Hypertension Restricts Leg Blood Flow and Aggravates Neuromuscular Fatigue during Human Locomotion in Males.

Abstract

Patients with hypertension (HTN) are characterized by exaggerated vascular resistance and mean arterial pressure (MAP), and a compromised leg blood flow (QL) 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 QL, remain unknown. Eight HTN (143±11mmHg / 95±6mmHg; 45±13years) and 8 matched (age, activity) controls (120±6mmHg / 77±7mmHg; CTRL) performed constant-load cycling exercise at 25, 50, and 75W (for 4-min each), and at 165±41W (for 5-min). Exercise-induced locomotor muscle fatigue was quantified as the pre- to post-exercise change in quadriceps twitch-torque (∆Qtw, peripheral fatigue) and voluntary activation (∆VA%, central fatigue). QL (Doppler-ultrasound) and leg vascular conductance (LVC) were determined during cycling at 25, 50, and 75W. Heart Rate and ventilatory responses were recorded during all intensities. MAP during exercise was, on average, ~21mmHg higher (P=0.002) and LVC ~39% lower (P=0.001) in HTN compared to CTRL. QL was consistently between 20-30% lower (P=0.004) and heart rate was significantly higher in HTN. Exercise-induced peripheral (∆Qtw: -53±19% vs -25±23%) and central (∆VA%: -7±5% vs -3±2%) fatigue were significantly greater in HTN compared to CTRL. In addition to an exaggerated MAP, LVC and QL were lower during exercise in HTN compared to CTRL. Given the critical role of QL 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.