Research Progress on Animal Models of Sepsis-Related Organ Injury

doi:10.12300/j.issn.1674-5817.2024.087

Abstract

Abstract:

Sepsis is a multi-organ dysfunction syndrome caused by infection and immune dysfunction, with a high mortality rate. It affects multiple important organs such as the heart, lungs, kidneys, liver, and brain. Establishing corresponding animal models of organ dysfunction syndrome is an essential step in clarifying its pathogenesis, researching potential effective drugs, and evaluating the effectiveness and safety of treatment plans. This article first summarizes classic modeling methods for sepsis related organ injury, including the destruction of intestinal barrier tissue integrity and the implantation of pathogens or toxic drugs. The former mainly includes cecal ligation and puncture, ascending colon stent implantation, and cecal ligation incision. The latter is divided into intraperitoneal injection, intravenous injection, and intratracheal administration based on the clinical infection route being simulated. Cecal ligation and puncture and lipopolysaccharide intraperitoneal injection are the most commonly used methods. Secondly, this article summarizes the common modeling methods and evaluation methods for animal models of sepsis-induced cardiomyopathy, acute lung injury, acute kidney injury, acute liver injury, and brain dysfunction. It points out that almost all organ injuries use classic modeling methods, and different organ injury models have additional modifications according to their different pathogenesis. For example, in addition to the classic modeling methods, lipopolysaccharide instillation in the trachea is more effective in modeling acute lung injury as it better simulates lung barrier dysfunction. Cecal ligation and puncture followed by Pseudomonas instillation in the trachea in a secondary challenge model better represents sepsis-induced acute kidney injury. Intraperitoneal injection of galactosamine is a mature modeling method of sepsis-induced acute liver injury. Intracerebral injection of lipopolysaccharide is a feasible model of sepsis-associated encephalopathy. In addition to the different modeling methods, there are differences in the administration time, dosage and experimental time points according to the different experimental purposes. This article reviews the research progress of animal experimental models for sepsis-induced cardiomyopathy, acute lung injury, acute kidney injury, acute liver injury, and brain dysfunction, aiming to provide a reference for the selection of animal experimental models and optimization of experimental design.

Key words: Sepsis, Animal models, Multiple organ dysfunction, Research progress

CLC Number:

R-332

YANG Jiahao,DING Chunlei,QIAN Fenghua,et al. Research Progress on Animal Models of Sepsis-Related Organ Injury[J]. Laboratory Animal and Comparative Medicine, 2024, 44(6): 636-644. DOI: 10.12300/j.issn.1674-5817.2024.087.

Figures/Tables 3

References 49

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方法 Methods	具体技术 Specific techniques	优点 Advantages	局限 Limitations
破坏肠道屏障组织完整性 Disrupting the integrity of intestinal barrier tissue	CLP^[7]	脓毒症造模“金标准”最接近人类脓毒症发病过程；可重复性高；可模拟多菌性感染	手术难度大、死亡率及疾病严重程度难以控制
	CASP^[8]	接近人类脓毒症发病过程；可重复性高；可控制脓毒症严重程度	手术难度大、操作复杂
	CLI^[9]	与CLP模式相同，可持续释放病原体，模拟临床腹腔感染致脓毒症	代谢组学、血流动力学以及免疫反应的研究尚未成熟
植入病原体/毒性药物 Introducing pathogens/ toxic drugs	脂多糖、酵母聚糖、肽聚糖^[13-14]	易操作、低侵入性；可激活宿主免疫系统用于研究脓毒症相关免疫反应	无法模拟脓毒症的多菌性感染
	大肠杆菌、金黄色葡萄球菌、肺炎克雷伯菌^[10-11]	易操作、低侵入性；适用研究宿主对特定病原体的反应机制	无法模拟脓毒症的多菌性感染，有细菌使用的实验室等级要求
	载有病原体的纤维蛋白凝块^[8]	可重复性高；使病原体缓慢释放，造成持久感染而不影响最终死亡率	纤维蛋白凝块制作难度大
	粪便溶液、盲肠匀浆^[15]	易操作、低侵入性；可模拟多菌性感染	免疫反应过于强烈，易导致早期死亡或早期完全康复，浓度难以控制

方法 Methods	具体技术 Specific techniques	优点 Advantages	局限 Limitations
破坏肠道屏障组织完整性 Disrupting the integrity of intestinal barrier tissue	CLP^[7]	脓毒症造模“金标准”最接近人类脓毒症发病过程；可重复性高；可模拟多菌性感染	手术难度大、死亡率及疾病严重程度难以控制
	CASP^[8]	接近人类脓毒症发病过程；可重复性高；可控制脓毒症严重程度	手术难度大、操作复杂
	CLI^[9]	与CLP模式相同，可持续释放病原体，模拟临床腹腔感染致脓毒症	代谢组学、血流动力学以及免疫反应的研究尚未成熟
植入病原体/毒性药物 Introducing pathogens/ toxic drugs	脂多糖、酵母聚糖、肽聚糖^[13-14]	易操作、低侵入性；可激活宿主免疫系统用于研究脓毒症相关免疫反应	无法模拟脓毒症的多菌性感染
	大肠杆菌、金黄色葡萄球菌、肺炎克雷伯菌^[10-11]	易操作、低侵入性；适用研究宿主对特定病原体的反应机制	无法模拟脓毒症的多菌性感染，有细菌使用的实验室等级要求
	载有病原体的纤维蛋白凝块^[8]	可重复性高；使病原体缓慢释放，造成持久感染而不影响最终死亡率	纤维蛋白凝块制作难度大
	粪便溶液、盲肠匀浆^[15]	易操作、低侵入性；可模拟多菌性感染	免疫反应过于强烈，易导致早期死亡或早期完全康复，浓度难以控制

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