通过将隐式膜模型与机器学习相结合来预测药物分子的膜渗透性能。
Prediction of Membrane Permeation of Drug Molecules by Combining an Implicit Membrane Model with Machine Learning.
机构信息
Department of Biochemistry and Molecular Biology , Michigan State University , East Lansing , Michigan 48824 , United States.
Department of Pharmaceutical Sciences , University of Maryland, School of Pharmacy , Baltimore , Maryland 21201 , United States.
出版信息
J Chem Inf Model. 2019 Mar 25;59(3):1147-1162. doi: 10.1021/acs.jcim.8b00648. Epub 2018 Dec 27.
Abstract
Lipid membrane permeation of drug molecules was investigated with Heterogeneous Dielectric Generalized Born (HDGB)-based models using solubility-diffusion theory and machine learning. Free energy profiles were obtained for neutral molecules by the standard HDGB and Dynamic HDGB (DHDGB) to account for the membrane deformation upon insertion of drugs. We also obtained hybrid free energy profiles where the neutralization of charged molecules was taken into account upon membrane insertion. The evaluation of the predictions was done against experimental permeability coefficients from Parallel Artificial Membrane Permeability Assays (PAMPA), and effects of partial charge sets, CGenFF, AM1-BCC, and OPLS, on the performance of the predictions were discussed. (D)HDGB-based models improved the predictions over the two-state implicit membrane models, and partial charge sets seemed to have a strong impact on the predictions. Machine learning increased the accuracy of the predictions, although it could not outperform the physics-based approach in terms of correlations.
摘要
采用基于非均相介电广义 Born(HDGB)的模型,通过溶度扩散理论和机器学习研究了药物分子的脂膜渗透。通过标准 HDGB 和动态 HDGB(DHDGB)获得中性分子的自由能曲线,以解释药物插入时膜的变形。我们还获得了混合自由能曲线,其中考虑了带电荷分子在插入膜时的中和作用。通过平行人工膜渗透性测定法(PAMPA)的实验渗透系数对预测结果进行评估,并讨论了部分电荷集、CGenFF、AM1-BCC 和 OPLS 对预测性能的影响。基于(D)HDGB 的模型比两态隐式膜模型提高了预测精度,部分电荷集对预测似乎有很大影响。机器学习提高了预测的准确性,尽管在相关性方面,它无法超过基于物理的方法。
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