循环休克重症患者个体化氧合目标的生理基础。

IF 2.8 Q2 CRITICAL CARE MEDICINE
Anne-Aylin Sigg, Vanja Zivkovic, Jan Bartussek, Reto A Schuepbach, Can Ince, Matthias P Hilty
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引用次数: 0

摘要

背景:循环休克是指组织灌注减少,导致供氧不足,无法满足细胞新陈代谢的需求,是一种发病率和死亡率都很高的常见病。快速恢复和恢复充足的组织灌注是治疗的主要目标。为实现这一目标,目前的血液动力学策略侧重于调整整体生理变量,如心输出量(CO)、血红蛋白(Hb)浓度和动脉血氧饱和度(SaO2)。然而,如何确定这些全局变量的最佳目标,从而最好地支持微循环功能,仍然是一项挑战。在选择重症患者的补氧量时,权衡风险和益处尤为困难。本综述评估了向组织输送氧气的生理基础,并概述了相关文献,以强调考虑风险和益处的重要性,并为床边决策提供支持:氧气必须输送到组织中才能进行氧化磷酸化。人体通过不同的机制及时发现缺氧,以维持组织足够的氧饱和度。肺循环对缺氧的主要反应是动脉血管收缩,相比之下,全身循环的调节机制旨在优化组织中的氧气供应。这是通过增加微循环中毛细血管的密度和毛细血管的血细胞比容来实现的,从而提高红细胞向组织扩散氧气的能力。而高氧则与氧自由基的产生有关,会促进细胞死亡:危重病人的临床试验主要集中在比较基于中风量和氧饱和度目标的大循环终点和结果。一些早期研究表明,保守氧合可能会带来益处。最近的试验显示,死亡率、器官功能障碍和无通气天数方面的结果相互矛盾。对不同的 SaO2 或氧分压目标进行比较的经验性研究表明,U 型曲线平衡了补氧的积极和消极作用:为了优化循环性休克重症患者复苏措施的风险效益比,除了 CO 和 Hb 浓度的个体目标外,首要目标还应该是恢复组织灌注和避免高氧。未来,微循环目标的个体化方法将变得越来越重要。要确定最佳目标,还需要进一步的研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The physiological basis for individualized oxygenation targets in critically ill patients with circulatory shock.

Background: Circulatory shock, defined as decreased tissue perfusion, leading to inadequate oxygen delivery to meet cellular metabolic demands, remains a common condition with high morbidity and mortality. Rapid restitution and restoration of adequate tissue perfusion are the main treatment goals. To achieve this, current hemodynamic strategies focus on adjusting global physiological variables such as cardiac output (CO), hemoglobin (Hb) concentration, and arterial hemoglobin oxygen saturation (SaO2). However, it remains a challenge to identify optimal targets for these global variables that best support microcirculatory function. Weighting up the risks and benefits is especially difficult for choosing the amount of oxygen supplementation in critically ill patients. This review assesses the physiological basis for oxygen delivery to the tissue and provides an overview of the relevant literature to emphasize the importance of considering risks and benefits and support decision making at the bedside.

Physiological premises: Oxygen must reach the tissue to enable oxidative phosphorylation. The human body timely detects hypoxia via different mechanisms aiming to maintain adequate tissue oxygenation. In contrast to the pulmonary circulation, where the main response to hypoxia is arteriolar vasoconstriction, the regulatory mechanisms of the systemic circulation aim to optimize oxygen availability in the tissues. This is achieved by increasing the capillary density in the microcirculation and the capillary hematocrit thereby increasing the capacity of oxygen diffusion from the red blood cells to the tissue. Hyperoxia, on the other hand, is associated with oxygen radical production, promoting cell death.

Current state of research: Clinical trials in critically ill patients have primarily focused on comparing macrocirculatory endpoints and outcomes based on stroke volume and oxygenation targets. Some earlier studies have indicated potential benefits of conservative oxygenation. Recent trials show contradictory results regarding mortality, organ dysfunction, and ventilatory-free days. Empirical studies comparing various targets for SaO2, or partial pressure of oxygen indicate a U-shaped curve balancing positive and negative effects of oxygen supplementation.

Conclusion and future directions: To optimize risk-benefit ratio of resuscitation measures in critically ill patients with circulatory shock in addition to individual targets for CO and Hb concentration, a primary aim should be to restore tissue perfusion and avoid hyperoxia. In the future, an individualized approach with microcirculatory targets will become increasingly relevant. Further studies are needed to define optimal targets.

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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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