Innovative strategies for the quantitative modeling of blood–brain barrier (BBB) permeability: harnessing the power of machine learning-based q-RASAR approach†

IF 3.2 3区 工程技术 Q2 CHEMISTRY, PHYSICAL
Vinay Kumar, Arkaprava Banerjee and Kunal Roy
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Abstract

In the current research, we have unveiled an advanced technique termed the quantitative read-across structure–activity relationship (q-RASAR) framework to harness the power of machine learning (ML) for significantly enhancing the precision of predictions related to blood–brain barrier (BBB) permeability. It is important to emphasize that the central objective of this study is not to introduce an additional model for predicting BBB permeability. Instead, our focus is on highlighting the improvement in quantitatively predicting the BBB permeability of organic compounds by utilizing the q-RASAR approach. This innovative methodology strives to enhance the precision of evaluating neuropharmacological implications and streamline the drug development process. In this investigation, we developed a machine learning (ML)-based q-RASAR PLS regression model using a large dataset comprising 1012 diverse classes of heterocyclic and aromatic compounds, obtained from the freely accessible B3DB database (accessible at https://github.com/theochem/B3DB) to predict BBB permeability during the lead discovery phase for central nervous system (CNS) drugs. The model's predictive capability underwent validation using two external sets, encompassing a total of 1 130 315 compounds, including synthetic compounds and natural products (NPs) for data gap filling and other two external sets comprising 116 drug-like/drug compounds from the FDA and ChEMBL databases to assess the model's reliability against the reported BBB permeability values. This study aimed to bridge the data gap by employing a predictive regression model to estimate the BBB permeability for both synthetic compounds and natural products (NPs). To further enhance predictability, we have developed various other ML-based q-RASAR models. The insights from the developed model highlight the pivotal roles played by hydrophobicity, electronic effects, degree of ionization, and steric factors as essential features facilitating the traversal of the blood–brain barrier. This research not only advances our understanding of the molecular determinants influencing the permeability of central nervous system drugs but also establishes a versatile computational platform for the rapid assessment of diverse compounds, facilitating informed decision-making in the realms of drug development and design.

Abstract Image

Abstract Image

血脑屏障(BBB)渗透性定量建模的创新策略:利用基于机器学习的 q-RASAR 方法的力量
在目前的研究中,我们推出了一种被称为定量交叉结构-活性关系(q-RASAR)框架的先进技术,以利用机器学习(ML)的力量显著提高与血脑屏障(BBB)通透性有关的预测精度。需要强调的是,本研究的核心目标并不是引入一个额外的模型来预测血脑屏障的通透性。相反,我们的重点是强调利用 q-RASAR 方法在定量预测有机化合物的 BBB 渗透性方面的改进。这种创新方法致力于提高神经药理学影响评估的精确度,并简化药物开发流程。在这项研究中,我们开发了一个基于机器学习(ML)的q-RASAR PLS回归模型,该模型使用了一个大型数据集,其中包括1012种不同类别的杂环化合物和芳香化合物,这些数据集来自可免费访问的B3DB数据库(可在https://github.com/theochem/B3DB),用于预测中枢神经系统(CNS)药物先导发现阶段的BBB渗透性。该模型的预测能力通过两组外部数据进行了验证,其中一组包括合成化合物和天然产物(NPs),共计 1 130 315 个化合物,用于填补数据缺口;另外两组外部数据包括来自 FDA 和 ChEMBL 数据库的 116 个类药物/药物化合物,用于评估该模型与所报告的 BBB 渗透性值之间的可靠性。本研究旨在采用预测回归模型来估算合成化合物和天然产物(NPs)的生物BB渗透性,从而弥补数据缺口。为了进一步提高预测能力,我们还开发了其他各种基于 ML 的 q-RASAR 模型。从所开发的模型中得到的启示强调了疏水性、电子效应、电离程度和立体因素在促进穿越血脑屏障的基本特征中所起的关键作用。这项研究不仅加深了我们对影响中枢神经系统药物渗透性的分子决定因素的理解,还为快速评估各种化合物建立了一个多功能计算平台,有助于在药物开发和设计领域做出明智的决策。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Molecular Systems Design & Engineering
Molecular Systems Design & Engineering Engineering-Biomedical Engineering
CiteScore
6.40
自引率
2.80%
发文量
144
期刊介绍: Molecular Systems Design & Engineering provides a hub for cutting-edge research into how understanding of molecular properties, behaviour and interactions can be used to design and assemble better materials, systems, and processes to achieve specific functions. These may have applications of technological significance and help address global challenges.
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