Department of Pharmaceutical Sciences, St. Jude Children's Research Hospital, Memphis, Tennessee;
Am J Physiol Cell Physiol. 2013 Dec 15;305(12):C1223-9. doi: 10.1152/ajpcell.00232.2013. Epub 2013 Aug 28.
Hydroxyurea is currently the only FDA-approved drug that ameliorates the pathophysiology of sickle cell anemia. Unfortunately, substantial interpatient variability in the pharmacokinetics (PK) of hydroxyurea may result in variation of the drug's efficacy. However, little is known about mechanisms that modulate hydroxyurea PK. Recent in vitro studies identifying hydroxyurea as a substrate for organic anion transporting polypeptide (OATP1B) transporters prompted the current investigation assessing the role of OATP1B transporters in modulating hydroxyurea PK. Using wild-type and Oatp1b knockout (Oatp1b(-/-)) mice, hydroxyurea PK was analyzed in vivo by measuring [(14)C]hydroxyurea distribution in plasma, kidney, liver, urine, or the exhaled (14)CO2 metabolite. Plasma levels were significantly reduced by 20% in Oatp1b(-/-) mice compared with wild-type (area under the curve of 38.64 or 48.45 μg·h(-1)·ml(-1), respectively) after oral administration, whereas no difference was observed between groups following intravenous administration. Accumulation in the kidney was significantly decreased by twofold in Oatp1b(-/-) mice (356.9 vs. 748.1 pmol/g), which correlated with a significant decrease in urinary excretion. Hydroxyurea accumulation in the liver was also decreased (136.6 vs. 107.3 pmol/g in wild-type or Oatp1b(-/-) mice, respectively) correlating with a decrease in exhaled (14)CO2. These findings illustrate that deficiency of Oatp1b transporters alters the absorption, distribution, and elimination of hydroxyurea thus providing the first in vivo evidence that cell membrane transporters may play a significant role in modulating hydroxyurea PK. Future studies to investigate other transporters and their role in hydroxyurea disposition are warranted for understanding the sources of variation in hydroxyurea's PK.
羟基脲是目前唯一被 FDA 批准用于改善镰状细胞贫血病理生理学的药物。不幸的是,羟基脲的药代动力学(PK)在患者之间存在很大的变异性,这可能导致药物疗效的变化。然而,对于调节羟基脲 PK 的机制知之甚少。最近的体外研究表明,羟基脲是有机阴离子转运多肽(OATP1B)转运体的底物,这促使我们进行了当前的研究,以评估 OATP1B 转运体在调节羟基脲 PK 中的作用。通过测量血浆、肾脏、肝脏、尿液或呼出的(14)CO2 代谢物中[(14)C]羟基脲的分布,在体内分析野生型和 Oatp1b 敲除(Oatp1b(-/-))小鼠的羟基脲 PK。与野生型相比,口服后 Oatp1b(-/-)小鼠的血浆水平降低了 20%(曲线下面积分别为 38.64 或 48.45 μg·h(-1)·ml(-1)),而静脉注射后两组之间无差异。Oatp1b(-/-)小鼠的肾脏积累减少了两倍(356.9 与 748.1 pmol/g),这与尿排泄量显著减少有关。肝脏中羟基脲的积累也减少了(野生型或 Oatp1b(-/-)小鼠分别为 136.6 与 107.3 pmol/g),与呼出的(14)CO2 减少有关。这些发现表明,Oatp1b 转运体的缺乏改变了羟基脲的吸收、分布和消除,从而首次提供了细胞表面转运体可能在调节羟基脲 PK 中起重要作用的体内证据。未来研究其他转运体及其在羟基脲处置中的作用,对于理解羟基脲 PK 变异性的来源是必要的。