Ergogenic effects of spinal cord stimulation on exercise performance following spinal cord injury

IF 3.2 3区医学 Q2 NEUROSCIENCES

Frontiers in Neuroscience Pub Date : 2024-08-29 DOI:10.3389/fnins.2024.1435716

Daniel D. Hodgkiss, Alison M. M. Williams, Claire S. Shackleton, Soshi Samejima, Shane J. T. Balthazaar, Tania Lam, Andrei V. Krassioukov, Tom E. Nightingale

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引用次数: 0

Abstract

Cervical or upper-thoracic spinal cord injury (SCI, ≥T6) often leads to low resting blood pressure (BP) and impaired cardiovascular responses to acute exercise due to disrupted supraspinal sympathetic drive. Epidural spinal cord stimulation (invasive, ESCS) and transcutaneous spinal cord stimulation (non-invasive, TSCS) have previously been used to target dormant sympathetic circuits and modulate cardiovascular responses. This case series compared the effects of cardiovascular-optimised ESCS and TSCS versus sham ESCS and TSCS on modulating cardiovascular responses and improving submaximal upper-body exercise performance in individuals with SCI. Seven males with a chronic, motor-complete SCI between C6 and T4 underwent a mapping session to identify cardiovascular responses to spinal cord stimulation. Subsequently, four participants (two ESCS and two TSCS) completed submaximal exercise testing. Stimulation parameters (waveform, frequency, intensity, epidural electrode array configuration, and transcutaneous electrode locations in the lumbosacral region) were optimised to elevate cardiovascular responses (CV-SCS). A sham condition (SHAM-SCS) served as a comparison. Participants performed arm-crank exercise to exhaustion at a fixed workload corresponding to above ventilatory threshold, on separate days, with CV-SCS or SHAM-SCS. At rest, CV-SCS increased BP and predicted left ventricular cardiac contractility and total peripheral resistance. During exercise, CV-SCS increased time to exhaustion and peak oxygen pulse (a surrogate for stroke volume), relative to SHAM-SCS. Ratings of perceived exertion also tended to be lower with CV-SCS than SHAM-SCS. Comparable improvements in time to exhaustion with ESCS and TSCS suggest that both approaches could be promising ergogenic aids to support exercise performance or rehabilitation, along with reducing fatigue during activities of daily living in individuals with SCI.

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脊髓刺激对脊髓损伤后运动表现的促进作用

颈椎或上胸椎脊髓损伤（SCI，≥T6）通常会导致静息血压（BP）偏低，并因脊髓上交感神经驱动力紊乱而影响心血管对急性运动的反应。硬膜外脊髓刺激（侵入性，ESCS）和经皮脊髓刺激（非侵入性，TSCS）曾被用于针对休眠交感神经回路和调节心血管反应。本病例系列比较了心血管优化的 ESCS 和 TSCS 与假 ESCS 和 TSCS 对调节心血管反应和改善 SCI 患者亚极限上肢运动表现的效果。七名男性脊髓损伤患者在C6和T4之间患有慢性完全运动性脊髓损伤，他们接受了映射治疗，以确定心血管对脊髓刺激的反应。随后，四名参与者（两名 ESCS 和两名 TSCS）完成了亚极限运动测试。对刺激参数（波形、频率、强度、硬膜外电极阵列配置和腰骶部经皮电极位置）进行了优化，以提高心血管反应（CV-SCS）。假条件（SHAM-SCS）作为对比。参与者在不同的日子里，分别在 CV-SCS 或 SHAM-SCS 条件下，以高于通气阈值的固定工作量进行曲臂运动，直至筋疲力尽。静息时，CV-SCS 可增加血压，预测左心室心脏收缩力和总外周阻力。与 SHAM-SCS 相比，在运动过程中，CV-SCS 增加了力竭时间和氧脉搏峰值（每搏量的代用指标）。与 SHAM-SCS 相比，CV-SCS 的体力感觉评分也更低。ESCS 和 TSCS 对力竭时间的改善效果相当，这表明这两种方法都是很有前途的人体工程学辅助方法，可用于支持运动表现或康复，以及减轻 SCI 患者在日常生活活动中的疲劳。

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来源期刊

Frontiers in Neuroscience NEUROSCIENCES-

CiteScore

6.20

自引率

4.70%

发文量

2070

审稿时长

14 weeks

期刊介绍： Neural Technology is devoted to the convergence between neurobiology and quantum-, nano- and micro-sciences. In our vision, this interdisciplinary approach should go beyond the technological development of sophisticated methods and should contribute in generating a genuine change in our discipline.