Pharmacokinetics and Metabolism of 14C-levetiracetam, a New Antiepileptic Agent, in Healthy Volunteers

Overview

Journal Eur J Clin Pharmacol

Specialty Pharmacology

Date 2003 Oct 8

PMID 14530892

Citations 23

Authors

Margherita Strolin Benedetti

Rhys Whomsley

Jean-Marie Nicolas

Colin Young

Eugene Baltes

Affiliations

Soon will be listed here.

Abstract

The absorption, disposition and metabolism of levetiracetam, a new antiepileptic drug, have been investigated after a single oral dose of the (14)C-labelled molecule administered to male healthy volunteers. As chiral inversion can occur during drug metabolism, the chiral inversion of levetiracetam and/or of its major metabolite produced by hydrolysis (the corresponding acid) was also investigated. Finally, the in vitro hydrolysis of levetiracetam to its major metabolite and the inhibition of this reaction in human blood have been studied. Levetiracetam was very rapidly absorbed in man, with the peak plasma concentration of the unchanged drug occurring at 0.25-0.50 h. The unchanged drug accounted for a very high percentage of plasma radioactivity (97-82%) at all the times measured, i.e. until 48 h after administration. The apparent volume of distribution of the compound was close (0.55-0.62 l/kg) to the volume of total body water. Total body clearance (0.80-0.97 ml/min/kg) was much lower than the nominal hepatic blood flow. The plasma elimination half-life of the unchanged drug varied between 7.4 h and 7.9 h. Plasma to blood ratio of total radioactivity concentrations was 1.1-1.3, showing that radioactivity concentrations were similar in blood cells and plasma. The balance of excretion was very high in all four volunteers. The predominant route of excretion was via urine, accounting for a mean of 95% of the administered dose after 4 days. Two major radioactive components were present in urine, the unchanged drug and the acid obtained by hydrolysis, accounting for 66% and 24% of the dose after 48 h, respectively. Hydrolysis of levetiracetam in human blood followed Michaelis-Menten kinetics with Km and V(max) values of 435 microM and 129 pmol/min/ml blood, respectively. Among the inhibitory agents investigated in this study, only paraoxon inhibited levetiracetam hydrolysis (92% inhibition at 100 microM). Oxidative metabolism occurred in man, although it accounted for no more than 2.5% of the dose. There was no evidence of chiral inversion.

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