Keywords
Sarcopenia
Systematic review
Mechanism
Clinical practice
Submitted : 2025-03-29
Accepted : 2025-04-13
Published : 2025-04-28
Abstract
Centrifugal contraction training has emerged as a powerful technique in sports rehabilitation, gaining attention for its ability to enhance muscle strength and promote recovery from various injuries. Unlike concentric contraction, which involves muscle shortening, eccentric contraction involves muscle lengthening under tension, leading to distinct physiological adaptations. This paper explores the physiological mechanisms underlying centrifugal contraction training, including its effects on muscle fibers, strength, and endurance. It also examines the neural adaptations triggered by eccentric training, such as increased motor unit recruitment and muscle fiber activation.
References
Proske U, Morgan DL, 2001, Muscle Damage from Eccentric Exercise: Mechanism, Mechanical Signs, Adaptation and Clinical Applications. The Journal of Physiology, 537(2): 333–345.
Hyldahl RD, Chen TC, Nosaka K, 2017, Mechanisms and Mediators of the Skeletal Muscle Repeated Bout Effect. Exercise and Sport Sciences Reviews, 45(1): 24–33.
Moore DR, Tang JE, Burd NA, et al., 2009, Differential Stimulation of Myofibrillar and Sarcoplasmic Protein Synthesis with Protein Ingestion at Rest and After Resistance Exercise. The Journal of Physiology, 587(4): 897–904.
Murphy RM, Watt MJ, Febbraio MA, 2020, Metabolic Communication during Exercise. Nature Metabolism, 2(9): 805–816.
Franchi MV, Atherton PJ, Reeves ND, et al., 2014, Architectural, Functional and Molecular Responses to Concentric and Eccentric Loading in Human Skeletal Muscle. Acta Physiologica, 210(3): 642–654.
Aagaard P, Simonsen EB, Andersen JL, et al., 2000, Neural Inhibition during Maximal Eccentric and Concentric Quadriceps Contraction: Effects of Resistance Training. Journal of Applied Physiology, 89(6): 2249–2257.
Nicol C, Kuitunen S, Kyrolainen H, et al., 2003, Effects of Long- and Short-Term Fatiguing Stretch-Shortening Cycle Exercises on Reflex EMG and Force of the Tendon-Muscle Complex. European Journal of Applied Physiology, 90: 470–479.
Tesch PA, Dudley GA, Duvoisin MR, et al., 1990, Force and EMG Signal Patterns during Repeated Bouts of Concentric or Eccentric Muscle Actions. Acta Physiologica Scandinavica, 138(3): 263–271.
Contractions I, 2011, Excitability at the Motoneuron Pool and Motor Cortex. J Physiol, 589(11): 2901–2916.
Duchateau J, Baudry S, 2014, The Neural Control of Coactivation during Fatiguing Contractions Revisited. Journal of Electromyography and Kinesiology, 24(6): 780–788.
Silbernagel KG, Thomee R, Eriksson BI, et al., 2007, Continued Sports Activity, using a Pain-Monitoring Model, during Rehabilitation in Patients with Achilles Tendinopathy: A Randomized Controlled Study. The American Journal of Sports Medicine, 35(6): 897–906.
Beyer R, Kongsgaard M, Hougs Kjaer B, et al., 2015, Heavy Slow Resistance Versus Eccentric Training as Treatment for Achilles Tendinopathy: A Randomized Controlled Trial. The American Journal of Sports Medicine, 43(7): 1704–1711.
Askling CM, Tengvar M, Thorstensson A, 2013, Acute Hamstring Injuries in Swedish Elite Football: A Prospective Randomized Controlled Clinical Trial Comparing Two Rehabilitation Protocols. British Journal of Sports Medicine, 47(15): 953–959.
Sandhu JS, Mahajan S, Shenoy S, 2008, An Electromyographic Analysis of Shoulder Muscle Activation during Push-Up Variations on Stable and Labile Surfaces. International Journal of Shoulder Surgery, 2(2): 30.