Your search keyword '"Yu NX"' showing total 2 results

1. 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.

Author

Tang C, Carr BA, Poignant F, Ma B, Polsky-Fisher SL, Kuo Y, Strong-Basalyga K, Norcross A, Richards K, Eisenhandler R, Carlini EJ, Di Marco CN, Kuduk SD, Yu NX, Raab CE, Rushmore T, Frederick CB, Bock MG, and Prueksaritanont T

Subjects

Acetamides blood, Acetamides urine, Animals, Benzoates blood, Benzoates urine, Bile metabolism, Cell Line, Tumor, Cells, Cultured, Cytochrome P-450 Enzyme System genetics, Female, Hepatocytes metabolism, Humans, Macaca mulatta, Male, Microsomes, Liver metabolism, Pregnane X Receptor, Receptor, Bradykinin B1 metabolism, Receptors, Steroid metabolism, Recombinant Proteins metabolism, Acetamides pharmacokinetics, Benzoates pharmacokinetics, Bradykinin B1 Receptor Antagonists, Cytochrome P-450 Enzyme System metabolism

Abstract

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.

Published

2008

2. Interaction of diclofenac and quinidine in monkeys: stimulation of diclofenac metabolism.

Author

Tang W, Stearns RA, Kwei GY, Iliff SA, Miller RR, Egan MA, Yu NX, Dean DC, Kumar S, Shou M, Lin JH, and Baillie TA

Subjects

Animals, Biotransformation, Blood Proteins metabolism, Chromatography, Liquid, Cytochrome P-450 CYP3A, Cytochrome P-450 Enzyme System metabolism, Drug Interactions, Liver drug effects, Liver enzymology, Liver metabolism, Macaca mulatta, Male, Mass Spectrometry, Microsomes, Liver drug effects, Microsomes, Liver metabolism, Oxidoreductases, N-Demethylating metabolism, Anti-Inflammatory Agents, Non-Steroidal pharmacokinetics, Antimalarials pharmacology, Aryl Hydrocarbon Hydroxylases, Diclofenac pharmacokinetics, Quinidine pharmacology

Abstract

The cytochrome P-450 (CYP)3A4-mediated metabolism of diclofenac is stimulated in vitro by quinidine. A similar effect is observed in incubations with monkey liver microsomes. We describe an in vivo interaction of diclofenac and quinidine that leads to enhanced clearance of diclofenac in monkeys. After a dose of diclofenac via portal vein infusion at 0.055 mg/kg/h, steady-state systemic plasma drug concentrations in three male rhesus monkeys were 87, 104, and 32 ng/ml, respectively (control). When diclofenac was coadministered with quinidine (0.25 mg/kg/h) via the same route, the corresponding plasma diclofenac concentrations were 50, 59, and 18 ng/ml, representing 57, 56, and 56% of control values, respectively. In contrast, steady-state systemic diclofenac concentrations in the same three monkeys were elevated 1.4 to 2.5 times when the monkeys were pretreated with L-754,394 (10 mg/kg i.v.), an inhibitor of CYP3A. Further investigation indicated that the plasma protein binding (>99%) and blood/plasma ratio (0.7) of diclofenac remained unchanged in the presence of quinidine. Therefore, the decreases in plasma concentrations of diclofenac after a combined dose of diclofenac and quinidine are taken to reflect increased hepatic clearance of the drug, presumably resulting from the stimulation of CYP3A-catalyzed oxidative metabolism. Consistent with this proposed mechanism, a 2-fold increase in the formation of 5-hydroxydiclofenac derivatives was observed in monkey hepatocyte suspensions containing diclofenac and quinidine. Stimulation of diclofenac metabolism by quinidine was diminished when monkey liver microsomes were pretreated with antibodies against CYP3A. Subsequent kinetic studies indicated that the K(m) value for the CYP-mediated conversion of diclofenac to its 5-hydroxy derivatives was little changed (75 versus 59 microM), whereas V(max) increased 2.5-fold in the presence of quinidine. These data suggest that the catalytic capacity of monkey hepatic CYP3A toward diclofenac metabolism is enhanced by quinidine.

Published

1999