Metabolism of a dopamine receptor partial agonist in rats, including an unusual N-dearylation reaction.

The metabolism of 3,4-dihydro-7-[4-(1-naphthalenyl)-1-piperazinyl]butoxy]-1,8-naphthyridin-2(1H)-one (NPBN) was investigated in rats. Animals were administered 30 mg/kg NPBN that was labeled with both tritium and carbon-14. The mass recovery of drug-related material was 96-98%, with almost all material excreted in feces. Metabolism occurred by oxidation reactions followed by conjugation. The main route of metabolism of NPBN occurred via oxidation of the naphthylene ring, which led to naphthol and dihydrodiol metabolites as well as a relatively novel N-dearylated metabolite in which the naphthylene ring was removed. In vitro investigation in rat liver microsomes also showed a glutathione adduct on the naphthalene and a glutathione adduct of naphthoquinone, which, along with the dihydrodiol metabolite, is consistent with the initial generation of an epoxide. A mechanism is proposed whereby the N-dearylation arises via epoxidation, followed by formation of an exocyclic iminium ion intermediate that is hydrolyzed to yield the N-dearylated metabolite. An additional mechanism involves oxidation of the naphthol metabolite via a radical mechanism, since this metabolite was also shown to undergo N-dearylation.

Assessment of a micropatterned hepatocyte coculture system to generate major human excretory and circulating drug metabolites.

Metabolism is one of the important determinants of the overall disposition of drugs, and the profile of metabolites can have an impact on efficacy and safety. Predicting which drug metabolites will be quantitatively predominant in humans has become increasingly important in the research and development of new drugs. In this study, a novel micropatterned hepatocyte coculture system was evaluated for its ability to generate human in vivo metabolites. Twenty-seven compounds of diverse chemical structure and subject to a range of drug biotransformation reactions were assessed for metabolite profiles in the micropatterned coculture system using pooled cryopreserved human hepatocytes. The ability of this system to generate metabolites that are >10% of dose in excreta or >10% of total drug-related material in circulation was assessed and compared to previously reported data obtained in human hepatocyte suspensions, liver S-9 fraction, and liver microsomes. The micropatterned coculture system was incubated for up to 7 days without a change in medium, which offered an ability to generate metabolites for slowly metabolized compounds. The micropatterned coculture system generated 82% of the excretory metabolites that exceed 10% of dose and 75% of the circulating metabolites that exceed 10% of total circulating drug-related material, exceeds the performance of hepatocyte suspension incubations and other in vitro systems. Phase 1 and phase 2 metabolites were generated, as well as metabolites that arise via two or more sequential reactions. These results suggest that this in vitro system offers the highest performance among in vitro metabolism systems to predict major human in vivo metabolites.