线粒体功能评估及其在败血症中的预后作用:文献综述。

IF 2.8 Q2 CRITICAL CARE MEDICINE
Wagner Nedel, Nathan Ryzewski Strogulski, Afonso Kopczynski, Luis Valmor Portela
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引用次数: 0

摘要

败血症的特点是全身炎症反应失调和过度,并伴有血管和代谢异常,最终导致器官功能障碍。在免疫细胞中,非氧化和氧化代谢率与炎症反应密切相关。线粒体通过利用代谢底物和耗氧合成 ATP,在支持这些细胞过程中发挥着核心作用。为了满足不断变化的细胞需求,线粒体必须在生物能容量、生物生成、融合和裂变的基础上表现出适应性可塑性。鉴于线粒体是各种细胞功能的枢纽,脓毒症诱导的线粒体改变可能会对病理生理学产生重大影响,并对临床结果产生影响。患者的线粒体 DNA 浓度、蛋白质表达水平和生物能谱可通过组织活检或分离的外周血细胞获得。在临床上,单核细胞和淋巴细胞是评估线粒体功能的理想基质。这些单核细胞具有高度氧化性,富含线粒体,可在血液中进行常规监测,易于收集和处理,并显示出与免疫状态的临床联系。因此,免疫细胞中的线粒体评估可作为生物标志物,用于评估败血症患者的临床恢复、免疫代谢状态以及对氧气和血管加压疗法的反应。这些特点突出表明,组织和免疫细胞中的线粒体参数是探索潜在机制和监测重症监护环境中脓毒症患者的实用工具。在本文中,我们将探讨病理生理学方面的问题、测量线粒体功能的主要方法以及该领域的重要研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Assessment of mitochondrial function and its prognostic role in sepsis: a literature review.

Sepsis is characterized by a dysregulated and excessive systemic inflammatory response to infection, associated with vascular and metabolic abnormalities that ultimately lead to organ dysfunction. In immune cells, both non-oxidative and oxidative metabolic rates are closely linked to inflammatory responses. Mitochondria play a central role in supporting these cellular processes by utilizing metabolic substrates and synthesizing ATP through oxygen consumption. To meet fluctuating cellular demands, mitochondria must exhibit adaptive plasticity underlying bioenergetic capacity, biogenesis, fusion, and fission. Given their role as a hub for various cellular functions, mitochondrial alterations induced by sepsis may hold significant pathophysiological implications and impact on clinical outcomes. In patients, mitochondrial DNA concentration, protein expression levels, and bioenergetic profiles can be accessed via tissue biopsies or isolated peripheral blood cells. Clinically, monocytes and lymphocytes serve as promising matrices for evaluating mitochondrial function. These mononuclear cells are highly oxidative, mitochondria-rich, routinely monitored in blood, easy to collect and process, and show a clinical association with immune status. Hence, mitochondrial assessments in immune cells could serve as biomarkers for clinical recovery, immunometabolic status, and responsiveness to oxygen and vasopressor therapies in sepsis. These characteristics underscore mitochondrial parameters in both tissues and immune cells as practical tools for exploring underlying mechanisms and monitoring septic patients in intensive care settings. In this article, we examine pathophysiological aspects, key methods for measuring mitochondrial function, and prominent studies in this field.

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来源期刊
Intensive Care Medicine Experimental
Intensive Care Medicine Experimental CRITICAL CARE MEDICINE-
CiteScore
5.10
自引率
2.90%
发文量
48
审稿时长
13 weeks
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