Genotype-Guided Tamoxifen Dosing Increases Active Metabolite Exposure in Women With Reduced CYP2D6 Metabolism: A Multicenter Study

We examined the feasibility of using CYP2D6 genotyping to determine optimal tamoxifen dose and investigated whether the key active tamoxifen metabolite, endoxifen, could be increased by genotype-guided tamoxifen dosing in patients with intermediate CYP2D6 metabolism

Contribution of N-Glucuronidation to Efavirenz Elimination In Vivo in the Basal and Rifampin-Induced Metabolism of Efavirenz▿

In this study, the contribution of efavirenz N-glucuronidation to efavirenz elimination in vivo was assessed. In a two-period placebo-controlled crossover trial design, a single 600-mg oral dose of efavirenz was administered to healthy volunteers (n = 10) pretreated with placebo pills or 600 mg/day rifampin orally for 10 days. Urine and plasma concentrations of efavirenz and 8-hydroxyefavirenz were measured by the liquid chromatography-tandem mass spectrometry method after enzymatic hydrolysis with β-glucuronidase (conjugated and unconjugated) and without enzymatic hydrolysis (unconjugated). Pharmacokinetic parameters of efavirenz within the placebo- or rifampin-treated group obtained after enzymatic hydrolysis did not show any statistically significant difference compared with those obtained without enzymatic hydrolysis (P > 0.05; paired t test, two-tailed). The amount of efavirenz excreted over 12 h was significantly larger after enzymatic hydrolysis in both the placebo (P = 0.007) and rifampin (P = 0.0001) treatment groups, supporting the occurrence of direct N-glucuronidation of efavirenz, but the relevance of this finding is limited because the amount of efavirenz excreted as unchanged or conjugated in urine is less than 1% of the dose administered. In both the placebo- and rifampin-treated groups, plasma concentrations of 8-hydroxyefavirenz and the amount excreted over 12 h were significantly larger (P < 0.00001) after enzymatic hydrolysis than without enzymatic hydrolysis. These findings suggest that although the occurrence of direct efavirenz N-glucuronidation is supported by the urine data, the abundance of efavirenz N-glucuronide in plasma is negligible and that the contribution of the N-glucuronidation pathway to the overall clearance of efavirenz seems minimal

Efavirenz Primary and Secondary Metabolism In Vitro and In Vivo: Identification of Novel Metabolic Pathways and Cytochrome P450 2A6 as the Principal Catalyst of Efavirenz 7-Hydroxylation

Efavirenz primary and secondary metabolism was investigated in vitro and in vivo. In human liver microsome (HLM) samples, 7- and 8-hydroxyefavirenz accounted for 22.5 and 77.5% of the overall efavirenz metabolism, respectively. Kinetic, inhibition, and correlation analyses in HLM samples and experiments in expressed cytochrome P450 show that CYP2A6 is the principal catalyst of efavirenz 7-hydroxylation. Although CYP2B6 was the main enzyme catalyzing efavirenz 8-hydroxylation, CYP2A6 also seems to contribute. Both 7- and 8-hydroxyefavirenz were further oxidized to novel dihydroxylated metabolite(s) primarily by CYP2B6. These dihydroxylated metabolite(s) were not the same as 8,14-dihydroxyefavirenz, a metabolite that has been suggested to be directly formed via 14-hydroxylation of 8-hydroxyefavirenz, because 8,14-dihydroxyefavirenz was not detected in vitro when efavirenz, 7-, or 8-hydroxyefavirenz were used as substrates. Efavirenz and its primary and secondary metabolites that were identified in vitro were quantified in plasma samples obtained from subjects taking a single 600-mg oral dose of efavirenz. 8,14-Dihydroxyefavirenz was detected and quantified in these plasma samples, suggesting that the glucuronide or the sulfate of 8-hydroxyefavirenz might undergo 14-hydroxylation in vivo. In conclusion, efavirenz metabolism is complex, involving unique and novel secondary metabolism. Although efavirenz 8-hydroxylation by CYP2B6 remains the major clearance mechanism of efavirenz, CYP2A6-mediated 7-hydroxylation (and to some extent 8-hydroxylation) may also contribute. Efavirenz may be a valuable dual phenotyping tool to study CYP2B6 and CYP2A6, and this should be further tested in vivo