通过分子特性、体外 ADME 和安全性特征的一致性来定义理想的中枢神经系统药物空间。
Defining desirable central nervous system drug space through the alignment of molecular properties, in vitro ADME, and safety attributes.
机构信息
558 Eastern Point Road, Groton, CT, USA.
出版信息
ACS Chem Neurosci. 2010 Jun 16;1(6):420-34. doi: 10.1021/cn100007x. Epub 2010 Mar 25.
Abstract
As part of our effort to increase survival of drug candidates and to move our medicinal chemistry design to higher probability space for success in the Neuroscience therapeutic area, we embarked on a detailed study of the property space for a collection of central nervous system (CNS) molecules. We carried out a thorough analysis of properties for 119 marketed CNS drugs and a set of 108 Pfizer CNS candidates. In particular, we focused on understanding the relationships between physicochemical properties, in vitro ADME (absorption, distribution, metabolism, and elimination) attributes, primary pharmacology binding efficiencies, and in vitro safety data for these two sets of compounds. This scholarship provides guidance for the design of CNS molecules in a property space with increased probability of success and may lead to the identification of druglike candidates with favorable safety profiles that can successfully test hypotheses in the clinic.
摘要
作为提高候选药物存活率并将我们的药物化学设计转移到神经科学治疗领域更高成功概率空间的努力的一部分,我们着手对一系列中枢神经系统 (CNS) 分子的性质空间进行详细研究。我们对 119 种上市 CNS 药物和 108 种辉瑞 CNS 候选药物进行了全面的性质分析。特别是,我们专注于理解这两组化合物的物理化学性质、体外 ADME(吸收、分布、代谢和消除)特性、主要药理学结合效率以及体外安全性数据之间的关系。这项奖学金为在具有更高成功概率的性质空间中设计 CNS 分子提供了指导,并可能导致鉴定出具有良好安全性特征的类药性候选药物,这些候选药物可以成功地在临床中验证假设。
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