Review on advances of monitoring T-cell subsets in septic patients

doi:10.3877/cma.j.issn.2096-1537.2021.01.009

Abstract

Abstract:

Although the understanding of the pathophysiological mechanism of sepsis has significantly improved, the outcome of septic patients remains poor. It is because of the heterogeneity of immune response, complex signaling pathways, the interplay of pro-inflammatory and anti-inflammatory processes and so on. Moreover, immunosuppression in sepsis increases the risk of death. Even survivors often remain a persistent immunosuppression status, which is one of the main reasons for long-term mortality. During pandemic of coronavirus disease 2019(COVID-19), severe COVID-19 patients also meet the diagnostic criteria of sepsis. In different periods of sepsis, there are close correlations between the counts of T cell subsets and immune status, demonstrated by monitoring peripheral helper T cells, regulatory T cells and CD8⁺T cells. The premise of appropriate treatment is to assess the patient's immune status precisely. Therefore, this review focuses on the change of T cell subsets counts, especially in patients with COVID-19, aiming to provide a monitoring indicator for precision immune treatment and improve outcome in sepsis.

Key words: Sepsis, T lymphocyte, Helper T cell, Regulatory T cell, COVID-19

Siye Zhang, Can Hou, Yanjun Zhong, Guobao Wu. Review on advances of monitoring T-cell subsets in septic patients[J]. Chinese Journal of Critical Care & Intensive Care Medicine(Electronic Edition), 2021, 07(01): 48-54.

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References 39

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T细胞亚群相关细胞因子	作用机制及意义
Th1
TNF-α	可激发巨噬细胞吞噬病原体，诱导单核/巨噬细胞和血管内皮细胞分泌细胞因子（IL-1、IL-6等），不仅为重要的促炎因子，而且是自身诱导不可逆休克和死亡的唯一因子；与严重感染的病死率有相关关系
IFN-γ	巨噬细胞活化因子，激活单核/巨噬细胞促进炎症反应；单独升高提示为真菌或胞内菌感染
IL-2	激活T细胞及NK细胞，使其杀伤性增强并分泌炎性因子；有促炎效应，与脓毒症预后相关
Th2
IL-4	抑制单核细胞分泌IL-6及TNF及活性，控制炎症反应；可用于评估感染的严重程度及预后
IL-6	促进B细胞分化和产生抗体，并诱导T细胞活化增殖、分化，参与机体的免疫应答，是炎性反应的促发剂；是感染的早期诊断、脓毒症的严重程度及预后指标
IL-10	炎症和免疫抑制因子，抑制巨噬细胞产生的炎症因子，促进B细胞增殖和抗体的产生；与感染程度成正相关，若明显升高上百甚至数千倍，提示细胞因子风暴，病情常迅速发展
Th17
IL-17	可诱导IL-6、TNF-α等炎性因子及趋化因子的表达，引起炎性细胞的浸润和组织破坏，在多种病原微生物尤其是胞外病原体和真菌感染中起着重要的抗感染作用；可作为较好的炎性预后指标，观察患者病情进展

T细胞亚群相关细胞因子	作用机制及意义
Th1
TNF-α	可激发巨噬细胞吞噬病原体，诱导单核/巨噬细胞和血管内皮细胞分泌细胞因子（IL-1、IL-6等），不仅为重要的促炎因子，而且是自身诱导不可逆休克和死亡的唯一因子；与严重感染的病死率有相关关系
IFN-γ	巨噬细胞活化因子，激活单核/巨噬细胞促进炎症反应；单独升高提示为真菌或胞内菌感染
IL-2	激活T细胞及NK细胞，使其杀伤性增强并分泌炎性因子；有促炎效应，与脓毒症预后相关
Th2
IL-4	抑制单核细胞分泌IL-6及TNF及活性，控制炎症反应；可用于评估感染的严重程度及预后
IL-6	促进B细胞分化和产生抗体，并诱导T细胞活化增殖、分化，参与机体的免疫应答，是炎性反应的促发剂；是感染的早期诊断、脓毒症的严重程度及预后指标
IL-10	炎症和免疫抑制因子，抑制巨噬细胞产生的炎症因子，促进B细胞增殖和抗体的产生；与感染程度成正相关，若明显升高上百甚至数千倍，提示细胞因子风暴，病情常迅速发展
Th17
IL-17	可诱导IL-6、TNF-α等炎性因子及趋化因子的表达，引起炎性细胞的浸润和组织破坏，在多种病原微生物尤其是胞外病原体和真菌感染中起着重要的抗感染作用；可作为较好的炎性预后指标，观察患者病情进展

CD4⁺T细胞亚群	性质	生理作用	生物学功能	变化趋势	临床意义
Th1	促炎	分泌CKs，如：IL-2、IFN-γ、TNF-α	介导细胞免疫，引起迟发型超敏反应	早期：升高	早期：Th2、Th1均升高，形成促炎与抗炎同时存在的炎症激活状态^[24]
				中晚期：升高或与病死率有关，但近期有文献报道其脓毒症中的独立变化趋势无明显统计学差异^[24]
				休克期：可下降	休克期：明显下降提示免疫抑制^[22]
Th2	抑炎	分泌CKs，如：IL-4、5、6、10、13	辅助体液免疫、抗寄生虫感染	早期：迅速、显著升高	早期：Th2、Th1均升高，形成促炎与抗炎同时存在的炎症激活状态
				中晚期：逐渐下降或持续高水平	中晚期：持续高水平Th2往往与不良预后相关
				休克期：可下降	休克期：明显下降提示免疫抑制
Th17	促炎	分泌CKs，如IL-17	抵御细胞外细菌、真菌感染以及自身免疫	早期：升高	早期：提示抗炎反应，但过度的活化会加重组织损伤
				中晚期：逐渐下降或高水平	中晚期：高水平提示更高概率的不良结局^[26]
				休克期：下降/升高	升高表示高度活化的促炎反应而不是更好的保护作用，加重病情
Tregs	抑炎	不同细胞群作用不同，可与受体结合直接作用，也可分泌IL-10或TGF-β	限制感染性疾病组织损伤，但也可增加病原体存活概率，抑制自身免疫疾病的发生发展，控制过敏反应	早期：升高	早期：限制脓毒症早期的促炎反应^[28]
				中晚期：可持续存在	参与免疫抑制，持续存在可降低宿主对继发院内感染的抵抗力^[30]
				休克期：3天内即可升高	进一步加重免疫抑制

CD4⁺T细胞亚群	性质	生理作用	生物学功能	变化趋势	临床意义
Th1	促炎	分泌CKs，如：IL-2、IFN-γ、TNF-α	介导细胞免疫，引起迟发型超敏反应	早期：升高	早期：Th2、Th1均升高，形成促炎与抗炎同时存在的炎症激活状态^[24]
				中晚期：升高或与病死率有关，但近期有文献报道其脓毒症中的独立变化趋势无明显统计学差异^[24]
				休克期：可下降	休克期：明显下降提示免疫抑制^[22]
Th2	抑炎	分泌CKs，如：IL-4、5、6、10、13	辅助体液免疫、抗寄生虫感染	早期：迅速、显著升高	早期：Th2、Th1均升高，形成促炎与抗炎同时存在的炎症激活状态
				中晚期：逐渐下降或持续高水平	中晚期：持续高水平Th2往往与不良预后相关
				休克期：可下降	休克期：明显下降提示免疫抑制
Th17	促炎	分泌CKs，如IL-17	抵御细胞外细菌、真菌感染以及自身免疫	早期：升高	早期：提示抗炎反应，但过度的活化会加重组织损伤
				中晚期：逐渐下降或高水平	中晚期：高水平提示更高概率的不良结局^[26]
				休克期：下降/升高	升高表示高度活化的促炎反应而不是更好的保护作用，加重病情
Tregs	抑炎	不同细胞群作用不同，可与受体结合直接作用，也可分泌IL-10或TGF-β	限制感染性疾病组织损伤，但也可增加病原体存活概率，抑制自身免疫疾病的发生发展，控制过敏反应	早期：升高	早期：限制脓毒症早期的促炎反应^[28]
				中晚期：可持续存在	参与免疫抑制，持续存在可降低宿主对继发院内感染的抵抗力^[30]
				休克期：3天内即可升高	进一步加重免疫抑制

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