Effect of 8 Weeks of Grip Strength Training on Adolescent Sprint Swimming: A Randomized Controlled Trial

Q4 Health Professions

Swiss Sports and Exercise Medicine Pub Date : 2020-06-05 DOI:10.26644/em.2020.001

K. Alshdokhi, C. Petersen, J. Clarke

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引用次数: 4

Abstract

R actual surface-swim performance, a swimmer’s ability to reach high speeds is determined by the ability to cover a long distance per stroke, while stroking at maximum frequency [1]. Short sprint swimming (50 – 100 m) requires a continuous high stroke rate and stroke length throughout the race [2,3]. The ability to cover a long distance per stroke demonstrates a greater propulsive efficiency [4] of a swimmer to reduce drag [5] and stroke length has been reported as the best discriminative factor for swim velocity [6]. Handgrip strength results from the forceful flexion of all hand joints (finger joints, thumbs, and wrists) and is measured as the maximum voluntary force that subjects are able to exert under normal biokinetic conditions. There are 35 muscles involved in grip strength which is created by the muscles involved in the flexor mechanism of the hand and forearm, whereas stabilization of the wrist occurs from the extensors of the forearm [7]. In addition to resistance training, handgrip strength is known to be affected by a number of factors such as age, body size, and gender [8]. Maximising propulsive force is a key factor in competitive swimming performance and isometric handgrip strength has been positively correlated with swimming performance [9]. Correlations are stronger in shorter compared to longer swimming races and are stronger for freestyle compared to other strokes [10]. In a recent review, giving mixed results Cronin et al., [11] found that stronger correlations were obResearch Article Exercise Medicine Open Access eISSN: 2508-9056

查看原文本刊更多论文

8周握力训练对青少年短跑游泳的影响:一项随机对照试验

在实际的水面游泳表现中，游泳者达到高速度的能力是由每次划水的长距离能力决定的，同时以最大频率划水。短距离冲刺游泳(50 - 100米)需要在整个比赛中保持持续的高划水速度和划水长度[2,3]。据报道，每次划水覆盖较长距离的能力表明，游泳者在减少阻力[5]和划水长度方面的推进效率[4]更高，这是游泳速度[6]的最佳判别因素。握力来自于所有手部关节(指关节、拇指和手腕)的强力屈曲，并被测量为受试者在正常生物动力学条件下能够施加的最大自主力。握力涉及35块肌肉，这些肌肉是由手和前臂的屈肌机制所涉及的肌肉产生的，而手腕的稳定是由前臂的伸肌产生的。除了阻力训练，握力还受到许多因素的影响，如年龄、体型和性别。最大推进力是竞技游泳成绩的关键因素，等长握力与游泳成绩呈正相关[1]。这种相关性在较短的游泳比赛中比在较长的游泳比赛中更强，在自由泳比赛中比在其他泳姿比赛中更强。在最近的一篇综述中，给出了不同的结果，Cronin等人，b[11]发现，研究文章运动医学开放获取eISSN: 2508-9056的相关性更强

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来源期刊

Swiss Sports and Exercise Medicine Health Professions-Physical Therapy, Sports Therapy and Rehabilitation

CiteScore

0.20

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0.00%

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