School of Pharmacy, Faculty of Medicine, The Chinese University of Hong Kong, Shatin, N.T., Hong Kong Special Administrative Region.
Department of Microbiology, Faculty of Medicine, The Chinese University of Hong Kong, Shatin, N.T., Hong Kong Special Administrative Region.
Life Sci. 2019 Oct 15;235:116818. doi: 10.1016/j.lfs.2019.116818. Epub 2019 Aug 29.
Considering the potential oral administration sequences and role of microbiota for metformin (MET) and berberine (BBR) during anti-diabetic treatments, the current study aimed to investigate the pharmacokinetic interactions between MET and BBR in rats after oral administration at different sequences and impacts of microbiota on such interactions.
Sprague-Dawley rats were divided into five groups as per what was orally administered to them: MET (G1)/BBR (G2) at 200 mg/kg, BBR 2-hour (h) after dosing MET (G3), MET 2-h after dosing BBR (G4) or MET with BBR at the same time (G5) followed by monitoring their pharmacokinetic profiles. Further in vitro incubations mimicking the above five treatments in rat intestinal content (G1R-G5R), human fecalase (G1H-G5H) and selected bacteria (G1B-G5B) were conducted for both MET and BBR (10 μg/ml for G1R/H-G5R/H and 50 μM for G1B-G5B) up to 24-h. Concentrations of MET and BBR were analyzed by LC/MS/MS.
Although BBR was barely measurable in vivo, it significantly increased systemic exposure of MET in G3/G4. Consistent with pharmacokinetic findings, sequential in vitro incubations of MET and BBR in both rat intestinal content and human fecalase demonstrated significant increase on MET persisted after 24-h incubation in G3R/H & G4R/H. Moreover, post-dose (G3B) and pre-dose (G4B) of BBR decreased the MET degradation significantly in most selected bacteria.
Our finding for the first time demonstrated the significant effect of sequential co-administration of BBR and MET on their pharmacokinetic interactions, which could be related to their microbiota mediated metabolisms in gastrointestinal tract (GI).
考虑到二甲双胍(MET)和小檗碱(BBR)在抗糖尿病治疗中的潜在口服给药顺序和微生物群的作用,本研究旨在研究不同给药顺序下 MET 和 BBR 口服给药后大鼠体内的药代动力学相互作用,以及微生物群对这种相互作用的影响。
将 Sprague-Dawley 大鼠按口服给药方式分为五组:MET(G1)/BBR(G2)200mg/kg,MET 给药后 2 小时(h)给予 BBR(G3),MET 给药后 2 小时(h)给予 BBR(G4)或同时给予 MET 和 BBR(G5),然后监测其药代动力学特征。进一步在大鼠肠内容物(G1R-G5R)、人粪便酶(G1H-G5H)和选定细菌(G1B-G5B)中进行模拟上述五种处理的体外孵育,用于 MET 和 BBR(G1R/H-G5R/H 为 10μg/ml,G1B-G5B 为 50μM),孵育时间长达 24 小时。采用 LC/MS/MS 分析 MET 和 BBR 的浓度。
虽然体内几乎无法检测到 BBR,但它显著增加了 G3/G4 中 MET 的全身暴露。与药代动力学研究结果一致,在大鼠肠内容物和人粪便酶中进行的 MET 和 BBR 的顺序体外孵育显示,在 G3R/H 和 G4R/H 中孵育 24 小时后,MET 的持续增加。此外,BBR 的给药后(G3B)和给药前(G4B)显著降低了大多数选定细菌中 MET 的降解。
我们的发现首次证明了 BBR 和 MET 序贯联合给药对其药代动力学相互作用的显著影响,这可能与它们在胃肠道(GI)中的微生物介导代谢有关。
