Medicinal chemistry

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Revision as of 08:21, 31 August 2008

Medicinal chemistry is at the forefront of innovation, blending synthetic chemistry, molecular modeling, computational biology, structural genomics, and pharmacology to discover and design new drugs, and investigate their interaction at the molecular, cellular, and whole-animal level.

Modern genomics and proteomics have elevated the sophistication of discovering new therapeutic targets. This data-intensive research is feeding the fast-paced fields of bioinformatics and pharmacogenomics, as they become integral components of medicinal chemistry. Medicinal or pharmaceutical chemistry is a scientific discipline at the intersection of chemistry and pharmacology involved with designing, synthesizing and developing pharmaceutical drugs. Medicinal chemistry involves the identification, synthesis and development of new chemical entities suitable for therapeutic use. It also includes the study of existing drugs, their biological properties, and their quantitative structure-activity relationships (QSAR). Pharmaceutical chemistry is focused on quality aspects of medicines and aims to assure fitness for the purpose of medicinal products. Compounds used as medicines are overwhelmingly organic products. However, metal-containing compounds have been found to be useful as drugs. For example, the cis-platin series of platinium-containing complexes have found use as anti-cancer agents. This type of compounds are known as metal-based drugs.

Medicinal chemistry is a highly interdisciplinary science combining organic chemistry with biochemistry, computational chemistry, pharmacology, pharmacognosy, molecular biology, statistics, and physical chemistry

Contents

Process of drug discovery

Discovery

The first step of drug discovery involves the identification of new active compounds, often called "hits", which are typically found by screening many compounds for the desired biological properties. These hits can come from natural sources, such as plants, animals, or fungi. More often, the hits can come from synthetic sources, such as historical compound collections and combinatorial chemistry.


Optimization

The second step of drug discovery involves the synthetic modification of the hits in order to improve the biological properties of the compound pharmacophore. The quantitative structure-activity relationship (QSAR) of the pharmacophore play an important part in finding lead compounds, which exhibit the most potency, most selectivity, best pharmacokinetics and least toxicity. QSAR involves mainly physical chemistry and molecular docking tools (CoMFA and CoMSIA), that leads to tabulated data and first and second order equations. There are many theories, being the most relevant Hansch's analysis that involves Hammett electronic parameters, stearic parameters and logP(lipophilicity) parameters.

Development

The final step involves the rendering the lead compounds suitable for use in clinical trials. This involves the optimization of the Chemical synthesis|synthetic route for bulk production, and the preparation of a suitable drug formulation.

Training in medicinal chemistry

Many workers in the field do not have formal training in medicinal chemistry. Graduate (postgraduate) level programs do exist in medicinal chemistry, but frequently the broader education in a chemistry graduate program can provide many of the skills needed.

See also