Hypertension restricts leg blood flow and aggravates neuromuscular fatigue during human locomotion in males.

IF 2.2 3区医学 Q3 PHYSIOLOGY American journal of physiology. Regulatory, integrative and comparative physiology Pub Date : 2024-11-01 Epub Date: 2024-08-12 DOI:10.1152/ajpregu.00117.2024

Taylor S Thurston, Joshua C Weavil, Hsuan-Yu Wan, Mark A Supiano, Philip A Kithas, Markus Amann

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Abstract

Patients with hypertension (HTN) are characterized by exaggerated vascular resistance and mean arterial pressure (MAP) and a compromised leg blood flow (Q_L) response to exercise recruiting a small muscle mass. However, the impact of hypertension on peripheral hemodynamics and the development of neuromuscular fatigue during locomotor activities, which critically depends on Q_L, remain unknown. Eight HTN (143 ± 11 mmHg/95 ± 6 mmHg; 45 ± 13 yr) and eight matched (age and activity) controls (120 ± 6 mmHg/77 ± 7 mmHg; CTRL) performed constant-load cycling exercise at 25, 50, and 75 W (for 4 min each) and at 165 ± 41 W (for 5 min). Exercise-induced locomotor muscle fatigue was quantified as the pre- to postexercise change in quadriceps twitch-torque (ΔQ_tw, peripheral fatigue) and voluntary activation (ΔVA%, central fatigue). Q_L (Doppler ultrasound) and leg vascular conductance (LVC) were determined during cycling at 25, 50, and 75 W. Heart rate and ventilatory responses were recorded during all intensities. MAP during exercise was, on average, ∼21 mmHg higher (P = 0.002) and LVC ∼39% lower (P = 0.001) in HTN compared with CTRL. Q_L was consistently between 20 and 30% lower (P = 0.004), and heart rate was significantly higher in HTN. Exercise-induced peripheral (ΔQ_tw: -53 ± 19% vs. -25 ± 23%) and central (ΔVA%: -7 ± 5% vs. -3 ± 2%) fatigue was significantly greater in HTN compared with CTRL. In addition to an exaggerated MAP, LVC and Q_L were lower during exercise in HTN compared with CTRL. Given the critical role of Q_L in determining the development of neuromuscular fatigue, these hemodynamic impairments likely accounted for the faster development of neuromuscular fatigue characterizing hypertensive individuals during locomotor exercise. NEW & NOTEWORTHY The impact of primary hypertension on the cardiovascular and neuromuscular fatigue response to locomotor exercise is unknown. We compared central and peripheral hemodynamics and the development of central and peripheral fatigue during cycling exercise in patients with stage I/II hypertension and age- and activity-matched healthy individuals. In addition to a significantly elevated blood pressure, hypertensive patients were, compared with their nonhypertensive counterparts, also characterized by considerable leg blood flow limitations and impaired neuromuscular fatigue resistance.

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高血压会限制腿部血流并加剧男性运动时的神经肌肉疲劳

高血压（HTN）患者的特点是血管阻力和平均动脉压（MAP）升高，腿部血流（QL）对运动的反应减弱，肌肉质量较小。然而，高血压对外周血流动力学的影响以及运动时神经肌肉疲劳的发展（这主要取决于 QL）仍不为人所知。八名高血压患者（143±11mmHg / 95±6mmHg；45±13岁）和八名匹配（年龄、活动）的对照组（120±6mmHg / 77±7mmHg；CTRL）分别在25、50和75瓦（各4分钟）以及165±41瓦（5分钟）下进行恒定负荷骑车运动。运动诱发的运动肌疲劳被量化为运动前与运动后股四头肌抽动扭矩（∆Qtw，外周疲劳）和自主激活（∆VA%，中枢疲劳）的变化。在 25、50 和 75 瓦的功率下骑车时测定 QL（多普勒超声）和腿部血管传导（LVC）。在所有强度下都记录了心率和呼吸反应。与 CTRL 相比，HTN 运动时的 MAP 平均高出约 21mmHg（P=0.002），LVC 低出约 39%（P=0.001）。高血压患者的 QL 持续降低 20-30%（P=0.004），心率显著升高。与 CTRL 相比，运动引起的外周（∆Qtw：-53±19% vs -25±23%）和中枢（∆VA%：-7±5% vs -3±2%）疲劳在 HTN 中明显增加。与 CTRL 相比，HTN 运动时除了 MAP 增高外，LVC 和 QL 也更低。鉴于 QL 在决定神经肌肉疲劳发展中的关键作用，这些血流动力学损伤可能是高血压患者在运动时神经肌肉疲劳发展较快的原因。

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来源期刊

American journal of physiology. Regulatory, integrative and comparative physiology 医学-生理学

CiteScore

5.30

自引率

3.60%

发文量

145

审稿时长

2 months

期刊介绍： The American Journal of Physiology-Regulatory, Integrative and Comparative Physiology publishes original investigations that illuminate normal or abnormal regulation and integration of physiological mechanisms at all levels of biological organization, ranging from molecules to humans, including clinical investigations. Major areas of emphasis include regulation in genetically modified animals; model organisms; development and tissue plasticity; neurohumoral control of circulation and hypertension; local control of circulation; cardiac and renal integration; thirst and volume, electrolyte homeostasis; glucose homeostasis and energy balance; appetite and obesity; inflammation and cytokines; integrative physiology of pregnancy-parturition-lactation; and thermoregulation and adaptations to exercise and environmental stress.