1. The disposition and metabolic fate of ropinirole, a novel compound indicated for the symptomatic treatment of Parkinson's disease, was studied in the mouse, rat, cynomolgus monkey and man, following oral and intravenous administration of ropinirole hydrochloride. 2. In all species, nearly all of the p.o. administered dose (94%) was rapidly absorbed from the gastrointestinal tract following administration of 14C-ropinirole hydrochloride. In rat and monkey, the compound distributed rapidly beyond total body water and was shown to cross the blood-brain barrier. Blood clearance of the compound was high, approximately equal to one-half the hepatic blood flow in the monkey and similar to the hepatic blood flow in rat. Terminal phase elimination half-lives for the compound were relatively short (0.5 and 1.3 h in rat and monkey respectively), although there was evidence of a second elimination phase in the monkey with an elimination half-life of approximately 5-11 h. Plasma concentrations of ropinirole after the intravenous dose were not determined in the mouse and were below the lower limit of quantification in man (0.08 ng/ml) at the doses used in the studies described in this paper. 3. In both animals and man, ropinirole was extensively metabolized. In the rat, the major metabolic pathway was via hydroxylation of the aromatic ring to form 7-hydroxy ropinirole. In mouse, monkey and man, the major pathway was via N-depropylation. The N-despropyl metabolite was metabolized further to form 7-hydroxy and carboxylic acid derivatives. Metabolites formed in all species were generally metabolized further by glucuronidation. 7-Hydroxy ropinirole is the only metabolite of ropinirole previously shown to possess significant dopamine agonist activity in vivo. In all species, the major route of excretion of ropinirole-related material after oral or intravenous administration of the compound was renal (60-90% of dose).
Metabolic and pharmacokinetic studies following oral administration of famciclovir to the rat and dog
1. Drug-related material was well absorbed following oral administration of 14C-famciclovir to the male rat at doses up to 4000 mg/kg and to the male dog at doses up to 250 mg/kg, as judged by the early onset of the peak blood or plasma concentrations of radioactivity (usually < or = 1.5h) and the rapid extensive excretion of radioactivity in the urine (57-76 and 86-89% of dose in rat and dog respectively). 2. Famciclovir underwent extensive first-pass metabolism in both species. In rat, following dosing at 40 mg/kg, famciclovir was rapidly and extensively metabolized to the active antiviral compound penciclovir, which reached peak concentrations in the plasma (mean 3.5 micrograms/ml) at 0.5 h. The 6-deoxy precursor of penciclovir, BRL 42359, was the only other major metabolite detected in rat plasma. Cmax values for BRL 42359 (mean 2.2 micrograms/ml) were also achieved at 0.5 h. In dog, extensive conversion of famciclovir to penciclovir, via BRL 42359, also occurred, but its rate of formation from BRL 42359 was somewhat slower than in rat. In dog, following dosing at 25 mg/kg, Cmax values for penciclovir (mean 4.4 micrograms/ml) occurred at 3 h and were lower than the Cmax values for BRL 42359 (mean 10.0 micrograms/ml) which were achieved at 1h. 3. A dose-dependent decrease in the conversion of BRL 42359 to penciclovir occurred in both species, resulting a changes in the ratios of the plasma concentrations of the two metabolites with increasing dose. In rat, the urinary excretion of penciclovir decreased from 36% of dose at 40 mg/kg to 21% at 4000 mg/kg, and was accompanied by a corresponding increase in the urinary excretion of BRL 42359. In dog, a similar decrease in the urinary excretion of penciclovir occurred on increasing the dose of famciclovir from 25 to 250 mg/kg. 4. Penciclovir and BRL 42359 were the major metabolites detected in urine and faeces. In rat, following dosing at 40 mg/kg, 54 and 22% of dose were recovered in the excreta as penciclovir and BRL 42359 respectively. Corresponding recoveries of the two metabolites in the dog were 34 and 50% of dose. The metabolic fate of famciclovir in these animal species is, therefore, similar to that reported previously in man.
1. Following oral administration of 14C-famciclovir (500 mg) to three healthy male subjects, drug-related material was rapidly absorbed as judged by peak plasma concentrations of radioactive material being achieved by 0.75 h (6.7 +/- 0.9 microgram equiv./ml (mean +/- SD). 2. Famciclovir underwent extensive first-pass metabolism and was only detected in the plasma of one subject at low concentrations (0.5 microgram/ml). Famciclovir was rapidly and extensively metabolized to the active antiviral compound penciclovir, which reached peak concentrations in the plasma of 3.6 +/- 0.7 microgram/ml (0.75 h). The plasma elimination half-life value for penciclovir was 2.1 +/- 0.1 h. The 6-deoxy precursor of penciclovir, BRL 42359, was the only other relatively major metabolite detected in plasma. Peak plasma concentrations of BRL 42359 (1.0 +/- 0.1 microgram/ml) were achieved at 0.5 h. 3. After 3 days, 73.0 +/- 6.1% of the radioactive dose was excreted in urine, showing that good absorption of drug-related material occurred. Renal excretion was rapid since 60.2 +/- 4.2 and 72.3 +/- 5.7% of the dose was recovered in the urine samples collected up to 6 and 24 h, respectively. A good recovery of the administered radioactive dose was obtained since a further 26.6 +/- 5.1% of the dose was excreted in the faeces over a 72-h period. 4. Penciclovir and BRL 42359 were the major metabolites detected in urine and faeces. Penciclovir accounted for 59.2 +/- 4.9 and 4.2 +/- 1.4% of the dose in 0-24 h urine and 0-48 h faeces, respectively. Corresponding values for BRL 42359 were 5.0 +/- 0.5 and 17.0 +/- 6.2%, respectively. These metabolites were identified in the biological samples using hplc-ms and ms-ms with thermospray ionization.
No abstract
1. Disposition of the 3R,4S(+) and 3S,4R(-) enantiomers of the racemic antihypertensive drug cromakalim has been studied in rats and cynomolgus monkeys using the 14C-drug labelled in either the 3R,4S(+) or the 3S,4R(-) enantiomer. 2. After oral administration to rat, blood concentrations of the 3R,4S(+) enantiomer were up to fourfold higher than those of the 3S,4R(-) enantiomer. Metabolism of the former was not as extensive as that of the latter and consequently plasma and urinary radiometabolite patterns were quantitatively different. 3. In contrast to rat, there were much greater differences in the disposition of the two enantiomers following oral administration of cromakalim to the cynomolgus monkey. Plasma concentrations of the 3R,4S(+) enantiomer were approximately 100 x those of the 3S,4R(-) enantiomer and the rate of urinary 14C elimination for the 3R,4S(+) enantiomer was much faster than that for the 3S,4R(-) enantiomer. Plasma and urinary radiometabolite patterns were very different for the two isomers. Metabolic end products of the 3R,4S(+) enantiomer were predominantly phase I metabolites whereas the 3S,4R(-) enantiomer was almost entirely metabolized by glucuronidation. 4. A study of the racemic drug alone would have led to a misunderstanding of the fate of the compound in these species.
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