通过药物分子量子信息的流形嵌入实现药物性肝毒性的深度学习预测

Deep Learning Prediction of Drug-Induced Liver Toxicity by Manifold Embedding of Quantum Information of Drug Molecules.

作者信息

Li Tonglei, Li Jiaqing, Jiang Hongyi, Skiles David B

机构信息

Department of Industrial & Molecular Pharmaceutics, Purdue University, 575 Stadium Mall Drive, West Lafayette, Indiana, 47907, USA.

出版信息

Pharm Res. 2025 Jan;42(1):109-122. doi: 10.1007/s11095-024-03800-4. Epub 2024 Dec 12.

DOI:10.1007/s11095-024-03800-4

PMID:39663331

Abstract

PURPOSE

Drug-induced liver injury, or DILI, affects numerous patients and also presents significant challenges in drug development. It has been attempted to predict DILI of a chemical by in silico approaches, including data-driven machine learning models. Herein, we report a recent DILI deep-learning effort that utilized our molecular representation concept by manifold embedding electronic attributes on a molecular surface.

METHODS

Local electronic attributes on a molecular surface were mapped to a lower-dimensional embedding of the surface manifold. Such an embedding was featurized in a matrix form and used in a deep-learning model as molecular input. The model was trained by a well-curated dataset and tested through cross-validations.

RESULTS

Our DILI prediction yielded superior results to the literature-reported efforts, suggesting that manifold embedding of electronic quantities on a molecular surface enables machine learning of molecular properties, including DILI.

CONCLUSIONS

The concept encodes the quantum information of a molecule that governs intermolecular interactions, potentially facilitating the deep-learning model development and training.

摘要

目的

药物性肝损伤（DILI）影响众多患者，并且在药物研发中也带来了重大挑战。人们一直试图通过计算机方法预测化学物质的DILI，包括数据驱动的机器学习模型。在此，我们报告了一项近期关于DILI的深度学习研究，该研究通过在分子表面嵌入电子属性来利用我们的分子表示概念。

方法

分子表面的局部电子属性被映射到表面流形的低维嵌入中。这种嵌入以矩阵形式进行特征化，并作为分子输入用于深度学习模型。该模型由精心策划的数据集进行训练，并通过交叉验证进行测试。

结果

我们的DILI预测产生了优于文献报道研究的结果，这表明在分子表面对电子量进行流形嵌入能够实现对包括DILI在内的分子性质的机器学习。

结论

该概念编码了控制分子间相互作用的分子量子信息，可能有助于深度学习模型的开发和训练。

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通过药物分子量子信息的流形嵌入实现药物性肝毒性的深度学习预测

Deep Learning Prediction of Drug-Induced Liver Toxicity by Manifold Embedding of Quantum Information of Drug Molecules.

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出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

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方法

结果

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