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Combinatorial Chemistry & High Throughput Screening

Editor-in-Chief

ISSN (Print): 1386-2073
ISSN (Online): 1875-5402

Virtual Darwinian Drug Design QSAR Inverse Problem, Virtual Combinatorial Chemistry, and Computational Screening.

Author(s): J. V. De Julian-Ortiz

Volume 4, Issue 3, 2001

Page: [295 - 310] Pages: 16

DOI: 10.2174/1386207013331129

Price: $65

Abstract

The generation of diversity and its further selection by an external system is a common mechanism for the evolution of the living species and for the current drug design methods. This assumption allows us to label the methods based on generation and selection of molecular diversity as Darwinian ones, and to distinguish them from the structure-based, structure-modulation approaches. An example of a Darwinian method is the inverse QSAR. It consists of the computational generation of candidate chemical structures and their selection according to a previously established QSAR model. New trends in the field of combinatorial chemical syntheses comprise the concepts of virtual combinatorial synthesis and virtual or computational screening. Virtual combinatorial synthesis, closely related to inverse QSAR, can be defined as the computational simulation of the generation of new chemical structures by using a combinatorial strategy to generate a virtual library. Virtual screening is the selection of chemical structures having potential desirable properties from a database or virtual library in order to be synthesized and assayed. This review is mainly focused on graph theoretical drug design approaches, but a survey with key references is provided that covers other simulation methods.

Keywords: Virtual Darwinian Drug Design, QSAR Inverse Problem, High Throughput Screening, Darwinian Drug Design, Electrotopological State, Platt index, Genetic mutation, naproxen and ranitidine, QSAR paradigm


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