Abstract
Hundreds of millions of U.S. dollars are invested in the research and development of a single drug. Lead compound development is an area ripe for new design strategies. Therapeutic lead candidates have been traditionally found using high-throughput in vitro pharmacological screening, a costly method for assaying thousands of compounds. This approach has recently been augmented by virtual screening (VS), which employs computer models of the target protein to narrow the search for possible leads. A variant of VS is fragment-based drug design (FBDD), an emerging in silico lead discovery method that introduces low-molecular weight fragments, rather than intact compounds, into the binding pocket of the receptor model. These fragments serve as starting points for “growing” the lead candidate. Current efforts in virtual FBDD within central nervous system (CNS) targets are reviewed, as is a recent rule-based optimization strategy in which new molecules are generated within a 3D receptor-binding pocket using the fragment as a scaffold. This process not only places special emphasis on creating synthesizable molecules but also exposes computational questions worth addressing. Fragment-based methods provide a viable, relatively low-cost alternative for therapeutic lead discovery and optimization that can be applied to CNS targets to augment current design strategies.
Highlights
The cost of developing and bringing a single successful drug to market approaches one billion dollars, and the process requires on average 12 years to accomplish
Among the reviews and discussion on structure- and knowledge-based Central nervous system (CNS) drug design [4, 6,7,8,9], recent fragment-based drug design (FBDD) literature focusing on CNS targets is underrepresented
R&D has become a target of cutbacks and a victim to outsourcing
Summary
The cost of developing and bringing a single successful drug to market approaches one billion dollars, and the process requires on average 12 years to accomplish. The preclinical evaluation process is estimated to be 32% of the total cost of drug design [2]. Central nervous system (CNS) disorders are logical foci for such new strategies; the increasingly geriatric population is more susceptible to Alzheimer’s disease, Parkinson’s disease, and ischemic stroke [4]. Mental health disorders such as depression are effectively treated with existing therapeutics only a fraction of the time; much of the population is unresponsive or plagued with adverse drug effects [5]. Application of FBDD to CNS targets should provide a new spark for drug design in this area
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