Your search keyword '"Robert S. Jansen"' showing total 2 results

1. Metabolite Profiling of Bendamustine in Urine of Cancer Patients after Administration of [14C]Bendamustine

Author

Mona Darwish, A. C. Dubbelman, Jos H. Beijnen, Philmore Robertson, Hilde Rosing, Jan H.M. Schellens, Robert S. Jansen, and Edward T. Hellriegel

Subjects

Bendamustine, Benzimidazole, Metabolite, Pharmaceutical Science, Urine, Hydroxylation, Phosphates, Butyric acid, chemistry.chemical_compound, Neoplasms, medicine, Bendamustine Hydrochloride, Humans, Carbon Radioisotopes, Cysteine, Mercapturic acid, Antineoplastic Agents, Alkylating, Pharmacology, Chromatography, Hydrolysis, Uric Acid, chemistry, Biochemistry, Dealkylation, Creatinine, Nitrogen Mustard Compounds, Metabolome, Uric acid, Oxidation-Reduction, Metabolic Networks and Pathways, medicine.drug

Abstract

Bendamustine is an alkylating agent consisting of a mechlorethamine derivative, a benzimidazole group, and a butyric acid substituent. A human mass balance study showed that bendamustine is extensively metabolized and subsequently excreted in urine. However, limited information is available on the metabolite profile of bendamustine in human urine. The objective of this study was to elucidate the metabolic pathways of bendamustine in humans by identification of its metabolites excreted in urine. Human urine samples were collected up to 168 h after an intravenous infusion of 120 mg/m(2) (80-95 μCi) [(14)C]bendamustine. Metabolites of [(14)C]bendamustine were identified using liquid chromatography (high-resolution)-tandem mass spectrometry with off-line radioactivity detection. Bendamustine and a total of 25 bendamustine-related compounds were detected. Observed metabolic conversions at the benzimidazole and butyric acid moiety were N-demethylation and γ-hydroxylation. In addition, various other combinations of these conversions with modifications at the mechlorethamine moiety were observed, including hydrolysis (the primary metabolic pathway), cysteine conjugation, and subsequent biotransformation to mercapturic acid and thiol derivatives, N-dealkylation, oxidation, and conjugation with phosphate, creatinine, and uric acid. Bendamustine-derived products containing phosphate, creatinine, and uric acid conjugates were also detected in control urine incubated with bendamustine. Metabolites that were excreted up to 168 h after the infusion included products of dihydrolysis and cysteine conjugation of bendamustine and γ-hydroxybendamustine. The range of metabolic reactions is generally consistent with those reported for rat urine and bile, suggesting that the overall processes involved in metabolic elimination are qualitatively the same in rats and humans.

Published

2012

2. Mass Balance Study of [14C]Eribulin in Patients with Advanced Solid Tumors

Author

Marja Mergui-Roelvink, Margarita Lymboura, Arturo Lopez-Anaya, A. C. Dubbelman, Jan H.M. Schellens, Alwin D. R. Huitema, Jos H. Beijnen, Larisa Reyderman, Barbara Koetz, Hilde Rosing, and Robert S. Jansen

Subjects

Pharmacology, Excretion, chemistry.chemical_compound, chemistry, Balance study, Metabolite, Pharmaceutical Science, In patient, Urine, Metabolism, Feces, Eribulin

Abstract

This mass balance study investigated the metabolism and excretion of eribulin, a nontaxane microtubule dynamics inhibitor with a novel mechanism of action, in patients with advanced solid tumors. A single approximately 2 mg (approximately 80 μCi) dose of [14C]eribulin acetate was administered as a 2 to 5 min bolus injection to six patients on day 1. Blood, urine, and fecal samples were collected at specified time points on days 1 to 8 or until sample radioactivity was ≤1% of the administered dose. Mean plasma eribulin exposure (627 ng · h/ml) was comparable with that of total radioactivity (568 ng Eq · h/ml). Time-matched concentration ratios of eribulin to total radioactivity approached unity in blood and plasma, indicating that unchanged parent compound constituted almost all of the eribulin-derived radioactivity. Only minor metabolites were detected in plasma samples up to 60 min postdose, pooled across patients, each metabolite representing ≤0.6% of eribulin. Elimination half-lives for eribulin (45.6 h) and total radioactivity (42.3 h) were comparable. Eribulin-derived radioactivity excreted in feces was 81.5%, and that of unchanged eribulin was 61.9%. Renal clearance (0.301 l/h) was a minor component of total eribulin clearance (3.93 l/h). Eribulin-derived radioactivity excreted in urine (8.9%) was comparable with that of unchanged eribulin (8.1%), indicating minimal excretion of metabolite(s) in urine. Total recovery of the radioactive dose was 90.4% in urine and feces. Overall, no major metabolites of eribulin were detected in plasma. Eribulin is eliminated primarily unchanged in feces, whereas urine constitutes a minor route of elimination.

Published

2011