原子描述符设计的艺术

Q1 Pharmacology, Toxicology and Pharmaceutics
Andreas H. Göller
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引用次数: 4

摘要

本文综述了原子描述在理解化学反应性和选择性、pKa值、代谢位点预测或氢键强度等现象中的应用,以及用机器学习模型代替量子力学计算的能量、力甚至光谱性质,最后是用于力场参数化的原子电荷的快速计算。描述符空间的范围从波函数或电子密度的导数通过量子力学衍生的描述符到原子及其在分子中的嵌入的经典描述。所有方法的共同点是对指导原子描述符设计的化学问题的物理学的透彻理解。量子力学(QM)和机器学习(ML)最终融合为一个新的学科,即QM/ML。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The art of atom descriptor design

This review provides an overview of descriptions of atoms applied to the understanding of phenomena like chemical reactivity and selectivity, pKa values, Site of Metabolism prediction, or hydrogen bond strengths, but also the substitution of quantum mechanical calculations by machine learning models for energies, forces or even spectrosocopic properties and finally the fast calculation of atomic charges for force field parametrization. The descriptor space ranges from derivatives of the wavefunctions or electron density via quantum mechanics derived descriptors to classical descriptions of atoms and their embedding in a molecule. The common denominator for all approaches is the thorough understanding of the physics of the chemical problem that guided the design of the atom descriptor. Quantum mechanics (QM) and machine learning (ML) finally are converging to a new discipline, namely QM/ML.

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来源期刊
Drug Discovery Today: Technologies
Drug Discovery Today: Technologies Pharmacology, Toxicology and Pharmaceutics-Drug Discovery
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期刊介绍: Discovery Today: Technologies compares different technological tools and techniques used from the discovery of new drug targets through to the launch of new medicines.
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