Quantitative structure-metabolism relationships for substituted benzoic acids in the rabbit: prediction of urinary excretion of glycine and glucuronide conjugates.

1. Quantitative relationships between molecular physicochemical properties of 24 substituted benzoic acids and their metabolic fate in the rabbit have been investigated using computational chemistry and multivariate statistical methods. 2. A total of 34 molecular properties were calculated for each compound using computational chemistry and were related statistically to the % molar recovery of glycine and glucuronide conjugates excreted in the urine of rabbits for the 24 compounds. 3. Compounds were successfully classified according to their dominant metabolic fate based on urinary excretion data, where stepwise linear regression analysis of the theoretical property data achieved good predictive fits for observed versus predicted % molar urinary recovery as glucuronide conjugates (r2 = 0.79) and % molar urinary recovery as glycine conjugates (r2 = 0.66). 4. Quantitative prediction of the urinary excretion of glucuronide and glycine conjugates of the parent compounds was achieved based on a statistical model using calculated molecular physicochemical parameters. Interpretation of the molecular properties, which are important for predicting the metabolic class, should give new insights into basic mechanisms of drug metabolism and underlying molecular recognition events that determine disposition and metabolism.

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