Results 261 to 270 of about 41,623 (301)
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Dynamic force responses of skeletal muscle during stretch–shortening cycles
European Journal of Applied Physiology, 2003Muscle damage due to stretch-shortening cycles (i.e., cyclic eccentric/concentric muscle actions) is one of the major concerns in sports and occupational related activities. Mechanical responses of whole muscle have been associated with damage in neural motor units, in connective tissues, and the force generation mechanism.
K B, Geronilla +8 more
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Differences in stretch-shortening cycle and residual force enhancement between muscles
Journal of Biomechanics, 2020It has been suggested that cross bridge kinetics and residual force enhancement (RFE) affect force in the stretch-shortening cycle (SSC). Because cross bridge kinetics and titin isoforms, which are thought to be related to RFE, differ between muscles, the SSC effect may be also muscle-dependent. Thus, we compared the SSC effect between psoas and soleus
Atsuki, Fukutani, Walter, Herzog
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Possibility of Stretch-Shortening Cycle Movement Training Using a Jump Rope
Journal of Strength and Conditioning Research, 2014Although jumping rope has been said to be a typical stretch-shortening cycle movement (SSC) from the dynamic analysis of muscle contraction, there are few research reports that focus on this point. Recently, the function of SSC of the legs with respect to the jumping movement has been evaluated using the rebound jump index (RJ-index).
Kazuyoshi, Miyaguchi +2 more
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Neuromuscular fatigue recovery following rapid and slow stretch–shortening cycle movements
Applied Physiology, Nutrition, and Metabolism, 2012The purpose of this study was to investigate underlying mechanisms and neuromuscular recovery patterns following rapid and slow stretch–shortening cycle (SSC) movements performed to fatigue. Fourteen (10 moderately trained (MT) and four highly trained (HT)) subjects completed rapid and slow SSC movements to fatigue. The rapid SSC movement consisted of
Katie P, Wadden +3 more
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Series elasticity in frog sartorius muscle subjected to stretch-shortening cycles
Journal of Biomechanics, 1990Changes in stiffness during stretch-shortening cycles were studied by applying prestretches of different rates and amplitudes on the tetanized sartorius muscle of the frog and measuring series elastic component characteristics during a subsequent quick release. Series elastic component stiffness was found to be dependent on the mechanical parameters of
G, Lensel-Corbeil, F, Goubel
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Comparison of Methods That Assess Lower-body Stretch-Shortening Cycle Utilization
Journal of Strength and Conditioning Research, 2016The purpose of this study was to compare 4 methods that assess the lower-body stretch-shortening cycle (SSC) utilization of athletes. Eighty-six National Collegiate Athletic Association Division I athletes from 6 different sports performed 2 squat jumps and 2 countermovement jumps on a force platform.
Suchomel, Timothy J. +2 more
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Fatigue During Stretch-Shortening Cycle Exercises
International Journal of Sports Medicine, 1987A. Gollhofer +3 more
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Potentiating Ballistic Limb Movements through Voluntary Production of the Stretch-Shorten Cycle
Perceptual and Motor Skills, 1992The purpose of this study was to examine the effect of learning to produce voluntarily a basic biomechanical mechanism, the stretch-shorten cycle (SSC), on the acceleration of a ballistic arm movement. The task required an elbow flexion at maximal effort performed with the forearm resting upon a horizontal manipulandum.
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