New metabolic pathways of alpha-lipoic acid.

The excretion and biotransformation of rac-alpha-lipoic acid (LA), which is used for the symptomatic treatment of diabetic polyneuropathy, were investigated following single oral dosing of [(14)C]LA to mice (30 mg/kg), rats (30 mg/kg), dogs (10 mg/kg), and unlabeled LA to humans (600 mg). More than 80% of the radioactivity given was renally excreted. Metabolite profiles obtained by radiometric high-performance liquid chromatography revealed that LA was extensively metabolized irrespective of the species. Based on a new on-line liquid chromatography/tandem mass spectroscopy assay developed for negative ions, LA and a total of 12 metabolites were identified. Mitochondrial beta-oxidation played the paramount role in the metabolism of LA. Simultaneously, the circulating metabolites were subjected to reduction of the 1,2-dithiolane ring and subsequent S-methylation. In addition, evidence is given for the first time that the methyl sulfides formed were partly oxidized to give sulfoxides, predominantly in dogs. The disulfoxide of 2,4-bismethylmercapto-butanoic acid, the most polar metabolite identified, was the major metabolite in dogs. Furthermore, new data are presented that suggest conjugation with glycine occurred as a separate metabolic pathway in competition with beta-oxidation, predominantly in mice.

Disposition and metabolism of cetrorelix, a potent luteinizing hormone-releasing hormone antagonist, in rats and dogs.

Disposition and metabolism of cetrorelix was studied in intact and bile duct-cannulated rats and dogs after s.c. injection. An s.c. dose of 0.1 mg/kg [(14)C]cetrorelix was rapidly and completely absorbed in rats. T(max) in plasma and most tissues was at 2 h. Radioactivity at the injection site in rats declined to 10% by 24 h. The extent of (14)C absorption in rats calculated from excretion until 264 h was 94%. Exposure of the target organ pituitary gland was demonstrated with a time course similar to plasma but on a higher level. Rats excreted 69.6% of radioactivity via feces and 24. 3% into urine. Excretion was nearly complete within 48 h. No enteral reabsorption was detected. In dogs t(max) in plasma was 1.3 h. (14)C- and cetrorelix-plasma levels were similar until 24 h, indicating a negligible amount of metabolites. A dose of 1 mg/kg in dogs showed an increasing influence of a slow absorption phase (flip-flop). In dogs equal amounts of the (14)C dose were found within 192 h in feces and urine, 46 and 48%, respectively. In urine of both species, only intact cetrorelix was detected. In bile and feces of both species qualitatively the same metabolites were found, characterized as truncated peptides of the parent decapeptide. The major metabolite occurring in bile of both species was the (1-7)heptapeptide. The amounts of the (1-4)tetrapeptide in feces of rats but not in that of dogs increase with time, suggesting additional degradation of the peptide in the gastrointestinal tract of rats by enteric metabolization.

Metabolism of retigabine (D-23129), a novel anticonvulsant.

Retigabine (D-23129, N-(2-amino-4-(4-fluorobenzylamino)-phenyl) carbamic acid ethyl ester) is a potent anticonvulsant in a variety of animal models. Rats metabolized [14C]retigabine mainly through glucuronidation and acetylation reactions. Glucuronides were detected in incubates with liver microsomes or slices, in plasma, and in bile and feces but were absent in urine (0-24 h) that contained about 2% of the dose as retigabine and approximately 29% of the dose in > 20 metabolites, which are derived mainly from acetylation reactions. About 67% of the radioactivity was excreted into feces, approximately 10% of the dose as glucuronide. The metabolite pattern in the urine (0-24 h) of dogs was comparatively simple in that retigabine (13%), retigabine-N-glucuronide (5%), and retigabine-N-glucoside (1%) were present. In the same 24-h interval, about 39% of unchanged retigabine was excreted into feces. Plasma profiling and spectroscopic analysis (liquid chromatography with tandem mass spectrometry NMR) of two isolated urinary metabolites obtained after single oral dosing of 600 mg retigabine in healthy volunteers indicated that both acetylation and glucuronidation are major metabolic pathways of retigabine in humans. We found that in vitro assays with liver slices from rat and humans reveal the major circulating metabolites in vivo.

Identification of talinolol metabolites in urine of man, dog, rat and mouse after oral administration by high-performance liquid chromatography-thermospray tandem mass spectrometry.

A new specific HPLC-TSP-MS/MS assay for identification of beta-blocking drug talinolol and its metabolites in urinary samples of man, dog, rat and mouse after single oral administration has been developed. Centrifuged urines were directly injected into the HPLC-TSP-MS system. Based on thermospray MS/MS studies of 10 reference compounds, several selective CID-MS/MS reactions were found, which were typical of substructure elements of potential phase I metabolites. In this way the differentiation of various stereochemical positions of the hydroxyl group in the cyclohexyl ring moiety of metabolites was possible. Renal metabolic profiles for all investigated species were generated by HPLC-multiple reaction monitoring (MRM). The detected metabolites were characterized by TSP full scan and MS/MS analysis in relation to synthesized reference compounds. The major metabolic pathway in all species results in the hydroxylation of the cyclohexylring moiety of talinolol. In dog urine, a phase II metabolite, the O-glucuronide of talinolol (I) was found. In order to identify this structure, the use of electrospray ionization was also necessary.