美罗培南在小鼠和人体内的上皮衬液中的渗透及暴露靶目标的描绘。
Meropenem penetration into epithelial lining fluid in mice and humans and delineation of exposure targets.
机构信息
Ordway Research Institute, Albany, New York 12208, USA.
出版信息
Antimicrob Agents Chemother. 2011 Jul;55(7):3406-12. doi: 10.1128/AAC.01559-10. Epub 2011 May 16.
Abstract
Pseudomonas aeruginosa pneumonia remains a most-difficult-to-treat nosocomial bacterial infection. We used mathematical modeling to identify drug exposure targets for meropenem in the epithelial lining fluid (ELF) of mice with Pseudomonas pneumonia driving substantial [2 to 3 log(10) (CFU/g)] killing and which suppressed resistant subpopulation amplification. We bridged to humans to estimate the frequency with which the largest licensed meropenem dose would achieve these exposure targets. Cell kills of 2 and 3 log(10) (CFU/g) and resistant subpopulation suppression were mediated by achieving time > MIC in ELF of 32%, 50%, and 50%. Substantial variability in meropenem's ability to penetrate into ELF of both mice and humans was observed. Penetration variability and high exposure targets combined to prevent even the largest licensed meropenem dose from achieving the targets at an acceptable frequency. Even a highly potent agent such as meropenem does not adequately suppress resistant subpopulation amplification as single-agent therapy administered at maximal dose and optimal schedule. Combination chemotherapy is likely required in humans if we are to minimize resistance emergence in Pseudomonas aeruginosa pneumonia. This combination needs evaluation both in the murine pneumonia model and in humans.
摘要
铜绿假单胞菌肺炎仍然是最难治疗的医院获得性细菌性感染。我们使用数学模型来确定美罗培南在铜绿假单胞菌肺炎驱动下的上皮衬液(ELF)中的药物暴露靶点,该肺炎导致大量[2 至 3 对数(10)(CFU/g)]杀伤,并抑制耐药亚群扩增。我们与人类联系起来,以估计最大许可的美罗培南剂量达到这些暴露靶点的频率。细胞杀伤 2 和 3 对数(10)(CFU/g)和抑制耐药亚群扩增是通过在 ELF 中实现 MIC 时间>32%、50%和 50%来介导的。在小鼠和人类的 ELF 中,美罗培南穿透能力存在很大的可变性。穿透变异性和高暴露靶点的结合,即使是最大许可的美罗培南剂量,也无法以可接受的频率达到这些目标。即使是像美罗培南这样的高效药物,作为单一药物治疗,以最大剂量和最佳方案给药,也不能充分抑制耐药亚群的扩增。如果我们要最大限度地减少铜绿假单胞菌肺炎中耐药性的出现,那么人类可能需要联合化疗。这种联合治疗需要在小鼠肺炎模型和人类中进行评估。
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