The effect of leg compression garments on the mechanical characteristics and performance of single-leg hopping in healthy male volunteers

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• 作者：Amitabh Gupta ; Joshua John Bryers…
• 关键词：Fatigue ; Vertical stiffness
• 刊名：BMC Sports Science, Medicine and Rehabilitation
• 出版年：2015
• 出版时间：December 2015
• 年：2015
• 卷：7
• 期：1
• 全文大小：390 KB
• 参考文献：1.Agu O, Baker D, Seifalian AM. Effect of graduated compression stockings on limb oxygenation and venous function during exercise in patients with venous insufficiency. Vascular. 2004;12:69-6.View Article PubMed
  2.Eberhardt RT, Raffetto JD. Chronic venous insufficiency. Circulation. 2005;111:2398-09.View Article PubMed
  3.Holavanahalli RK, Helm OA, Parry IS, Dolezal CA, Greenhalgh DG. Select practices in management and rehabilitation of burns: a survey report. J Burn Care Res. 2011;32:210-3.View Article PubMed
  4.Duffield R, Portus M. Comparison of three types of full-body compression garments on throwing and repeat-sprint performance in cricket players. Br J Sports Med. 2007;41:409-4.View Article PubMed Central PubMed
  5.Scanlan AT, Dascombe BJ, Reaburn PR, Osborne M. The effects of wearing lower-body compression garments during endurance cycling. Int J Sports Physiol Perform. 2008;3:424-8.PubMed
  6.Ali A, Caine MP, Snow BG. Graduated compression stockings: physiological and perceptual responses during and after exercise. J Sports Sci. 2007;25:413-.View Article PubMed
  7.Kraemer WJ, Bush JA, Bauer JA, Triplet-McBride NT, Paxton NJ, Clemson A, et al. Influence of compression garments on vertical jump performance in NCAA Division I volleyball players. J Strength Condition Res. 1996;10:180-.
  8.Kemmler W, von Stengel S, K?ckritz C, Mayhew J, Wassermann A, Zapf J. Effect of compression stockings on running performance in men runners. J Strength Condition Res. 2009;23:101-.View Article
  9.Doan BK, Kwon YH, Newton RU, Shim J, Popper EM, Rogers RA, et al. Evaluation of a lower-body compression garment. J Sports Sci. 2003;21:601-0.View Article PubMed
  10.MacRae BA, Cotter JD, Laing MR. Compression garments and exercise. Garment considerations, physiology and performance. Sports Med. 2011;41:815-3.View Article PubMed
  11.Oliver JL, Smith PM. Neural control of leg stiffness during hopping in boys and men. J Electromyogr Kinesiol. 2010;20:973-.View Article PubMed
  12.Bryant AL, Crossley KL, Bartold S, Hohmann E, Clark R. Estrogen induced effects on the neuro-mechanics of hopping in humans. Eur J Appl Physiol. 2011;111:245-2.View Article PubMed
  13.Pruyn EC, Watsford ML, Murphy AJ, Pine MJ, Spurrs RW, Cameron ML, et al. Relationship between leg stiffness and lower body injuries in professional Australian football. J Sports Sci. 2012;30:71-.View Article PubMed
  14.Padua DA, Arnold BL, Perrin DH, Gansneder BM, Carcia CR, Granata KP. Fatigue, vertical leg stiffness, and stiffness control strategies in males and females. J Athletic Training. 2006;41:294-04.
  15.Perrier ET, Pavol MJ, Hoffman MJ. The acute effects of warm-up including static or dynamic stretching on countermovement jump height, reaction time, and flexibility. J Strength Condition Res. 2011;25:1925-1.View Article
  16.Buchheit M, Laursen PB. High-intensity training, solutions to the programming puzzle. Part II: anaerobic energy, neuromuscular load and practical applications. Sports Med. 2013;43:927-4.View Article PubMed
  17.de Salles BF, Sim?o R, Miranda F, Novaes JS, Lemos A, Willardson JM. Rest interval between sets in strength training. Sports Med. 2009;39:765-7.View Article PubMed
  18.Hobara H, Kimura K, Omuro K, Gomi K, Muraoka T, Iso S, et al. Determinants of difference in leg stiffness between endurance- and power-trained athletes. J Biomech. 2008;41:506-4.View Article PubMed
  19.Kraemer WJ, Bush JA, Newton RU, Duncan ND, Volek JS, Denegar CR, et al. Influence of a compression garment on repetitive power output production before and after different tyes of muscle fatigue. Sports Med Train Rehabilitation. 1998;8:163-4.View Article
  20.Law RY, Herbert RD. Warm-up reduces delayed onset muscle soreness but cool-dwon does not: a randomised controlled trial. Australian J Physiotherapy. 2007;53:91-.View Article
  21.Olsen O, Sj?haug M, van Beekvelt M, Mork PJ. The effect of warm-up and cool-down exercise on delayed onset muscle soreness in the quadriceps muscle: a randomised controlled trial. J Human Kinetics. 2012;35:59-8.View Article
  22.Rousanoglow EN, Konstantinos DB. Rhythmic performance during a whole body movement: dynamic analysis of force–time curves. Hum Mov Sci. 2006;25:393-08.View Article
  23.Farley CT, Blickham R, Saito J, Taylor CR. Hopping frequency in humans: a test of how springs set stride frequency in bouncing gaits. J Appl Physiol. 1991;71:2127-2.PubMed
  24.Bonnard M, Sirin AV, Oddsson L, Thorstensson A. Different strategies to compensate for the effects of fatigue revealed by neuromuscular adaptation processes in humans. Neurosci Lett. 1994;166:101-.View Article PubMed
  25.Chang Y-H, Roiz RA, Auyang AG. Intralimb compensation strategy depends on the nature of joint perturbation in human hopping. J Biomech. 2009;41:1832-.View Article
  26.Hobara H, Kanosue K, Suzuki S. Changes in muscle activity with increase in leg stiffness during hopping. Ne
• 作者单位：Amitabh Gupta (1)
  Joshua John Bryers (1)
  Peter James Clothier (1)
  
  1. School of Science & Health, University of Western Sydney, Narellan Road, Campbelltown, Australia
  
• 刊物主题：Sports Medicine; Orthopedics; Rehabilitation Medicine;
• 出版者：BioMed Central
• ISSN：2052-1847

文摘

Background Compression garments (CG) are commonly used by athletes to improve motor performance and recovery during or following exercise. Numerous studies have investigated the effect of CG on physiological and physical parameters with variable results as to their efficacy. A possible effect of commercially available CG may be to induce a change in leg mechanical characteristics during repetitive tasks to fatigue. This investigation determined the effect of CG on performance and vertical stiffness during single-leg-hopping to exhaustion. Methods Thirty-eight healthy, male participants, mean (SD) 22.1 (2.8) years of age performed single-leg hopping at 2.2?Hz to volitional exhaustion with a CG, without CG and with a sham. Differences in total duration of hopping (1-way repeated ANOVA) and dependant variables for the start and end periods (2-way repeated ANOVA) including duration of flight (t_f), loading (t_l) and contact (t_c) phases, vertical height displacement during flight (z_f) and loading (z_l) phases, normalised peak vertical ground reaction force (F_zN) and normalised vertical stiffness (k _N), were determined. Bonferroni correction was performed to reduce the risk of type 1 error. Results There was no significant difference (p--.73) in the total duration of hopping between conditions (CG (mean (SD)) 89.6 (36.3) s; without CG 88.5 (27.5) s; sham 91.3 (27.7) s). There were no significant differences between conditions for spatiotemporal or kinetic characteristics (p-gt;-.05). From the start to the end periods there was no significant difference in t_l (p--.15), significant decrease in t_f (p-lt;-.001), z_f and z_l (p-lt;-.001) and increase in t_c (p-lt;-.001). There was also a significant increase in k _N from start to end periods (p-lt;-.01) ranging from 9.6 to 14.2%. Conclusions This study demonstrates that commercially available CG did not induce a change in spatiotemporal or vertical stiffness during a fatiguing task. The finding that vertical stiffness increased towards the end of the task, while hopping frequency and duration of loading were maintained, may indicate that there was an alteration to the motor control strategy as fatigue approached. Trial registration Current Controlled Trials ACTRN12615000240-49. Registered 17 March 2015.