CYP2C75-involved autoinduction of metabolism in rhesus monkeys of methyl 3-chloro-3'-fluoro-4'-{(1R)-1-[({1-[(trifluoroacetyl)amino]cyclopropyl}carbonyl)amino]ethyl}-1,1'-biphenyl-2-carboxylate (MK-0686), a bradykinin B1 receptor antagonist.

After oral treatment (once daily) for 4 weeks with the potent bradykinin B(1) receptor antagonist methyl 3-chloro-3'-fluoro-4'-{(1R)-1-[({1-[(trifluoroacetyl)amino]cyclopropyl}carbonyl)-amino]ethyl}-1,1'-biphenyl-2-carboxylate (MK-0686), rhesus monkeys (Macaca mulatta) exhibited significantly reduced systemic exposure of the compound in a dose-dependent manner, suggesting an occurrence of autoinduction of MK-0686 metabolism. This possibility is supported by two observations. 1) MK-0686 was primarily eliminated via biotransformation in rhesus monkeys, with oxidation on the chlorophenyl ring as one of the major metabolic pathways. This reaction led to appreciable formation of a dihydrodiol (M11) and a hydroxyl (M13) product in rhesus liver microsomes supplemented with NADPH. 2) The formation rate of these two metabolites determined in liver microsomes from MK-0686-treated groups was > or = 2-fold greater than the value for a control group. Studies with recombinant rhesus P450s and monoclonal antibodies against human P450 enzymes suggested that CYP2C75 played an important role in the formation of M11 and M13. The induction of this enzyme by MK-0686 was further confirmed by a concentration-dependent increase of its mRNA in rhesus hepatocytes, and, more convincingly, the enhanced CYP2C proteins and catalytic activities toward CYP2C75 probe substrates in liver microsomes from MK-0686-treated animals. Furthermore, a good correlation was observed between the rates of M11 and M13 formation and hydroxylase activities toward probe substrates determined in a panel of liver microsomal preparations from control and MK-0686-treated animals. Therefore, MK-0686, both a substrate and inducer for CYP2C75, caused autoinduction of its own metabolism in rhesus monkeys by increasing the expression of this enzyme.

Lack of a clinically meaningful pharmacokinetic effect of rifabutin on raltegravir: in vitro/in vivo correlation.

Raltegravir is an HIV-1 integrase strand transfer inhibitor with potent activity against HIV-1. A prior investigation of raltegravir coadministered with rifampin demonstrated a decrease in plasma concentrations of raltegravir likely secondary to induction of UGT1A1, the enzyme primarily responsible for the metabolism of raltegravir. Little is known regarding the induction of UGT1A1 by rifabutin, an alternate rifamycin. In vitro characterization of the induction potency of rifampin and rifabutin on UGT1A1 was performed. In vitro studies indicate that rifabutin is a less potent inducer of UGT1A1 messenger RNA expression than is rifampin. A fixed-sequence, 2-period, clinical crossover study was conducted to assess the effect of rifabutin on plasma levels of raltegravir: period 1, 400 mg of raltegravir every 12 hours for 4 days; period 2, 400 mg of raltegravir every 12 hours and 300 mg of rifabutin once daily for 14 days. Geometric mean ratio (GMR) (coadministration of rifabutin and raltegravir vs raltegravir alone) of raltegravir area under the concentration-time curve from 0 to 12 hours post dose (AUC(0-12h)) and the 90% confidence interval (CI) was 1.19 (0.86-1.63); GMR of concentration at 12 hours (C(12h)) and 90% CI was 0.80 (0.68-0.94); and GMR of time to maximal concentration (C(max)) and 90% CI was 1.39 (0.87-2.21). Overall, coadministration of rifabutin did not alter raltegravir pharmacokinetics to a clinically meaningful degree.

Safety and pharmacokinetics of higher doses of caspofungin in healthy adult participants.

Caspofungin was the first in a new class of antifungal agents (echinocandins) indicated for the treatment of primary and refractory fungal infections. Higher doses of caspofungin may provide another option for patients who have failed caspofungin or other antifungal therapy. This study evaluated the safety, tolerability, and pharmacokinetics of single 150- and 210-mg doses of caspofungin in 16 healthy participants and 100 mg/d for 21 days in 20 healthy participants. Other than infusion site reactions and 1 reversible elevation in alanine aminotransferase (≥2× and <4× upper limit of normal), caspofungin was generally well tolerated. Geometric mean AUC(0-∞) after single 150- and 210-mg doses was 279.7 and 374.9 µg·h/mL, respectively; peak concentrations were 29.4 and 33.5 µg/mL, respectively; and 24-hour postdose concentrations were 2.8 and 4.2 µg/mL, respectively. Steady state was achieved in the third week of dosing. Following multiple 100-mg doses of caspofungin, day 21 geometric mean AUC(0-24) was 227.4 µg·h/mL, peak concentration was 20.9 µg/mL, and trough concentration was 4.7 µg/mL. Beta-phase t(1/2) was ~8 to ~13 hours. Caspofungin pharmacokinetics at these higher doses were dose proportional to and consistent with those observed at lower doses, suggesting a modest nonlinearity of increased accumulation with dose, which was considered not clinically meaningful.