Is the Force-Velocity Profile for Free Jumping a Sound Basis for Individualized Jump Training Prescriptions?

IF 4.1 2区医学 Q1 SPORT SCIENCES

Medicine and Science in Sports and Exercise Pub Date : 2025-04-01 Epub Date: 2024-11-28 DOI:10.1249/MSS.0000000000003612

Maarten F Bobbert, Kolbjørn Lindberg, Gøran Paulsen

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引用次数: 0

Abstract

Introduction: Formulating individualized optimized jump training prescriptions based on the force-velocity profile has become popular, but its effectiveness has been contested. Such training programs have opposite effects on "maximal average force" and "maximal average shortening velocity," and we set out to investigate which training-induced changes in the neuromuscular system could cause such effects.

Methods: We used a musculoskeletal simulation model with four body segments and six muscle-tendon actuators to simulate vertical squat jumps with different loads. Independent input was muscle stimulation over time, which was optimized for maximal jump height. We determined the force-velocity profile for a reference model and investigated how it changed when we modified muscle properties and initial postures.

Results: We could not reproduce the reported training effects by realistically improving muscle properties (maximal force, shortening velocity, and rate of force development) or modifying initial postures of the model. However, the profile was very sensitive to gains in jump height at low loads but not high loads, or vice versa. Reaching maximal height in force-velocity profile jumps requires skill. We argued that submaximal performance in low-load or high-load jumps caused by lack of skill could be responsible for large imbalances in profiles before training. Differential skill training promoted by the individualized optimized approach could explain quick changes toward a balanced profile.

Conclusions: If the success of individualized optimized training studies is explained by selective skill improvements, training effects are unlikely to transfer to other tasks, and individualized optimized training will not be superior to other types of training.

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自由跳跃的力-速度曲线是个性化跳跃训练处方的可靠依据吗？

简介：根据力-速度曲线制定个性化的优化跳跃训练处方已成为一种流行趋势，但其有效性一直存在争议：根据力量-速度曲线制定个性化的优化跳跃训练方案已成为一种流行趋势，但其有效性一直存在争议。此类训练计划对 "最大平均力 "和 "最大平均缩短速度 "的影响截然相反，因此我们开始研究神经肌肉系统中哪些训练诱导的变化可能导致此类影响：我们使用了一个包含四个身体部分和六个肌肉肌腱致动器的肌肉骨骼模拟模型，来模拟不同负荷下的垂直深蹲跳跃。独立输入是随时间变化的肌肉刺激，该刺激针对最大跳跃高度进行了优化。我们确定了参考模型的力-速度曲线，并研究了当我们改变肌肉特性和初始姿势时，力-速度曲线是如何变化的：结果：我们无法通过真实地改善肌肉特性（最大力量、缩短速度和力量发展速度）或修改模型的初始姿势来重现所报告的训练效果。不过，该模型对低负荷时的跳跃高度增加非常敏感，但对高负荷时的跳跃高度增加并不敏感，反之亦然。在力-速度曲线跳跃中达到最大高度需要技巧。我们认为，在低负荷或高负荷起跳中，由于缺乏技巧而导致的亚极限表现可能是训练前曲线严重失衡的原因。个体化优化方法所促进的差异化技能训练可以解释向平衡曲线快速转变的原因：如果个体化优化训练研究的成功是由选择性技能提高造成的，那么训练效果不太可能转移到其他任务上，个体化优化训练也不会优于其他类型的训练。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Medicine and Science in Sports and Exercise 医学-运动科学

CiteScore

7.70

自引率

4.90%

发文量

2568

审稿时长

1 months

期刊介绍： Medicine & Science in Sports & Exercise® features original investigations, clinical studies, and comprehensive reviews on current topics in sports medicine and exercise science. With this leading multidisciplinary journal, exercise physiologists, physiatrists, physical therapists, team physicians, and athletic trainers get a vital exchange of information from basic and applied science, medicine, education, and allied health fields.