0.1 Hz 的诱导血流振荡可保护人体严重缺血组织的氧合。

IF 3.3 3区医学 Q1 PHYSIOLOGY

Journal of applied physiology Pub Date : 2024-11-01 Epub Date: 2024-09-19 DOI:10.1152/japplphysiol.00438.2024

K Austin Davis, Nasrul A Bhuiyan, Benjamin J McIntyre, Viet Q Dinh, Caroline A Rickards

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引用次数: 0

摘要

动脉压和血流产生 10 秒钟（约 0.1 Hz）的波动或 "振荡"，可在脑血流量减少 15-20% 时减弱脑组织氧合的减少。为了研究 0.1 赫兹血流动力学振荡对严重缺血时组织氧合的影响，我们制定了一个部分肢体缺血方案，目标是使血流量减少 70-80%。我们假设 0.1 Hz 血流动力学振荡将减轻严重缺血时组织氧合的降低。13 名健康人（6 名男性，7 名女性；27.3±4.2 岁）完成了两个实验方案，时间间隔≥48 小时。在这两个条件下，都使用上臂袖带使肱动脉（BA）血流速度比基线下降约 70-80%。在振荡条件（0.1 Hz）下，在前臂缺血期间，每隔 5 秒钟间歇性地给双侧大腿袖带充气和放气，从而诱发 0.1 Hz 的血液动力学振荡。在对照组条件下（0 Hz），大腿袖带处于非活动状态。对 BA 血流、前臂组织氧合（SmO2）和动脉压进行连续测量。不同方案下 BA 血流速度的初始降低幅度完全一致（0 Hz：-76.9±7.9% vs. 0.1 Hz：-75.5±7.4%，p=0.49）。虽然前臂缺血期间的 0.1 Hz 振荡对 BA 速度的降低没有影响（0 Hz：-73.0±9.9% vs. 0.1 Hz：-73.3±8.2%，p=0.91），但 SmO2 的降低有所减弱（0 Hz：-35.7±8.6% vs. 0.1 Hz：-27.2±8.9%；p=0.01）。这些数据进一步证明了 0.1 赫兹血液动力学振荡可作为一种潜在的治疗干预手段，用于治疗与严重组织缺血相关的疾病（如出血和中风）。

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Induced blood flow oscillations at 0.1 Hz protects oxygenation of severely ischemic tissue in humans.

Generating 10-s (∼0.1 Hz) fluctuations or "oscillations" in arterial pressure and blood flow blunts reductions in cerebral tissue oxygenation in response to 15%-20% reductions in cerebral blood flow. To examine the effect of 0.1 Hz hemodynamic oscillations on tissue oxygenation during severe ischemia, we developed a partial limb ischemia protocol targeting a 70%-80% reduction in blood flow. We hypothesized that 0.1 Hz hemodynamic oscillations would attenuate reductions in tissue oxygenation during severe ischemia. Thirteen healthy humans (6 M and 7 F; 27.3 ± 4.2 yr) completed two experimental protocols separated by ≥48 h. In both conditions, an upper arm cuff was used to decrease brachial artery (BA) blood velocity by ∼70%-80% from baseline. In the oscillation condition (0.1 Hz), 0.1 Hz hemodynamic oscillations were induced by intermittently inflating and deflating bilateral thigh cuffs every 5 s during forearm ischemia. In the control condition (0 Hz), the thigh cuffs were inactive. BA blood flow, forearm tissue oxygenation (SmO₂), and arterial pressure were measured continuously. The initial reduction in BA blood velocity was tightly matched between protocols (0 Hz: -76.9 ± 7.9% vs. 0.1 Hz: -75.5 ± 7.4%, P = 0.49). Although 0.1 Hz oscillations during forearm ischemia had no effect on the reduction in BA velocity (0 Hz: -73.0 ± 9.9% vs. 0.1 Hz: -73.3 ± 8.2%, P = 0.91), the reduction in SmO₂ was attenuated (0 Hz: -35.7 ± 8.6% vs. 0.1 Hz: -27.2 ± 8.9%, P = 0.01). These data provide further evidence for the use of 0.1 Hz hemodynamic oscillations as a potential therapeutic intervention for conditions associated with severe tissue ischemia (e.g., hemorrhage and stroke).NEW & NOTEWORTHY We investigated the effects of induced 10-s (0.1 Hz) oscillations in blood flow on forearm tissue oxygenation during severe ischemia. Intermittent inflation of bilateral thigh cuffs was used as a clinically applicable method to drive blood flow oscillations. In support of our hypothesis, 0.1 Hz oscillations in blood flow blunted reductions in forearm tissue oxygenation. These results further support the potential use of oscillatory hemodynamics as a therapeutic intervention for ischemic conditions.

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来源期刊

Journal of applied physiology 医学-生理学

CiteScore

6.00

自引率

9.10%

发文量

296

审稿时长

2-4 weeks

期刊介绍： The Journal of Applied Physiology publishes the highest quality original research and reviews that examine novel adaptive and integrative physiological mechanisms in humans and animals that advance the field. The journal encourages the submission of manuscripts that examine the acute and adaptive responses of various organs, tissues, cells and/or molecular pathways to environmental, physiological and/or pathophysiological stressors. As an applied physiology journal, topics of interest are not limited to a particular organ system. The journal, therefore, considers a wide array of integrative and translational research topics examining the mechanisms involved in disease processes and mitigation strategies, as well as the promotion of health and well-being throughout the lifespan. Priority is given to manuscripts that provide mechanistic insight deemed to exert an impact on the field.