机器学习在临床前药物发现中的应用。

Machine learning in preclinical drug discovery.

机构信息

Department of Biochemistry and Biomedical Sciences, McMaster University, Hamilton, Ontario, Canada.

Michael G. DeGroote Institute for Infectious Disease Research, McMaster University, Hamilton, Ontario, Canada.

出版信息

Nat Chem Biol. 2024 Aug;20(8):960-973. doi: 10.1038/s41589-024-01679-1. Epub 2024 Jul 19.

DOI:10.1038/s41589-024-01679-1

PMID:39030362

Abstract

Drug-discovery and drug-development endeavors are laborious, costly and time consuming. These programs can take upward of 12 years and cost US $2.5 billion, with a failure rate of more than 90%. Machine learning (ML) presents an opportunity to improve the drug-discovery process. Indeed, with the growing abundance of public and private large-scale biological and chemical datasets, ML techniques are becoming well positioned as useful tools that can augment the traditional drug-development process. In this Perspective, we discuss the integration of algorithmic methods throughout the preclinical phases of drug discovery. Specifically, we highlight an array of ML-based efforts, across diverse disease areas, to accelerate initial hit discovery, mechanism-of-action (MOA) elucidation and chemical property optimization. With advances in the application of ML across diverse therapeutic areas, we posit that fully ML-integrated drug-discovery pipelines will define the future of drug-development programs.

摘要

药物发现和药物开发的工作既艰苦又昂贵，而且耗时。这些项目可能需要 12 年以上的时间，花费 25 亿美元，失败率超过 90%。机器学习（ML）为改善药物发现过程提供了机会。实际上，随着公共和私人大规模生物和化学数据集的日益丰富，ML 技术已成为有用的工具，可以增强传统的药物开发过程。在本观点中，我们讨论了在药物发现的临床前阶段整合算法方法。具体来说，我们强调了一系列基于机器学习的努力，涵盖了不同的疾病领域，以加速初始命中发现、作用机制（MOA）阐明和化学性质优化。随着 ML 在不同治疗领域的应用的进步，我们认为完全集成 ML 的药物发现管道将定义药物开发计划的未来。

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机器学习在临床前药物发现中的应用。

Machine learning in preclinical drug discovery.

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