前庭刺激对步行和跑步的不同影响。

Differential effects of vestibular stimulation on walking and running.

作者信息

Jahn K, Strupp M, Schneider E, Dieterich M, Brandt T

机构信息

Department of Neurology, Klinikum Grosshadern, Ludwig-Maximilians University, Munich, Germany.

出版信息

Neuroreport. 2000 Jun 5;11(8):1745-8. doi: 10.1097/00001756-200006050-00029.

DOI:10.1097/00001756-200006050-00029

PMID:10852236

Abstract

Prompted by our recent observation that an acute vestibular tone imbalance causes less deviation from the intended path when running than when slowly walking, we examined 10 healthy subjects when walking or running at different step frequencies during galvanic vestibular stimulation. Blindfolded subjects were asked to walk (1 Hz step frequency) or run (3 Hz step frequency) straight ahead toward a previously seen target. The mean gait deviation after 10 s was 6.0 +/- 2.4 degrees at 1 Hz and 2.8 +/- 1.8 degrees at 3 Hz step frequency (n = 10; p < 0.001, paired t-test). In a second experiment walking and running in place were investigated. There was no significant difference in body displacement. Walking and running are highly automated processes based on spinal locomotor generators that are under supraspinal control. We conclude that vestibular input is differentially regulated depending on the locomotion speed and pattern used.

摘要

基于我们最近的观察，即急性前庭张力失衡在跑步时比在慢走时导致的偏离预期路径的偏差更小，我们在电前庭刺激期间，以不同步频行走或跑步时对10名健康受试者进行了检查。蒙眼受试者被要求朝着先前看到的目标直走（步频1Hz）或跑步（步频3Hz）。在1Hz步频时，10秒后的平均步态偏差为6.0±2.4度，在3Hz步频时为2.8±1.8度（n = 10；配对t检验，p < 0.001）。在第二个实验中，研究了原地行走和跑步。身体位移没有显著差异。行走和跑步是基于脊髓运动发生器的高度自动化过程，受脊髓上控制。我们得出结论，前庭输入根据所使用的运动速度和模式受到不同的调节。

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前庭刺激对步行和跑步的不同影响。

Differential effects of vestibular stimulation on walking and running.

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