Jeffrey R Deschamps1. 1. Naval Research Laboratory, Code 6030, 4555 Overlook Ave., Washington, DC 20375, United States. deschamps@nrl.navy.mil
Abstract
AIMS: Accurate knowledge of molecular structure is a prerequisite for rational drug design. This review examines the role of X-ray crystallography in providing the required structural information and advances in the field of X-ray crystallography that enhance or expand its role. MAIN METHODS: X-ray crystallography of new drugs candidates and intermediates can provide valuable information of new syntheses and parameters for quantitative structure activity relationships (QSAR). KEY FINDINGS: Crystallographic studies play a vital role in many disciplines including materials science, chemistry, pharmacology, and molecular biology. X-ray crystallography is the most comprehensive technique available to determine molecular structure. A requirement for the high accuracy of crystallographic structures is that a 'good crystal' must be found, and this is often the rate-limiting step. In the past three decades developments in detectors, increases in computer power, and powerful graphics capabilities have contributed to a dramatic increase in the number of materials characterized by X-ray crystallography. More recently the advent of high-throughput crystallization techniques has enhanced our ability to produce that one good crystal required for crystallographic analysis. SIGNIFICANCE: Continuing advances in all phases of a crystallographic study have expanded the ranges of samples which can be analyzes by X-ray crystallography to include larger molecules, smaller or weakly diffracting crystals, and twinned crystals. Published by Elsevier Inc.
AIMS: Accurate knowledge of molecular structure is a prerequisite for rational drug design. This review examines the role of X-ray crystallography in providing the required structural information and advances in the field of X-ray crystallography that enhance or expand its role. MAIN METHODS: X-ray crystallography of new drugs candidates and intermediates can provide valuable information of new syntheses and parameters for quantitative structure activity relationships (QSAR). KEY FINDINGS: Crystallographic studies play a vital role in many disciplines including materials science, chemistry, pharmacology, and molecular biology. X-ray crystallography is the most comprehensive technique available to determine molecular structure. A requirement for the high accuracy of crystallographic structures is that a 'good crystal' must be found, and this is often the rate-limiting step. In the past three decades developments in detectors, increases in computer power, and powerful graphics capabilities have contributed to a dramatic increase in the number of materials characterized by X-ray crystallography. More recently the advent of high-throughput crystallization techniques has enhanced our ability to produce that one good crystal required for crystallographic analysis. SIGNIFICANCE: Continuing advances in all phases of a crystallographic study have expanded the ranges of samples which can be analyzes by X-ray crystallography to include larger molecules, smaller or weakly diffracting crystals, and twinned crystals. Published by Elsevier Inc.
Authors: Joseph R Luft; Robert J Collins; Nancy A Fehrman; Angela M Lauricella; Christina K Veatch; George T DeTitta Journal: J Struct Biol Date: 2003-04 Impact factor: 2.867
Authors: Christian A Cumbaa; Angela Lauricella; Nancy Fehrman; Christina Veatch; Robert Collins; Joe Luft; George DeTitta; Igor Jurisica Journal: Acta Crystallogr D Biol Crystallogr Date: 2003-08-19
Authors: Sonja L Knowles; Christopher D Roberts; Mario Augustinović; Laura Flores-Bocanegra; Huzefa A Raja; Kimberly N Heath-Borrero; Joanna E Burdette; Joseph O Falkinham Iii; Cedric J Pearce; Nicholas H Oberlies Journal: J Nat Prod Date: 2021-03-25 Impact factor: 4.050