Active metabolites resulting from decarboxylation, reduction and ester hydrolysis of parent drugs.

Decarboxylation, reduction and hydrolysis can yield active metabolites from the parent drug. Major therapeutic indications and metabolic routes of these drugs are reviewed. Changes in the logP values (determined and calculated) from the parent drug to the active metabolite show certain characteristics in comparison to other phase I metabolic alterations. Metabolic decarboxylation of parent drug is commonly associated with increase in lipophilicity. However, in some cases, decarboxylation may cause a reduction in lipophilicity. Ester hydrolysis generally unmasks either the polar carboxylic or hydroxyl group with the outcome of an increase in hydrophilicity. On the contrary, hydrolysis of phosphate ester means a huge increase in the lipophilic character of the drug, as the highly polar phosphate group is removed.

Medicinal chemistry of antiviral/anticancer prodrugs subjected to phosphate conjugation.

Certain xenobiotics are given in the "prodrug" form. Either the human body, or one compartment of the body, or the targeted virus itself metabolizes the prodrug into its active form. The bioprecursor form of drugs is used for a wide variety of reasons, namely: to make drug penetration into the target organ (mainly to the brain through the blood-brain-barrier) possible, eliminate unpleasant taste, alter (either increasing or decreasing) the half life of the active component or supply more than one active components to the body.

Metabolism of moexipril to moexiprilat: determination of in vitro metabolism using HPLC-ES-MS.

Moexipril is a long-acting, non-sulfhydryl angiotensine-converting enzyme inhibitor. It is used for treatment of arterial hypertension. Moexipril is the prodrug, yielding moexiprilat by hydrolysis of an ethyl ester group. Moexiprilat is the metabolite responsible for the pharmacological effect after moexipril administration. Samples of rat and human microsomal preparations exposed to moexipril treatment were analyzed by HPLC using octyl silica stationary phase and isocratic elution. To detect moexipril and moexiprilat the separation was monitored by both ultraviolet and mass specific detection. The rat liver microsomal preparation was more effective to in producing moexiprilat than the similar one derived from human liver cell lines. While additional potential metabolites of moexipril were suggested by computer-modeling, moexiprilat was the sole metabolite detected after microsomal treatment.