Smith N F, Hayes A, Nutley B P, Raynaud F I, Workman P
Cancer Research UK Centre for Cancer Therapeutics, The Institute of Cancer Research, 15 Cotswold Road, SM2 5NG, Sutton, UK.
Cancer Chemother Pharmacol. 2004 Dec;54(6):475-86. doi: 10.1007/s00280-004-0853-7. Epub 2004 Jul 29.
There is currently much interest in developing analogues of the benzoquinone ansamycin geldanamycin that may overcome the limitations of 17-(allylamino)-17-demethoxygeldanamycin (17AAG), which is the first known inhibitor of heat shock protein 90 (Hsp90) to enter clinical trials. Studies were performed to assess whether cassette dosing, the coadministration of several compounds to a single animal, is a suitable approach to evaluate the preclinical pharmacokinetics of geldanamycin analogues in high throughput.
Five geldanamycin analogues (17AAG, NSC 255110, NSC 682300, NSC 683661, NSC 683663) were administered intravenously to mice in combination at 5 mg/kg each and as single agents at 5 mg/kg and 50 mg/kg, or 12.5 mg/kg for NSC 682300. The compounds were also incubated with mouse liver microsomes individually and in combination at 15 microM each. Quantitative analysis was performed by LC/MS/MS. Plasma and tissue pharmacokinetic parameters were evaluated by non-compartmental analysis. In vitro metabolic stability was assessed by monitoring disappearance of the parent compound.
Of the compounds that were detectable following individual administration at 5 mg/kg, 17AAG and NSC 683661 exhibited nonlinear pharmacokinetics. In addition, the plasma area under the curve (AUC) and the half-life of these compounds was greater following cassette dosing at 5 mg/kg compared to single administration at the same dose. When pharmacokinetic parameters were calculated up to the same time point following cassette and individual administration at the higher dose, three of the compounds displayed non-linear increases in AUC and slower clearances following cassette compared to single compound dosing. When all measurable concentrations at the higher dose were included, the half-life of NSC 683663 was nine-fold longer following individual compared to cassette administration. 17AAG displayed the highest AUC following cassette dosing, whereas NSC 683663 displayed the highest AUC following single-compound dosing. Excluding NSC 683663, the rank order from the highest to the lowest AUC was the same; however, NSC 682300, which ranked fifth, was administered at a four-fold lower individual dose than the other compounds. Exposure of the liver and kidneys to the compounds was greater than that of plasma. Despite being administered at a lower dose, NSC 682300 displayed the highest kidney AUC of the five compounds. The same ranking was maintained between cassette and single compound dosing in the kidney. With the exception of NSC 682300, in vitro metabolic stability was predictive of in vivo pharmacokinetics in the plasma and liver. The extent of metabolism of four of the five compounds was lower following microsomal incubation in combination compared to incubation alone, suggestive of likely drug-drug interaction in the cassette. However, for 17AAG this may be partly due to metabolism of NSC 683661 and NSC 683663 to this compound.
Whilst cassette dosing has advantages for use in drug discovery, it is probably unsuitable to evaluate the pharmacokinetics of geldanamycin analogues due to non-linear pharmacokinetics and drug-drug interaction. The issues identified for this compound series should also be considered in assessing the suitability of cassette dosing for other chemotypes.
目前人们对开发苯醌安莎霉素格尔德霉素的类似物兴趣浓厚,这类类似物可能会克服17 -(烯丙基氨基)- 17 -去甲氧基格尔德霉素(17AAG)的局限性,17AAG是首个进入临床试验的热休克蛋白90(Hsp90)已知抑制剂。开展研究以评估盒式给药(即向单一动物同时给予几种化合物)是否是一种适用于高通量评估格尔德霉素类似物临床前药代动力学的方法。
将五种格尔德霉素类似物(17AAG、NSC 255110、NSC 682300、NSC 683661、NSC 683663)以每千克体重5毫克的剂量联合静脉注射给小鼠,同时也分别以每千克体重5毫克和50毫克的剂量作为单一药物给药,NSC 682300则以每千克体重12.5毫克的剂量给药。这些化合物还分别以及以每种15微摩尔的浓度联合与小鼠肝微粒体进行孵育。通过液相色谱/串联质谱进行定量分析。采用非房室分析评估血浆和组织药代动力学参数。通过监测母体化合物的消失来评估体外代谢稳定性。
在以每千克体重5毫克的剂量单独给药后可检测到的化合物中,17AAG和NSC 683661呈现非线性药代动力学。此外,与相同剂量的单次给药相比,以每千克体重5毫克的剂量进行盒式给药后,这些化合物的血浆曲线下面积(AUC)和半衰期更大。当在较高剂量下盒式给药和单独给药后计算至相同时间点的药代动力学参数时,与单一化合物给药相比,其中三种化合物的AUC呈现非线性增加,且盒式给药后的清除率较慢。当纳入较高剂量下所有可测量浓度时,与盒式给药相比,NSC 683663单独给药后的半衰期长九倍。盒式给药后17AAG的AUC最高,而单一化合物给药后NSC 683663的AUC最高。排除NSC 683663后,从最高到最低AUC的排序相同;然而,排名第五的NSC 682300单独给药剂量是其他化合物的四分之一。肝脏和肾脏对这些化合物的暴露程度高于血浆。尽管NSC 682300给药剂量较低,但在这五种化合物中它在肾脏中的AUC最高。在肾脏中,盒式给药和单一化合物给药之间保持相同的排名。除NSC 682300外,体外代谢稳定性可预测血浆和肝脏中的体内药代动力学。与单独孵育相比,五种化合物中有四种在联合微粒体孵育后的代谢程度较低,这表明在盒式给药中可能存在药物 - 药物相互作用。然而,对于17AAG,这可能部分归因于NSC 683661和NSC 683663代谢生成该化合物。
虽然盒式给药在药物研发中有优势,但由于非线性药代动力学和药物 - 药物相互作用,它可能不适用于评估格尔德霉素类似物的药代动力学。在评估盒式给药对其他化学类型的适用性时,也应考虑该化合物系列中发现的问题。
