Mechanisms of enhanced force production in lengthening (eccentric) muscle contractions.
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Insights into the neural control of eccentric contractionsFrom Tusko to Titin: the role for comparative physiology in an era of molecular discoverySex differences in human fatigability: mechanisms and insight to physiological responsesSkeletal Muscle Remodeling in Response to Eccentric vs. Concentric Loading: Morphological, Molecular, and Metabolic AdaptationsOxygen consumption of gastrocnemius medialis muscle during submaximal voluntary isometric contractions with and without preceding stretch.A novel three-filament model of force generation in eccentric contraction of skeletal muscles.A new experimental model for force enhancement: steady-state and transient observations of the Drosophila jump muscleReduced activation in isometric muscle action after lengthening contractions is not accompanied by reduced performance fatigability.Physiological Mechanisms of Eccentric Contraction and Its Applications: A Role for the Giant Titin Protein.Residual force enhancement following shortening is speed-dependent.A new paradigm for muscle contraction.Back to the future! Revisiting the physiological cost of negative work as a team-based activity for exercise physiology students.Residual Force Enhancement Following Eccentric Contractions: A New Mechanism Involving Titin.Eccentric Exercise: Physiological Characteristics and Acute Responses.Time-Course of Neuromuscular Changes during and after Maximal Eccentric Contractions.Shortening-induced force depression is modulated in a time- and speed-dependent manner following a stretch-shortening cycle.Skeletal muscle mechanics: questions, problems and possible solutions.Why muscle is an efficient shock absorber.The stretch-shortening cycle (SSC) revisited: residual force enhancement contributes to increased performance during fast SSCs of human m. adductor pollicis.Force depression following a stretch-shortening cycle is independent of stretch peak force and work performed during shortening.Effects of a titin mutation on negative work during stretch-shortening cycles in skeletal muscles.Early detection of exercise-induced muscle damage using elastography.Factors contributing to lower metabolic demand of eccentric compared with concentric cycling.The multiple roles of titin in muscle contraction and force production.Specific joint angle dependency of voluntary activation during eccentric knee extensions.Analysis of concentric and eccentric contractions in biceps brachii muscles using surface electromyography signals and multifractal analysis.Contribution of muscle short-range stiffness to initial changes in joint kinetics and kinematics during perturbations to standing balance: A simulation study.Control of the extension–flexion cycle of human knees during bicycle riding by a synergy of solitary muscular excitations and contractionsTime-course effect of exercise-induced muscle damage on localized muscle mechanical properties assessed using elastographyBasic science and clinical use of eccentric contractions: History and uncertaintiesThe mysteries of eccentric muscle actionWhy are muscles strong, and why do they require little energy in eccentric action?
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Mechanisms of enhanced force production in lengthening (eccentric) muscle contractions.
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Mechanisms of enhanced force production in lengthening (eccentric) muscle contractions.
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Mechanisms of enhanced force production in lengthening (eccentric) muscle contractions.
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Mechanisms of enhanced force production in lengthening (eccentric) muscle contractions.
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P1476
Mechanisms of enhanced force production in lengthening (eccentric) muscle contractions
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P2093
Walter Herzog
P304
P356
10.1152/JAPPLPHYSIOL.00069.2013
P407
P577
2013-02-21T00:00:00Z