The purpose of this study was to examine the acute effect of indirect vibration on neuromuscular responses and fatigue resistance (electromyographic activity - EMG and force) during isometric exercise. Nineteen healthy men (age=22.4±2.7years; body mass=76.4±12.9kg, height=175±6.7cm) performed isometric elbow flexion exercises in three experimental treatments: only isometric exercise (control - CON); isometric exercise with the addition of sinusoidal vibrations (SVE1; frequency=20Hz, displacement=3.55±0.54mm); and isometric exercise with the addition of sinusoidal vibrations with frequency variation (SVE2; frequency=20±3Hz, displacement=3.6±0.8mm). The peak of the rate of EMG rise (RER) and the root mean square of biceps brachii during the first 200ms (RMS200bic) were significantly higher in SVE1 (RMS200bic, 25.57±11.70%MVC; RER, 266.91±130.16%MVCs-1) than CON (RMS200bic, 19.31±8.19%MVC; RER, 169.15±65.98%MVCs-1). Regarding force, in SVE1, compared to CON, significant increases were observed in peak of rate of force development (CON, 643.96±192.57N/s; SVE1, 845.54±292.84N/s), rate of force development in the first 200ms (CON, 382.92±138,63N/s; SVE1, 501.09±147.46N/s), and impulse in 200ms (CON, 8.56±3.56Ns; SVE1, 11.67±4.45Ns). The addition of indirect sinusoidal vibrations during exercise induced increases in the rate of force development (explosive strength), without affecting the peak force (maximal strength) and the ability to sustain strength production.

J Electromyogr Kinesiol. 2017 Jun 14;35:76-85. Indirect sinusoidal vibrations induces an acute increase in explosive strength.