阿托品
分子
力场(虚构)
化学
立体中心
领域(数学)
集合(抽象数据类型)
工作流程
密度泛函理论
基础(线性代数)
马克西玛
能量(信号处理)
势能面
功能(生物学)
最大值和最小值
计算化学
势能
国家(计算机科学)
试验装置
转动能
统计物理学
静止点
有机分子
人工神经网络
点(几何)
生物系统
旋转(数学)
工作(物理)
小分子
人工智能
算法
数据集
计算机科学
基准集
化学物理
过渡状态
能量最小化
物理
构象异构
氢键
作者
Ty Balduf,Philip A. Gerken,Mee Shelley,Mark A. Watson,M. Chandler Bennett,Mats Svensson,Abba E. Leffler,Art Bochevarov
标识
DOI:10.1021/acs.jcim.5c02720
摘要
A multistep computational workflow that accurately assigns organic drug-like molecules to one of three atropisomer classes on the basis of computed barrier heights has been developed. The workflow identifies rotatable bonds and applies progressively more accurate types of calculations to the eligible rotational degrees of freedom. An initial energy scan with a force field (OPLS4) is followed by a similar scan that uses an energy function driven by a neural network model (QRNN-TB) trained on density functional theory (DFT) energies. The maxima corresponding to the potentially stereogenic rotatable bonds identified at this point are further processed by applying a transition state search at the QRNN-TB level of theory. Finally, ωB97X-D3/def2-TZVP(-f) DFT energies are computed for all located extrema. The accuracy of the predicted rotational barriers was benchmarked against ωB97M-V/cc-pVTZ and DLPNO-CCSD(T)/def2-TZVPP energies with excellent correlations. The automated protocol classifies organic molecules into atropisomeric classes with a greater than 90% success rate when applied to a test set of 65 molecules containing rotationally restricted torsions (68 torsions in total). We anticipate that the balance of speed and accuracy in this method will make it conducive to production use in drug discovery programs.
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