地高辛通过肠黏膜大量排泄,以及多药耐药蛋白1a(mdr 1a)P-糖蛋白防止地高辛在大脑中长期蓄积。
Substantial excretion of digoxin via the intestinal mucosa and prevention of long-term digoxin accumulation in the brain by the mdr 1a P-glycoprotein.
作者信息
Mayer U, Wagenaar E, Beijnen J H, Smit J W, Meijer D K, van Asperen J, Borst P, Schinkel A H
机构信息
Division of Molecular Biology, The Netherlands Cancer Institute, Amsterdam, The Netherlands.
出版信息
Br J Pharmacol. 1996 Nov;119(5):1038-44. doi: 10.1111/j.1476-5381.1996.tb15775.x.
Abstract
- We have used mice with a disrupted mdr 1a P-glycoprotein gene (mdr 1a (-/-) mice) to study the role of P-glycoprotein in the pharmacokinetics of digoxin, a model P-glycoprotein substrate. 2. [3H]-digoxin at a dose of 0.2 mg kg-1 was administered as a single i.v. or oral bolus injection. We focussed on intestinal mucosa and brain endothelial cells, two major pharmacological barriers, as the mdr 1a P-glycoprotein is the only P-glycoprotein normally present in these tissues. 3. Predominant faecal excretion of [3H]-digoxin in wild-type mice shifted towards predominantly urinary excretion in mdr 1a (-/-) mice. 4. After interruption of the biliary excretion into the intestine, we found a substantial excretion of [3H]-digoxin via the gut mucosa in wild-type mice (16% of administered dose over 90 min). This was only 2% in mdr 1a (-/-) mice. Biliary excretion of [3H]-digoxin was not dramatically decreased (24% in wild-type mice versus 16% in mdr 1a (-/-) mice). 5. After a single bolus injection, brain levels of [3H]-digoxin in wild-type mice remained very low, whereas in mdr 1a (-/-) mice these levels continuously increased over a period of 3 days, resulting in a approximately 200 fold higher concentration than in wild-type mice. 6. These data demonstrate the in vivo contribution of intestinal P-glycoprotein to direct elimination of [3H]-digoxin from the systemic circulation and to the pattern of [3H]-digoxin disposition, and they underline the importance of P-glycoprotein for the blood-brain barrier.
摘要
- 我们使用了多药耐药蛋白1a(mdr 1a)P-糖蛋白基因缺失的小鼠(mdr 1a (-/-) 小鼠)来研究P-糖蛋白在洋地黄毒苷(一种典型的P-糖蛋白底物)药代动力学中的作用。2. 以0.2 mg kg-1的剂量静脉内或口服推注给予[3H]-洋地黄毒苷。我们将重点放在肠黏膜和脑内皮细胞这两个主要的药理学屏障上,因为mdr 1a P-糖蛋白是这些组织中正常存在的唯一P-糖蛋白。3. 野生型小鼠中[3H]-洋地黄毒苷主要经粪便排泄,而在mdr 1a (-/-) 小鼠中则主要转向经尿液排泄。4. 在胆汁排泄进入肠道的过程被阻断后,我们发现野生型小鼠中[3H]-洋地黄毒苷通过肠黏膜有大量排泄(90分钟内为给药剂量的16%)。在mdr 1a (-/-) 小鼠中这一比例仅为2%。[3H]-洋地黄毒苷的胆汁排泄没有显著减少(野生型小鼠中为24%,mdr 1a (-/-) 小鼠中为16%)。5. 单次推注给药后,野生型小鼠脑中[3H]-洋地黄毒苷的水平一直很低,而在mdr 1a (-/-) 小鼠中,这些水平在3天内持续升高,导致其浓度比野生型小鼠高约200倍。6. 这些数据证明了肠P-糖蛋白在体内对[3H]-洋地黄毒苷从体循环中的直接清除以及[3H]-洋地黄毒苷处置模式的作用,并且强调了P-糖蛋白对血脑屏障的重要性。
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