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Departments of
Medicinal Chemistry (P.S., M.R., J.G.S., T.A.B.),
Pharmaceutics (S.W.M., F.E.B., B.M.K., M.M., M.M., R.H.L.), and
Neurological Surgery (R.H.L.), University of Washington; and
Biocodex
Research Centre (L.B.-C., F.L., J.-J.D., M.P.)
N-(2,6-dimethylphenyl)-5-methyl-3-isoxazolecarboxamide
(D2624) belongs to a new series of experimental anticonvulsants related to lidocaine. This study was undertaken to understand the
pharmacokinetics and metabolism of D2624 in rats and humans, with
emphasis on the possible formation of 2,6-dimethylaniline (2,6-DMA).
After oral administration of stable isotope-labeled parent drug to rats
and GC/MS analysis of plasma samples, two metabolites were identified: D3017, which is the primary alcohol, and 2,6-DMA, formed by amide bond
hydrolysis of either D2624 or D3017. In urine, three metabolites of
D2624 were identified: namely D3017, 2,6-DMA, and D3270 (which is the
carboxylic acid derivative of D3017). Based on plasma AUC analysis,
D3017 and 2,6-DMA accounted for >90% of the dose of D2624. After oral
administration, D2624 was found to be well absorbed (93%), but
underwent extensive first-pass metabolism in the rat, thus resulting in
5.3% bioavailability. Rat and human liver microsomal preparations were
capable of metabolizing D2624 to D3017 and 2,6-DMA. The formation of
D3017 was NADPH-dependent, whereas 2,6-DMA formation was
NADPH-independent and probably was catalyzed by amidase(s) enzymes. In
a single-dose (25-225 mg) human volunteer study, the parent drug
(D2624) was not detected in plasma at any dose, whereas 2,6-DMA was
detected only at the two highest doses (150 and 225 mg). D3017 was
detected after all doses of parent drug, with approximate dose
proportionality in AUC and a half-life of 1.3-2.2 hr. The metabolic
behavior observed in humans suggests there is a marked species
difference in the oxidative and hydrolytic pathways of D2624.
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