Lin Jiunn H, Yamazaki Masayo
Department of Drug Metabolism, Merck Research Laboratories, West Point, Pennsylvania 19486, USA.
Clin Pharmacokinet. 2003;42(1):59-98. doi: 10.2165/00003088-200342010-00003.
P-glycoprotein, the most extensively studied ATP-binding cassette (ABC) transporter, functions as a biological barrier by extruding toxins and xenobiotics out of cells. In vitro and in vivo studies have demonstrated that P-glycoprotein plays a significant role in drug absorption and disposition. Because of its localisation, P-glycoprotein appears to have a greater impact on limiting cellular uptake of drugs from blood circulation into brain and from intestinal lumen into epithelial cells than on enhancing the excretion of drugs out of hepatocytes and renal tubules into the adjacent luminal space. However, the relative contribution of intestinal P-glycoprotein to overall drug absorption is unlikely to be quantitatively important unless a very small oral dose is given, or the dissolution and diffusion rates of the drug are very slow. This is because P-glycoprotein transport activity becomes saturated by high concentrations of drug in the intestinal lumen. Because of its importance in pharmacokinetics, P-glycoprotein transport screening has been incorporated into the drug discovery process, aided by the availability of transgenic mdr knockout mice and in vitro cell systems. When applying in vitro and in vivo screening models to study P-glycoprotein function, there are two fundamental questions: (i) can in vitro data be accurately extrapolated to the in vivo situation; and (ii) can animal data be directly scaled up to humans? Current information from our laboratory suggests that in vivo P-glycoprotein activity for a given drug can be extrapolated reasonably well from in vitro data. On the other hand, there are significant species differences in P-glycoprotein transport activity between humans and animals, and the species differences appear to be substrate-dependent. Inhibition and induction of P-glycoprotein have been reported as the causes of drug-drug interactions. The potential risk of P-glycoprotein-mediated drug interactions may be greatly underestimated if only plasma concentration is monitored. From animal studies, it is clear that P-glycoprotein inhibition always has a much greater impact on tissue distribution, particularly with regard to the brain, than on plasma concentrations. Therefore, the potential risk of P-glycoprotein-mediated drug interactions should be assessed carefully. Because of overlapping substrate specificity between cytochrome P450 (CYP) 3A4 and P-glycoprotein, and because of similarities in P-glycoprotein and CYP3A4 inhibitors and inducers, many drug interactions involve both P-glycoprotein and CYP3A4. Unless the relative contribution of P-glycoprotein and CYP3A4 to drug interactions can be quantitatively estimated, care should be taken when exploring the underlying mechanism of such interactions.
P-糖蛋白是研究最为广泛的ATP结合盒(ABC)转运蛋白,它通过将毒素和外源性物质排出细胞而发挥生物屏障的作用。体外和体内研究均表明,P-糖蛋白在药物吸收和处置过程中发挥着重要作用。由于其定位特点,相较于促进药物从肝细胞和肾小管排泄至相邻管腔空间,P-糖蛋白似乎对限制药物从血液循环进入大脑以及从肠腔进入上皮细胞的细胞摄取影响更大。然而,除非给予极小的口服剂量,或者药物的溶解和扩散速率非常缓慢,否则肠道P-糖蛋白对总体药物吸收的相对贡献在数量上不太可能具有重要意义。这是因为肠道腔内高浓度的药物会使P-糖蛋白的转运活性饱和。鉴于其在药代动力学中的重要性,借助转基因mdr基因敲除小鼠和体外细胞系统,P-糖蛋白转运筛选已被纳入药物研发过程中。在应用体外和体内筛选模型研究P-糖蛋白功能时,存在两个基本问题:(i)体外数据能否准确外推至体内情况;(ii)动物数据能否直接放大至人体?我们实验室目前的信息表明,对于给定药物,体内P-糖蛋白活性可以较好地从体外数据合理外推得出。另一方面,人与动物之间P-糖蛋白转运活性存在显著的种属差异,且种属差异似乎依赖于底物。据报道,P-糖蛋白的抑制和诱导是药物相互作用的原因。如果仅监测血浆浓度,P-糖蛋白介导药物相互作用的潜在风险可能会被大大低估。从动物研究中可以清楚地看到,P-糖蛋白抑制对组织分布(尤其是大脑)的影响总是比对血浆浓度大得多。因此,应仔细评估P-糖蛋白介导药物相互作用的潜在风险。由于细胞色素P450(CYP)3A4与P-糖蛋白之间存在底物特异性重叠,且P-糖蛋白和CYP3A4的抑制剂和诱导剂具有相似性,许多药物相互作用同时涉及P-糖蛋白和CYP3A4。除非能够定量估计P-糖蛋白和CYP3A4对药物相互作用的相对贡献,则在探究此类相互作用的潜在机制时应谨慎行事。
