不同跑步速度下步频的运动学和力学变化。

Kinematics and mechanical changes with step frequency at different running speeds.

作者信息

Mesquita R M, Willems P A, Catavitello G, Dewolf A H

机构信息

Laboratory of Biomechanics and Physiology of Locomotion, Institute of NeuroScience, Université Catholique de Louvain, Place P. de Coubertin, 1, 1348, Louvain-la-Neuve, Belgium.

出版信息

Eur J Appl Physiol. 2024 Feb;124(2):607-622. doi: 10.1007/s00421-023-05303-3. Epub 2023 Sep 8.

DOI:10.1007/s00421-023-05303-3

PMID:37684396

Abstract

PURPOSE

Running at a given speed can be achieved by taking large steps at a low frequency or on the contrary by taking small steps at a high frequency. The consequences of a change in step frequency, at a fixed speed, affects the stiffness of the lower limb differently. In this study, we compared the running mechanics and kinematics at different imposed step frequencies (from 2 step s to 3.6 step s) to understand the relationship between kinematic and kinetic parameters.

METHODS

Eight recreational male runners ran on a treadmill at 5 different speeds and 5 different step frequencies. The lower-limb segment motion and the ground reaction forces were recorded. Mechanical powers, general gait parameters, lower-limb movements and coordination were investigated.

RESULTS

At low step frequencies, in order to limit the magnitude of the ground reaction force, the vertical stiffness is reduced and thus runners deviate from an elastic rebound. At high step frequencies, the stiffness is increased and the elastic rebound is optimised in its ability to absorb and restore energy during the contact phase.

CONCLUSION

We studied the consequences of a change in step frequency on the bouncing mechanics of running. We showed that the lower limb stiffness and the intersegmental coordination of the lower-limb segments are affected by running step frequency rather than speed. The runner rather adapts their lower limb stiffness to match a step frequency for a given speed than the opposite.

摘要

目的

以给定速度跑步可以通过低频大步幅或相反地高频小步幅来实现。在固定速度下，步频变化的后果对下肢刚度的影响有所不同。在本研究中，我们比较了不同施加步频（从2步/秒到3.6步/秒）下的跑步力学和运动学，以了解运动学参数和动力学参数之间的关系。

方法

八名男性业余跑步者在跑步机上以5种不同速度和5种不同步频跑步。记录下肢节段运动和地面反作用力。研究了机械功率、一般步态参数、下肢运动和协调性。

结果

在低步频时，为了限制地面反作用力的大小，垂直刚度降低，因此跑步者偏离了弹性反弹。在高步频时，刚度增加，并且在接触阶段吸收和恢复能量方面，弹性反弹的能力得到优化。

结论

我们研究了步频变化对跑步弹跳力学的影响。我们表明，下肢刚度和下肢节段间协调性受跑步步频而非速度的影响。跑步者更倾向于调整下肢刚度以匹配给定速度下的步频，而非相反。

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不同跑步速度下步频的运动学和力学变化。

Kinematics and mechanical changes with step frequency at different running speeds.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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