Humes H David, Buffington Deborah A, Lou Liandi, Abrishami Simin, Wang Min, Xia Jun, Fissell William H
Department of Internal Medicine, University of Michigan Medical Center, Ann Arbor 48109-0726, USA.
Crit Care Med. 2003 Oct;31(10):2421-8. doi: 10.1097/01.CCM.0000089644.70597.C1.
Gram-negative septic shock has a clinical mortality rate approaching 50%. The cause of death is secondary to a systemic inflammatory response syndrome with resulting cardiovascular collapse, ischemic damage to vital organs, and multiple-organ systems failure. Renal tubule cell injury occurs early in septic shock but is not clinically appreciated. Since renal tubule cells appear to play a critical role in the immunoregulation of stress states, renal cell therapy during septic shock may alter the detrimental multiple-organ consequences of systemic Gram-negative infection. The development of a tissue-engineered bioartificial kidney consisting of a conventional hemofiltration cartridge in series with a renal tubule assist device (RAD) containing 109 renal proximal tubule cells may be a new therapeutic approach to this clinical disorder.
Laboratory study.
University medical school.
Pigs weighing 30-35 kg.
To assess the effect of the bioartificial kidney and the RAD in septic shock, pigs were administered 30 x 10(10) bacteria/kg body weight of Escherichia coli into the peritoneal cavity and within 1 hr were immediately placed in a continuous venovenous hemofiltration extracorporeal circuit with either a sham RAD without cells or a RAD with cells.
In this animal model, septic shock resulted within hours in acute tubule necrosis in the kidneys of all animals. Renal cell therapy resulted in significantly higher cardiac outputs and renal blood flow rates in treated animals compared with sham controls. RAD treatment also was associated with significantly lower plasma circulating concentrations of interleukin-6 and interferon-gamma compared with sham-treated animals. IL-6 release rates from peripheral blood mononuclear cells isolated from RAD-treated animals were significantly higher after endotoxin stimulation than those isolated from control animals. These physiologic and molecular alterations were associated with nearly a doubling of the average survival time in the RAD-treated group compared with the sham control group.
These results demonstrate that renal cell therapy ameliorates cardiac and vascular dysfunction, alters systemic cytokine abnormalities, and improves survival time in a large animal model of Gram-negative septic shock. A cell therapeutic approach with a tissue-engineered bioartificial kidney may be a new treatment modality for this current unmet medical need.
革兰氏阴性菌败血症性休克的临床死亡率接近50%。死亡原因继发于全身炎症反应综合征,导致心血管衰竭、重要器官缺血性损伤和多器官系统功能衰竭。肾小管细胞损伤在败血症性休克早期就会发生,但在临床上未被重视。由于肾小管细胞似乎在应激状态的免疫调节中起关键作用,败血症性休克期间的肾细胞治疗可能会改变全身性革兰氏阴性菌感染对多个器官的有害影响。开发一种组织工程化生物人工肾,它由一个传统的血液滤过器与一个含有109个肾近端小管细胞的肾小管辅助装置(RAD)串联组成,可能是治疗这种临床疾病的一种新方法。
实验室研究。
大学医学院。
体重30 - 35千克的猪。
为评估生物人工肾和RAD在败血症性休克中的作用,给猪腹腔内注射30×10(10)个/千克体重的大肠杆菌,1小时内立即将其置于连续静脉 - 静脉血液滤过体外循环中,分别连接无细胞的假RAD或有细胞的RAD。
在这个动物模型中,所有动物在数小时内均因败血症性休克导致急性肾小管坏死。与假手术对照组相比,肾细胞治疗使治疗组动物的心输出量和肾血流量显著增加。与假手术治疗的动物相比,RAD治疗还使血浆中白细胞介素 - 6和干扰素 - γ的循环浓度显著降低。内毒素刺激后,从RAD治疗动物分离的外周血单核细胞的IL - 6释放率明显高于从对照动物分离的细胞。这些生理和分子改变与RAD治疗组的平均存活时间相比假手术对照组几乎翻倍有关。
这些结果表明,在革兰氏阴性菌败血症性休克的大型动物模型中,肾细胞治疗可改善心脏和血管功能障碍,改变全身细胞因子异常,并延长存活时间。采用组织工程化生物人工肾的细胞治疗方法可能是满足当前这一未满足医疗需求的一种新治疗方式。
