斜坡-递增循环至不耐受时运动神经肌肉疲劳的动态变化。

IF 4.1 2区医学 Q1 SPORT SCIENCES Medicine and Science in Sports and Exercise Pub Date : 2025-04-01 Epub Date: 2024-03-11 DOI:10.1249/MSS.0000000000003414

Molly M Baldwin, Matt R Chadwick, Alan P Benson, Harry B Rossiter, Carrie Ferguson

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引用次数: 0

摘要

简介传统的神经肌肉疲劳评估没有任务特异性，无法描述动态全身运动中神经肌肉性能下降的特征。本研究使用交错最大等速骑车运动来描述斜坡递增（RI）循环测力运动达到不耐受时神经肌肉性能下降的动态特征：方法：11 名年轻健康的参与者（10 男/女）进行了两次 RI 循环测力锻炼到不耐受的测试：[1] RI-运动，以 80 转/分-1 的峰值等动肌力（Piso）进行基线测量，并在最大约 6 秒的努力达到不耐受时立即进行测量；[2] RI-运动，每隔 90 秒交错进行额外的 Piso 测量，以描述 RI 测试期间神经肌肉性能下降的特征。在所有 Piso 评估过程中，均使用肌电图测量肌肉兴奋性，并在整个过程中测量肺气体交换：结果：基线 Piso 为 832 ± 140 W，在不耐受时，RI 运动将 Piso 降至 349 ± 96 W（p = 0.001），与不耐受时的飞轮功率（303 ± 96 W；p = 0.292）没有差异。在基线骑行和气体交换阈值（GET；基线 Piso 与低于 GET 的平均 Piso 之比）之间，Piso 没有减少：828 ± 146 W vs. 815 ± 149 W；p = 1.00）。Piso 在 GET 以上逐渐下降，直至不耐受（Piso 在 GET 以上每 90 秒下降一次：759 ± 139；684 ± 141；535 ± 144；374 ± 117 W；与基线和低于 GET 的平均 Piso 相比，每个 p < 0.05）。肌肉兴奋峰值（EMG）也只有在 GET 以上才会降低（不耐受时为基线的 73 ± 14 %；p < 0.05）。然而，皮索峰值的降低先于肌肉兴奋峰值的降低：结论：在 RI 运动中，神经肌肉性能下降（Piso 和 EMG 下降）的动态与已知的强度依赖性代谢和传统的离散式恒定功率运动后神经肌肉疲劳反应一致。

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The Dynamics of Locomotor Neuromuscular Fatigue during Ramp-Incremental Cycling to Intolerance.

Introduction: Traditional neuromuscular fatigue assessments are not task-specific and are unable to characterize neuromuscular performance decline during dynamic whole-body exercise. This study used interleaved maximal isokinetic cycling efforts to characterize the dynamics of the decline in neuromuscular performance during ramp-incremental (RI) cycle ergometry exercise to intolerance.

Methods: Eleven young healthy participants (10 male/1 female) performed two RI cycle ergometry exercise tests to intolerance: 1) RI exercise with peak isokinetic power (Piso) at 80 rpm measured at baseline and immediately at intolerance from a maximal ~6 s effort, and 2) RI exercise where additional Piso measurements were interleaved every 90 s to characterize the decline in neuromuscular performance during the RI test. Muscle excitation was measured using EMG during all Piso assessments, and pulmonary gas exchange was measured throughout.

Results: Baseline Piso was 832 ± 140 W and RI exercise reduced Piso to 349 ± 96 W at intolerance ( P = 0.001), which was not different from flywheel power at intolerance (303 ± 96 W; P = 0.292). There was no reduction in Piso between baseline cycling and gas exchange threshold (GET; baseline Piso vs mean Piso below GET: 828 ± 146 vs 815 ± 149 W; P = 1.00). Piso fell progressively above GET until intolerance (Piso every 90 s above GET: 759 ± 139, 684 ± 141, 535 ± 144, 374 ± 117 W; each P < 0.05 vs baseline and mean Piso below GET). Peak muscle excitation (EMG) was also reduced only above GET (73% ± 14% of baseline, at intolerance; P < 0.05). However, the reduction in peak Piso preceded the reduction in peak muscle excitation.

Conclusions: The dynamics of the decline in neuromuscular performance (reduction in Piso and EMG) during RI exercise are consistent with known intensity-dependent metabolic and traditional pre-post neuromuscular fatigue responses to discrete bouts of constant-power exercise.

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来源期刊

Medicine and Science in Sports and Exercise 医学-运动科学

CiteScore

7.70

自引率

4.90%

发文量

2568

审稿时长

1 months

期刊介绍： Medicine & Science in Sports & Exercise® features original investigations, clinical studies, and comprehensive reviews on current topics in sports medicine and exercise science. With this leading multidisciplinary journal, exercise physiologists, physiatrists, physical therapists, team physicians, and athletic trainers get a vital exchange of information from basic and applied science, medicine, education, and allied health fields.