Kharasch E D, Russell M, Mautz D, Thummel K E, Kunze K L, Bowdle A, Cox K
Anesthesiology Service, Puget Sound Veterans Affairs Health Care System, Seattle, Washington, USA.
Anesthesiology. 1997 Jul;87(1):36-50. doi: 10.1097/00000542-199707000-00006.
There is considerable unexplained variability in alfentanil pharmacokinetics, particularly systemic clearance. Alfentanil is extensively metabolized in vivo, and thus systemic clearance depends on hepatic biotransformation. Cytochrome P450 3A4 was previously shown to be the predominant P450 isoform responsible for human liver microsomal alfentanil metabolism in vitro. This investigation tested the hypothesis that P450 3A4 is responsible for human alfentanil metabolism and clearance in vivo.
Nine healthy male volunteers who provided institutionally approved written informed consent were studied in a three-way randomized crossover design. Each subject received alfentanil (20 micrograms/kg given intravenously) 30 min after midazolam (1 mg injected intravenously) on three occasions: control; high P450 3A4 activity (rifampin induction); and low P450 3A4 activity (selective inhibition by troleandomycin). Midazolam is a validated selective in vivo probe for P450 3A4 activity. Venous blood was sampled for 24 h and plasma concentrations of midazolam and alfentanil and their primary metabolites 1'-hydroxymidazolam and noralfentanil were measured by gas chromatography-mass spectrometry. Pharmacokinetic parameters were determined by two-stage analysis using both noncompartmental and three-compartment models.
Plasma alfentanil concentration-time profiles depended significantly on P450 3A4 activity. Alfentanil noncompartmental clearance was 5.3 +/- 2.3, 14.6 +/- 3.8, and 1.1 +/- 0.5 ml.kg-1.min-1, and elimination half-life was 58 +/- 13, 35 +/- 7, and 630 +/- 374 min, respectively, in participants with normal (controls), high (rifampin), and low (troleandomycin) P450 3A4 activity (means +/- SD; P < 0.05 compared with controls). Multicompartmental modeling suggested a time-dependent inhibition-resynthesis model for troleandomycin effects on P450 3A4 activity, characterized as k10(t) = k10[1-phi e-alpha(t-tzero)], where k10(t) is the apparent time-dependent rate constant, k10 is the uninhibited rate constant, phi is the fraction of P450 3A4 inhibited, and alpha is the apparent P450 3A4 reactivation rate. Alfentanil clearance was calculated as V1 k10 for controls and men receiving rifampin, and as V1.average k10(t) for men receiving troleandomycin. This clearance was 4.9 +/- 2.1, 13.2 +/- 3.6, and 1.5 +/- 0.8 ml.kg-1.min-1, respectively, in controls and in men receiving rifampin or troleandomycin. There was a significant correlation (r = 0.97, P < 0.001) between alfentanil systemic clearance and P450 3A4 activity.
Modulation of P450 3A4 activity by rifampin and troleandomycin significantly altered alfentanil clearance and disposition. These results strongly suggest that P450 3A4 is the major isoform of P450 responsible for clinical alfentanil metabolism and clearance. This observation, combined with the known population variability in P450 3A4 activity, provides a mechanistic explanation for the interindividual variability in alfentanil disposition. Furthermore, known susceptibility of human P450 3A4 activity to induction and inhibition provides a conceptual framework for understanding and predicting clinical alfentanil drug interactions. Finally, human liver microsomal alfentanil metabolism in vitro is confirmed as an excellent model for human alfentanil metabolism in vivo.
阿芬太尼的药代动力学存在相当大的无法解释的变异性,尤其是全身清除率。阿芬太尼在体内广泛代谢,因此全身清除率取决于肝脏生物转化。细胞色素P450 3A4先前已被证明是体外负责人类肝微粒体阿芬太尼代谢的主要P450同工酶。本研究检验了P450 3A4负责人类阿芬太尼体内代谢和清除的假设。
采用三向随机交叉设计对9名提供了机构批准的书面知情同意书的健康男性志愿者进行研究。每位受试者在咪达唑仑(静脉注射1 mg)后30分钟静脉注射阿芬太尼(20微克/千克),共进行三次:对照;高P450 3A4活性(利福平诱导);低P450 3A4活性(醋竹桃霉素选择性抑制)。咪达唑仑是一种经过验证的P450 3A4活性体内选择性探针。采集静脉血24小时,采用气相色谱-质谱法测定血浆中咪达唑仑和阿芬太尼及其主要代谢物1'-羟基咪达唑仑和去甲阿芬太尼的浓度。使用非房室模型和三室模型通过两阶段分析确定药代动力学参数。
血浆阿芬太尼浓度-时间曲线显著依赖于P450 3A4活性。在P450 3A4活性正常(对照)、高(利福平)和低(醋竹桃霉素)的参与者中,阿芬太尼的非房室清除率分别为5.3±2.3、14.6±3.8和1.1±0.5毫升·千克-1·分钟-1,消除半衰期分别为58±13、35±7和630±374分钟(均值±标准差;与对照相比P<0.05)。多房室建模表明醋竹桃霉素对P450 3A4活性的影响为时间依赖性抑制-再合成模型,其特征为k10(t)=k10[1-φe-α(t-t0)],其中k10(t)是表观时间依赖性速率常数,k10是未受抑制的速率常数,φ是被抑制的P450 3A部分,α是表观P450 3A4再激活速率。对照和接受利福平的男性的阿芬太尼清除率按V1k10计算,接受醋竹桃霉素的男性按V1.average k10(t)计算 = 分别为4.9±2.1、13.2±3.6和1.5±0.8毫升·千克-1·分钟-1。阿芬太尼全身清除率与P450 3A4活性之间存在显著相关性(r = 0.97,P<0.001)。
利福平和醋竹桃霉素对P450 3A4活性的调节显著改变了阿芬太尼的清除率和处置。这些结果强烈表明P450 3A4是负责临床阿芬太尼代谢和清除的主要P450同工酶。这一观察结果,结合已知的P450 3A4活性人群变异性,为阿芬太尼处置的个体间变异性提供了一个机制解释。此外,已知人类P450 3A4活性对诱导和抑制的敏感性为理解和预测临床阿芬太尼药物相互作用提供了一个概念框架。最后,体外人肝微粒体阿芬太尼代谢被确认为体内人阿芬太尼代谢的一个优秀模型。
