Hong Richard S, Rojas Ana V, Bhardwaj Rajni Miglani, Wang Lingle, Mattei Alessandra, Abraham Nathan S, Cusack Kevin P, Pierce M Olivia, Mondal Sayan, Mehio Nada, Bordawekar Shailendra, Kym Philip R, Abel Robert, Sheikh Ahmad Y
AbbVie Inc., Research & Development, 1 N Waukegan Road, North Chicago, Illinois 60064, United States.
Schrödinger Inc., 1540 Broadway 24th Floor, New York, New York 10036, United States.
J Med Chem. 2023 Dec 14;66(23):15883-15893. doi: 10.1021/acs.jmedchem.3c01339. Epub 2023 Nov 28.
Early assessment of crystalline thermodynamic solubility continues to be elusive for drug discovery and development despite its critical importance, especially for the ever-increasing fraction of poorly soluble drug candidates. Here we present a detailed evaluation of a physics-based free energy perturbation (FEP+) approach for computing the thermodynamic aqueous solubility. The predictive power of this approach is assessed across diverse chemical spaces, spanning pharmaceutically relevant literature compounds and more complex AbbVie compounds. Our approach achieves predictive (RMSE = 0.86) and differentiating power ( = 0.69) and therefore provides notably improved correlations to experimental solubility compared to state-of-the-art machine learning approaches that utilize quantum mechanics-based descriptors. The importance of explicit considerations of crystalline packing in predicting solubility by the FEP+ approach is also highlighted in this study. Finally, we show how computed energetics, including hydration and sublimation free energies, can provide further insights into molecule design to feed the medicinal chemistry DMTA cycle.
尽管晶体热力学溶解度的早期评估对于药物发现和开发至关重要,尤其是对于日益增多的难溶性候选药物而言,但它仍然难以实现。在此,我们详细评估了一种基于物理的自由能微扰(FEP+)方法来计算热力学水溶解度。该方法的预测能力在不同的化学空间中进行了评估,涵盖了药学相关的文献化合物以及更复杂的艾伯维化合物。我们的方法实现了预测能力(均方根误差=0.86)和区分能力(=0.69),因此与利用基于量子力学描述符的现有机器学习方法相比,与实验溶解度的相关性显著提高。本研究还强调了在通过FEP+方法预测溶解度时明确考虑晶体堆积的重要性。最后,我们展示了计算得到的能量学,包括水合和升华自由能,如何能够为分子设计提供进一步的见解,以推动药物化学的设计-制造-测试-分析(DMTA)循环。
