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Int J Sports Med 2016; 37(04): 288-294
DOI: 10.1055/s-0035-1559787
DOI: 10.1055/s-0035-1559787
Training & Testing
Effects of Stable and Unstable Resistance Training in an Altered-G Environment on Muscle Power
Further Information
Publication History
accepted after revision 05 August 2015
Publication Date:
14 December 2015 (online)
Abstract
The study evaluated the effect of 4 weeks of combined resistance-balance training and resistance training alone in a 90° tilted environment on muscle power. Two groups of healthy young subjects performed leg extensions while in a supine position, either on a firm surface along a linear track or on an unstable surface requiring mediolateral balancing movements. Power and force during squats were measured at isokinetic velocities of 10 and 35 deg/s. Results showed significantly greater gains in peak force (44.1%; F1,21=8.876, p=0.026), mean force (58.6%; F1,21=16.136, p=0.013), peak power (58.7%; F1,21=18.754, p=0.009), and mean power (59.2%; F1,21=23.114, p=0.007) at the velocity of 35 deg/s after stable than unstable resistance training. However, there were no significant between-groups differences in pre-post training gains in peak force (10.4%; F1,21=1.965, p=0.74), mean force (10.3%; F1,21=1.889, p=0.80), peak power (12.9%; F1,21=2.980, p=0.49), and mean power (19.1%; F1,21=3.454, p=0.36) during squats at the velocity of 10 deg/s. Resistance exercises under stable conditions performed in a 90° tilted environment are more effective in the improvement of high velocity muscle power than their use in combination with balance exercises. Such training may be applicable in pre- and in-flight exercise regimens for astronauts and in functional rehabilitation of bed-ridden patients.
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