1098-2299/asset/DDR_centre.gif?v=1&s=0de46fc8e2686c185b44eedd0a5a3895cd6d9afe)
Research Overview
Developing technologies in biodefense research: computational drug design
Article first published online: 12 JUN 2009
DOI: 10.1002/ddr.20305
© 2009 Wiley-Liss, Inc.
Issue
1098-2299/asset/cover.gif?v=1&s=c8b6d95b3bde54896854147d5045c8f3690d6eff "Drug Development Research")
Drug Development Research
Special Issue: Biodefense Countermeasure Development
Volume 70, Issue 4, pages 279–287, June 2009
Additional Information
How to Cite
Clark, M., Meshkat, S., Talbot, G., Konteatis, Z., Ludington, J., Zou, J., Freedman, S. J. and Wiseman, J. S. (2009), Developing technologies in biodefense research: computational drug design. Drug Development Research, 70: 279–287. doi: 10.1002/ddr.20305
Publication History
- Issue published online: 12 JUN 2009
- Article first published online: 12 JUN 2009
- Abstract
- References
- Cited By
Keywords:
- computation;
- drug-design;
- free-energy
Abstract
The development of small-molecule drugs to counter the threat of bioterrorism will differ from classical drug discovery because it will be impossible to evaluate efficacy in clinical trials for many agents. This difference focuses biodefense on the identification of multiple drug candidates for each threat organism so that multiple treatments can be mounted simultaneously when needed to maximize the probability of success. Accordingly, drug discovery will become the rate- and cost-limiting phase of the overall drug development process. We address the potential of computational chemistry to optimize efficiency and efficacy in the discovery phase. The major elements required for a successful computational approach are the calculation of binding free energy, accounting for changes in solvation on ligand binding, and compensating for protein flexibility. Drug Dev Res 70:279–287, 2009. © 2009 Wiley-Liss, Inc.