Yang Xiao-Xia, Hu Ze-Ping, Chan Sui Yung, Duan Wei, Ho Paul Chi-Liu, Boelsterli Urs Alex, Ng Ka-Yun, Chan Eli, Bian Jin-Song, Chen Yu-Zong, Huang Min, Zhou Shu-Feng
Department of Pharmacy, Faculty of Science, National University of Singapore, Science Drive 4, Singapore 117543, Singapore.
Curr Drug Metab. 2006 May;7(4):431-55. doi: 10.2174/138920006776873517.
The clinical use of irinotecan (CPT-11) is hindered by dose-limiting diarrhea and myelosuppression. Recent clinical studies indicate that thalidomide, a known tumor necrosis factor-alpha inhibitor, ameliorated the toxicities induced by CPT-11. However, the mechanisms for this are unknown. This study aimed to investigate whether combination of thalidomide modulated the toxicities of CPT-11 using a rat model and the possible role of the altered pharmacokinetic component in the toxicity modulation using in vitro models. The toxicity model was constructed by treatment of healthy rats with CPT-11 at 60 mg/kg per day by intravenous (i.v.) injection. Body weight, acute and delayed-onset diarrhea, blood cell counts, and macroscopic and microscopic intestinal damages were monitored in rats treated with CPT-11 alone or combined therapy with thalidomide at 100 mg/kg administered by intraperitoneal (i.p.) injection. Single dose and 5-day multiple-dose studies were conducted in rats to examine the effects of concomitant thalidomide on the plasma pharmacokinetics of CPT-11 and its major metabolites SN-38 and SN-38 glucuronide (SN-38G). The effect of CPT-11 on thalidomide's pharmacokinetics was also checked. Rat liver microsomes and a rat hepatoma cell line, H4-II-E cells, were used to study the in vitro metabolic interactions between these two drugs. H4-II-E cells were also used to investigate the effect of thalidomide and its hydrolytic products on the transport of CPT-11 and SN-38. In addition, the effect of thalidomide and its hydrolytic products on rat plasma protein binding of CPT-11 and SN-38 was examined. Administration of CPT-11 by i.v. for 4 consecutive days to rats induced significant body weight loss, decrease in neutrophil and lymphocyte counts, severe acute- and delayed-onset diarrhea, and intestinal damages. These toxicities were alleviated when CPT-11 was combined with thalidomide. In both single-dose and 5-day multiple-dose pharmacokinetic study, coadministered thalidomide significantly increased the area under the plasma concentration-time curve (AUC) of CPT-11, but the AUC and elimination half-life (t(1/2)) of SN-38 were significantly decreased. However, CPT-11 did not significantly alter the pharmacokinetics of thalidomide. Thalidomide at 25 and 250 microM and its hydrolytic products at a total concentration of 10 microM had no significant effect on the plasma protein binding of CPT-11 and SN-38, except for that thalidomide at 250 microM caused a significant increase in the unbound fraction (f(u)) of CPT-11 by 6.7% (P < 0.05). The hydrolytic products of thalidomide (total concentration of 10 microM), but not thalidomide, significantly decreased CPT-11 hydrolysis by 16% in rat liver microsomes (P < 0.01). The formation of both SN-38 and SN-38G from CPT-11, SN-38 glucuronidation, or intracellular accumulation of both CPT-11 and SN-38 in H4-II-E cells followed Michaelis-Menten kinetics with the one-binding site model being the best fit for the kinetic data. Coincubation or 2-hr preincubation of thalidomide at 25 microM and 250 microM and its hydrolytic products at 10 microM did not show any significant effects on CPT-11 hydrolysis and SN-38 glucuronidation. However, preincubation of H4-II-E cells with thalidomide (250 microM), its hydrolytic products (total concentration of 10 microM), or phthaloyl glutamic acid (one major thalidomide hydrolytic product, 10 microM) significantly increased the intracellular accumulation of SN-38, but not CPT-11 (P < 0.01). The dose-limiting toxicities of CPT-11 were alleviated by combination with thalidomide in rats and the pharmacokinetic modulation by thalidomide may partially explain its antagonizing effects on the toxicities of CPT-11. The hydrolytic products of thalidomide, instead of the parental drug, modulated the hepatic hydrolysis of CPT-11 and intracellular accumulation of SN-38, probably contributing to the altered plasma pharmacokinetics of CPT-11 and SN-38. Further studies are needed to explore the role of both pharmacokinetics and pharmacodynamic components in the protective effect of thalidomide against the toxicities of CPT-11.
伊立替康(CPT-11)的临床应用受到剂量限制性腹泻和骨髓抑制的阻碍。最近的临床研究表明,沙利度胺作为一种已知的肿瘤坏死因子-α抑制剂,可改善CPT-11诱导的毒性。然而,其机制尚不清楚。本研究旨在使用大鼠模型研究沙利度胺联合用药是否能调节CPT-11的毒性,并使用体外模型探讨药代动力学成分改变在毒性调节中的可能作用。通过每天以60mg/kg的剂量静脉注射CPT-11处理健康大鼠来构建毒性模型。监测单独接受CPT-11治疗或联合腹腔注射100mg/kg沙利度胺治疗的大鼠的体重、急性和迟发性腹泻、血细胞计数以及大体和显微镜下的肠道损伤。在大鼠中进行单剂量和5天多剂量研究,以检查同时使用沙利度胺对CPT-11及其主要代谢产物SN-38和SN-38葡萄糖醛酸苷(SN-38G)血浆药代动力学的影响。还检查了CPT-11对沙利度胺药代动力学的影响。使用大鼠肝微粒体和大鼠肝癌细胞系H4-II-E细胞研究这两种药物之间的体外代谢相互作用。H4-II-E细胞还用于研究沙利度胺及其水解产物对CPT-11和SN-38转运的影响。此外,检查了沙利度胺及其水解产物对CPT-11和SN-38大鼠血浆蛋白结合的影响。连续4天对大鼠静脉注射CPT-11会导致体重显著减轻、中性粒细胞和淋巴细胞计数减少、严重的急性和迟发性腹泻以及肠道损伤。当CPT-11与沙利度胺联合使用时,这些毒性得到缓解。在单剂量和5天多剂量药代动力学研究中,同时给予沙利度胺均显著增加了CPT-11的血浆浓度-时间曲线下面积(AUC),但SN-38的AUC和消除半衰期(t(1/2))显著降低。然而,CPT-11并未显著改变沙利度胺的药代动力学。25μM和250μM的沙利度胺及其总浓度为10μM的水解产物对CPT-11和SN-38的血浆蛋白结合没有显著影响,除了250μM的沙利度胺使CPT-11的未结合分数(f(u))显著增加6.7%(P<0.05)。沙利度胺的水解产物(总浓度为10μM)而非沙利度胺本身,使大鼠肝微粒体中CPT-11的水解显著降低16%(P<0.01)。CPT-11生成SN-38和SN-38G、SN-38葡萄糖醛酸化或CPT-11和SN-38在H4-II-E细胞中的细胞内积累均遵循米氏动力学,单结合位点模型最适合该动力学数据。25μM和250μM的沙利度胺及其10μM的水解产物共同孵育或预孵育2小时对CPT-11水解和SN-38葡萄糖醛酸化均无显著影响。然而,用沙利度胺(250μM)、其水解产物(总浓度为10μM)或邻苯二甲酰谷氨酸(一种主要的沙利度胺水解产物,10μM)预孵育H4-II-E细胞可显著增加SN-38的细胞内积累,但对CPT-11无影响(P<0.01)。在大鼠中,CPT-11与沙利度胺联合使用可减轻其剂量限制性毒性,沙利度胺的药代动力学调节可能部分解释了其对CPT-11毒性的拮抗作用。沙利度胺的水解产物而非母体药物调节了CPT-11的肝脏水解和SN-38的细胞内积累,这可能导致了CPT-11和SN-38血浆药代动力学的改变。需要进一步研究来探讨药代动力学和药效学成分在沙利度胺对CPT-11毒性的保护作用中的作用。
