一种针对缺氧的前药 PR-104A 的药代动力学模型在人体、犬、大鼠和小鼠中的综合应用预测了清除率和毒性方面的物种差异。

A combined pharmacokinetic model for the hypoxia-targeted prodrug PR-104A in humans, dogs, rats and mice predicts species differences in clearance and toxicity.

机构信息

Faculty of Medical and Health Sciences, Auckland Cancer Society Research Centre, The University of Auckland, Private Bag 92019, Auckland, New Zealand.

出版信息

Cancer Chemother Pharmacol. 2011 May;67(5):1145-55. doi: 10.1007/s00280-010-1412-z. Epub 2010 Aug 4.

DOI:10.1007/s00280-010-1412-z

PMID:20683596

Abstract

BACKGROUND

PR-104 is a phosphate ester that is systemically converted to the corresponding alcohol PR-104A. The latter is activated by nitroreduction in tumours to cytotoxic DNA cross-linking metabolites. Here, we report a population pharmacokinetic (PK) model for PR-104 and PR-104A in non-human species and in humans.

METHODS

A compartmental model was used to fit plasma PR-104 and PR-104A concentration-time data after intravenous (i.v.) dosing of humans, Beagle dogs, Sprague-Dawley rats and CD-1 nude mice. Intraperitoneal (i.p.) PR-104 and i.v. PR-104A dosing of mice was also investigated. Protein binding was measured in plasma from each species. Unbound drug clearances and volumes were scaled allometrically.

RESULTS

A two-compartment model described the disposition of PR-104 and PR-104A in all four species. PR-104 was cleared rapidly by first-order (mice, rats, dogs) or mixed-order (humans) metabolism to PR-104A in the central compartment. The estimated unbound human clearance of PR104A was 211 L/h/70 kg, with a steady state unbound volume of 105 L/70 kg. The size equivalent unbound PR-104A clearance was 2.5 times faster in dogs, 0.78 times slower in rats and 0.63 times slower in mice, which may reflect reported species differences in PR-104A O-glucuronidation.

CONCLUSIONS

The PK model demonstrates faster size equivalent clearance of PR-104A in dogs and humans than rodents. Dose-limiting myelotoxicity restricts the exposure of PR-104A in humans to approximately 25% of that achievable in mice.

摘要

背景

PR-104 是一种磷酸酯，可在体内转化为相应的醇 PR-104A。后者在肿瘤中通过硝基还原被激活，生成细胞毒性 DNA 交联代谢物。在此，我们报告了一种非人类物种和人类中 PR-104 和 PR-104A 的群体药代动力学（PK）模型。

方法

使用房室模型拟合 PR-104 和 PR-104A 在人、比格犬、Sprague-Dawley 大鼠和 CD-1 裸鼠静脉内（i.v.）给药后以及小鼠腹腔内（i.p.）给药后的血浆浓度-时间数据。还研究了 i.v. PR-104A 和 i.p. PR-104 的给药情况。测量了来自每种物种的血浆中的蛋白结合。未结合药物清除率和体积按比例缩放。

结果

两房室模型描述了 PR-104 和 PR-104A 在所有四种物种中的处置情况。PR-104 通过中央室中一级（小鼠、大鼠、狗）或混合级（人）代谢快速清除，转化为 PR-104A。估计的人 PR104A 的未结合清除率为 211 L/h/70 kg，稳态未结合体积为 105 L/70 kg。狗的未结合 PR-104A 清除率是大鼠的 2.5 倍，是小鼠的 0.78 倍，可能反映了 PR-104A O-葡糖醛酸化的物种差异。

结论

PK 模型表明，狗和人的 PR-104A 清除率与啮齿动物相比更快。剂量限制的骨髓毒性将 PR-104A 在人体内的暴露限制在大约小鼠的 25%。

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一种针对缺氧的前药 PR-104A 的药代动力学模型在人体、犬、大鼠和小鼠中的综合应用预测了清除率和毒性方面的物种差异。

A combined pharmacokinetic model for the hypoxia-targeted prodrug PR-104A in humans, dogs, rats and mice predicts species differences in clearance and toxicity.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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