non-AD-associated drugs, and performed statistical analysis. The nitrogen-containing benzene substituent alerts were found to be significantly associated with the risk of drug-induced ADs (odds ratio = 2.95, p = 0.0036). Furthermore, we developed a machine-learning-based predictive model by using daily dose and nitrogen-containing benzene substituent alerts as the top inputs and achieved the predictive performance of area under curve (AUC) of 70%. Additionally, we confirmed the reactivity of the nitrogen-containing benzene substituent aniline and related metabolites using quantum chemistry analysis and explored the underlying mechanisms. These identified structural alerts could be helpful in identifying drug candidates that carry a potential risk of drug-induced ADs to improve their safety profiles.

Topics & Concepts

DrugSubstituentMetaboliteOdds ratioOddsAnilineWorkflowMedicinePharmacologyChemistryComputer scienceMachine learningLogistic regressionDatabaseStereochemistryInternal medicineOrganic chemistryComputational Drug Discovery MethodsPharmacogenetics and Drug MetabolismBiosimilars and Bioanalytical Methods