Takahashi Ryan H, Choo Edna F, Ma Shuguang, Wong Susan, Halladay Jason, Deng Yuzhong, Rooney Isabelle, Gates Mary, Hop Cornelis E C A, Khojasteh S Cyrus, Dresser Mark J, Musib Luna
Departments of Drug Metabolism and Pharmacokinetics (R.H.T., E.F.C., S.M., S.W., J.H., Y.D., C.E.C.A.H., S.C.K.,), Product Development Oncology (I.R.), Early Clinical Development (M.G.), and Clinical Pharmacology (M.J.D, L.M.), Genentech, South San Francisco, California
Departments of Drug Metabolism and Pharmacokinetics (R.H.T., E.F.C., S.M., S.W., J.H., Y.D., C.E.C.A.H., S.C.K.,), Product Development Oncology (I.R.), Early Clinical Development (M.G.), and Clinical Pharmacology (M.J.D, L.M.), Genentech, South San Francisco, California.
Drug Metab Dispos. 2016 Jan;44(1):28-39. doi: 10.1124/dmd.115.066282. Epub 2015 Oct 8.
The pharmacokinetics, metabolism, and excretion of cobimetinib, a MEK inhibitor, were characterized in healthy male subjects (n = 6) following a single 20 mg (200 μCi) oral dose. Unchanged cobimetinib and M16 (glycine conjugate of hydrolyzed cobimetinib) were the major circulating species, accounting for 20.5% and 18.3% of the drug-related material in plasma up to 48 hours postdose, respectively. Other circulating metabolites were minor, accounting for less than 10% of drug-related material in plasma. The total recovery of the administered radioactivity was 94.3% (±1.6%, S.D.) with 76.5% (±2.3%) in feces and 17.8% (±2.5%) in urine. Metabolite profiling indicated that cobimetinib had been extensively metabolized with only 1.6% and 6.6% of the dose remaining as unchanged drug in urine and feces, respectively. In vitro phenotyping experiments indicated that CYP3A4 was predominantly responsible for metabolizing cobimetinib. From this study, we concluded that cobimetinib had been well absorbed (fraction absorbed, Fa = 0.88). Given this good absorption and the previously determined low hepatic clearance, the systemic exposures were lower than expected (bioavailability, F = 0.28). We hypothesized that intestinal metabolism had strongly attenuated the oral bioavailability of cobimetinib. Supporting this hypothesis, the fraction escaping gut wall elimination (Fg) was estimated to be 0.37 based on F and Fa from this study and the fraction escaping hepatic elimination (Fh) from the absolute bioavailability study (F = Fa × Fh × Fg). Physiologically based pharmacokinetics modeling also showed that intestinal clearance had to be included to adequately describe the oral profile. These collective data suggested that cobimetinib was well absorbed following oral administration and extensively metabolized with intestinal first-pass metabolism contributing to its disposition.
在6名健康男性受试者单次口服20毫克(200微居里)剂量的MEK抑制剂考比替尼后,对其药代动力学、代谢和排泄情况进行了研究。原形考比替尼和M16(水解考比替尼的甘氨酸结合物)是主要的循环物质,在给药后48小时内分别占血浆中药物相关物质的20.5%和18.3%。其他循环代谢物含量较少,占血浆中药物相关物质的比例不到10%。给药放射性的总回收率为94.3%(±1.6%,标准差),其中76.5%(±2.3%)经粪便排出,17.8%(±2.5%)经尿液排出。代谢物谱分析表明,考比替尼已被广泛代谢,尿液和粪便中分别仅有1.6%和6.6%的剂量以原形药物形式存在。体外表型实验表明,CYP3A4是考比替尼代谢的主要酶。从这项研究中,我们得出结论,考比替尼吸收良好(吸收分数,Fa = 0.88)。鉴于这种良好的吸收以及先前测定的较低肝清除率,全身暴露量低于预期(生物利用度,F = 0.28)。我们推测肠道代谢强烈削弱了考比替尼的口服生物利用度。支持这一假设的是,根据本研究中的F和Fa以及绝对生物利用度研究中的肝脏消除逃逸分数(Fh),估计肠道壁消除逃逸分数(Fg)为0.37(F = Fa × Fh × Fg)。基于生理学的药代动力学模型也表明,必须纳入肠道清除率才能充分描述口服情况。这些综合数据表明,考比替尼口服给药后吸收良好且被广泛代谢,肠道首过代谢对其处置过程有影响。
