Zhu Zailiang, Dou Bozheng, Cao Yukang, Jiang Jian, Zhu Yueying, Chen Dong, Feng Hongsong, Liu Jie, Zhang Bengong, Zhou Tianshou, Wei Guo-Wei
School of Computer Science and Artificial Intelligence, Wuhan Textile University, Wuhan, 430200, P R. China.
Research Center of Nonlinear Science, School of Mathematical and Physical Sciences, Wuhan Textile University, Wuhan, 430200, P R. China.
J Chem Inf Model. 2023 Mar 13;63(5):1472-1489. doi: 10.1021/acs.jcim.3c00046. Epub 2023 Feb 24.
Drug addiction is a global public health crisis, and the design of antiaddiction drugs remains a major challenge due to intricate mechanisms. Since experimental drug screening and optimization are too time-consuming and expensive, there is urgent need to develop innovative artificial intelligence (AI) methods for addressing the challenge. We tackle this challenge by topology-inferred drug addiction learning (TIDAL) built from integrating multiscale topological Laplacians, deep bidirectional transformer, and ensemble-assisted neural networks (EANNs). Multiscale topological Laplacians are a novel class of algebraic topology tools that embed molecular topological invariants and algebraic invariants into its harmonic spectra and nonharmonic spectra, respectively. These invariants complement sequence information extracted from a bidirectional transformer. We validate the proposed TIDAL framework on 22 drug addiction related, 4 hERG, and 12 DAT data sets, which suggests that the proposed TIDAL is a state-of-the-art framework for the modeling and analysis of drug addiction data. We carry out cross-target analysis of the current drug addiction candidates to alert their side effects and identify their repurposing potentials. Our analysis reveals drug-mediated linear and bilinear target correlations. Finally, TIDAL is applied to shed light on relative efficacy, repurposing potential, and potential side effects of 12 existing antiaddiction medications. Our results suggest that TIDAL provides a new computational strategy for pressingly needed antisubstance addiction drug development.
药物成瘾是一场全球公共卫生危机,由于机制复杂,抗成瘾药物的设计仍然是一项重大挑战。由于实验性药物筛选和优化耗时且昂贵,迫切需要开发创新的人工智能(AI)方法来应对这一挑战。我们通过整合多尺度拓扑拉普拉斯算子、深度双向变换器和集成辅助神经网络(EANN)构建的拓扑推断药物成瘾学习(TIDAL)来应对这一挑战。多尺度拓扑拉普拉斯算子是一类新型代数拓扑工具,分别将分子拓扑不变量和代数不变量嵌入其谐波谱和非谐波谱中。这些不变量补充了从双向变换器提取的序列信息。我们在22个与药物成瘾相关的数据集、4个hERG数据集和12个DAT数据集上验证了所提出的TIDAL框架,这表明所提出的TIDAL是用于药物成瘾数据建模和分析的最先进框架。我们对当前的药物成瘾候选药物进行交叉靶点分析,以提醒其副作用并确定其重新利用的潜力。我们的分析揭示了药物介导的线性和双线性靶点相关性。最后,应用TIDAL来阐明12种现有抗成瘾药物的相对疗效、重新利用潜力和潜在副作用。我们的结果表明,TIDAL为迫切需要的抗物质成瘾药物开发提供了一种新的计算策略。
