Explainable AI and tree-based ensemble models: a comparative study in predicting chemical pulmonary toxicity

Keerthana Jaganathan, P. R. Geethika, Shanmugam Ramakrishnan, Dhanasekar Sundaram
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Abstract

Chemical-induced pulmonary toxicity, characterized by adverse respiratory effects from various drugs or chemicals, is increasingly becoming a point of concern for the pharmaceutical and chemical sectors, as well as public health. Traditional toxicity prediction methods are not only expensive but also demand significant time and effort. In response to these challenges, we focus on computational models to identify potential pulmonary toxicants early in the drug development process. Early identification of toxicity not only enhances the safety and efficiency of drugs and chemicals but also helps prevent late-stage drug withdrawals. In this study, we compared various sets of molecular descriptors and fingerprints using Mordred and RDKit software. We systematically employed feature selection techniques to identify the key molecular and structural features that significantly affect the model’s performance. We then applied a variety of tree-based ensemble machine-learning algorithms to build the proposed model, using a tenfold cross-validation methodology to enhance the model’s ability to predict pulmonary toxicity. We subsequently evaluated the proposed model’s performance using both a test set and a separate external validation set to assess reliability. The proposed optimal tree-ensemble model achieved an accuracy of 85.07% during tenfold cross-validation and 86.88% on the test set. Additionally, we applied the SHapley Additive exPlanations (SHAP) approach to gain deeper insights into the crucial molecular features influencing pulmonary toxicity predictions. Thus, the proposed model emerged as a promising tool for the early screening of potential pulmonary toxic compounds, enhancing chemical safety and providing interpretability for the predictions.

Abstract Image

可解释人工智能和基于树的集合模型:预测化学物质肺毒性的比较研究
化学物质引起的肺毒性是指各种药物或化学物质对呼吸系统造成的不良影响,它正日益成为制药和化工行业以及公共卫生领域关注的焦点。传统的毒性预测方法不仅成本高昂,而且需要花费大量的时间和精力。为了应对这些挑战,我们将重点放在计算模型上,以便在药物开发过程的早期识别潜在的肺毒性物质。早期识别毒性不仅能提高药物和化学品的安全性和效率,还有助于防止后期药物撤回。在这项研究中,我们使用 Mordred 和 RDKit 软件比较了各种分子描述符和指纹集。我们系统地采用了特征选择技术,以确定对模型性能有重大影响的关键分子和结构特征。然后,我们应用了多种基于树的集合机器学习算法来构建所提出的模型,并使用十倍交叉验证方法来提高模型预测肺毒性的能力。随后,我们使用测试集和单独的外部验证集评估了拟议模型的性能,以评估其可靠性。在十倍交叉验证过程中,所提出的最优树状组合模型的准确率达到了 85.07%,在测试集上的准确率达到了 86.88%。此外,我们还应用了 SHapley Additive exPlanations(SHAP)方法,以深入了解影响肺毒性预测的关键分子特征。因此,所提出的模型有望成为早期筛选潜在肺毒性化合物的工具,从而提高化学安全性并为预测提供可解释性。
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