Lin Shih-Yun, Su Pei-Fang, Chung Chia-Hua, Hsia Chi-Chun, Chang Chih-Han
Department of Biomedical Engineering, National Cheng Kung University, Tainan, Taiwan.
Information and Communications Research Laboratories, Industrial Technology Research Institute, Tainan, Taiwan.
PLoS One. 2017 Jan 3;12(1):e0169151. doi: 10.1371/journal.pone.0169151. eCollection 2017.
Rocker-soled shoes provide a way to reduce the possible concentration of stress, as well as change movement patterns, during gait. This study attempts to examine how plantar force and spatio-temporal variables are affected by two rocker designs, one with softer and one with denser sole materials, by comparing them with the barefoot condition and with flat-soled shoes. Eleven subjects' gait parameters during walking and jogging were recorded. Our results showed that compared with barefoot walking, plantar forces were higher for flat shoes while lower for both types of rocker shoes, the softer-material rocker being the lowest. The plantar force of flat shoes is greater than the vertical ground reaction force, while that of both rocker shoes is much less, 13.87-30.55% body weight. However, as locomotion speed increased to jogging, for all shoe types, except at the second peak plantar force of the denser sole material rocker shoes, plantar forces were greater than for bare feet. More interestingly, because the transmission of force was faster while jogging, greater plantar force was seen in the rocker-soled shoes with softer material than with denser material; results for higher-speed shock absorption in rocker-soled shoes with softer material were thus not as good. In general, the rolling phenomena along the bottom surface of the rocker shoes, as well as an increase in the duration of simultaneous curve rolling and ankle rotation, could contribute to the reduction of plantar force for both rocker designs. The possible mechanism is the conversion of vertical kinetic energy into rotational kinetic energy. To conclude, since plantar force is related to foot-ground interface and deceleration methods, rocker-design shoes could achieve desired plantar force reduction through certain rolling phenomena, shoe-sole stiffness levels, and locomotion speeds.
摇椅底鞋提供了一种在步态过程中降低可能的压力集中以及改变运动模式的方法。本研究试图通过将两种摇椅设计(一种鞋底材料较软,另一种较硬)与赤脚状态和平底鞋进行比较,来检验足底力和时空变量是如何受到这两种摇椅设计影响的。记录了11名受试者在行走和慢跑时的步态参数。我们的结果表明,与赤脚行走相比,平底鞋的足底力更高,而两种摇椅鞋的足底力更低,其中材料较软的摇椅鞋的足底力最低。平底鞋的足底力大于地面垂直反作用力,而两种摇椅鞋的足底力则小得多,为体重的13.87 - 30.55%。然而,当运动速度增加到慢跑时,对于所有鞋类,除了较硬鞋底材料的摇椅鞋的第二个足底力峰值外,足底力都大于赤脚时的情况。更有趣的是,由于慢跑时力的传递更快,材料较软的摇椅底鞋比材料较硬的摇椅底鞋出现了更大的足底力;因此,材料较软的摇椅底鞋在高速减震方面的效果并不好。一般来说,摇椅鞋底面的滚动现象,以及同时曲线滚动和脚踝旋转持续时间的增加,可能有助于两种摇椅设计降低足底力。可能的机制是垂直动能向旋转动能的转换。总之,由于足底力与脚 - 地面界面和减速方法有关,摇椅设计的鞋子可以通过某些滚动现象、鞋底刚度水平和运动速度来实现所需的足底力降低。
