3D足弓支撑鞋垫对纵跳的生物力学影响:一项统计参数映射分析
Biomechanical impacts of 3D arch-support insoles on countermovement jumps: a statistical parametric mapping analysis.
作者信息
Shi Qiu-Qiong, Yick Kit-Lun, Huang Rui-Feng, Li Chu-Hao, Wu Jin Long
机构信息
School of Fashion and Textiles, The Hong Kong Polytechnic University, Hong Kong, China.
Research Institute for Sports Science and Technology, Hong Kong, China.
出版信息
Front Bioeng Biotechnol. 2025 Aug 26;13:1624892. doi: 10.3389/fbioe.2025.1624892. eCollection 2025.
OBJECTIVE
Despite the widespread use of arch-support insoles in sports, their time-dependent biomechanical effects on dynamic movements like countermovement jumps (CMJs) remain poorly understood. This study investigated the biomechanical impacts of three-dimensional (3D) arch-support insoles with varying degrees of stiffness on CMJs by using a statistical parametric mapping (SPM) analysis.
DESIGN
Randomized crossover study.
METHOD
Twelve active male university students tested three different polyurethane 3D arch-support insoles (i.e., soft, semi-rigid, and rigid insoles). A total of 16 reflective markers were placed on the lower limbs of the participants according to the Vicon Plug-in Gait marker set protocols. The lower limb kinematics and kinetics were captured by using two synchronized force plates and an eight-camera motion analysis system. SPM was used to statistically compare the biomechanical changes across the different 3D insoles during six continuous key phases of CMJs.
RESULTS
With the 3D arch-support insoles donned, supra-threshold clusters of the ankle kinematics in the sagittal and frontal planes exceeded the critical thresholds during propulsion-flight ( = 0.022) and the landing ( = 0.033). Ankle moment in the transverse direction exceeded the critical threshold of 6.46 during propulsion ( = 0.038) and landing ( < 0.001). The critical threshold of 6.555 was exceeded for propulsion ( = 0.050) and landing ( < 0.001) with supra-threshold clusters for the force in the frontal plane of the knee. Ankle force in the transverse direction showed that the supra-threshold clusters exceeded the critical threshold during weighing-unweighting ( < 0.001), and early landing ( = 0.007).
CONCLUSION
Rigid and semi-rigid 3D arch-support insoles significantly altered the biomechanics of the ankle joint, primarily in the frontal and transverse planes during propulsion-flight, and the landing phases. The rigid 3D insole most effectively enhanced ankle joint stability, which is crucial for maintaining balance and preventing injuries. SPM provided a time-dependent analysis of the biomechanical impacts during CMJ.
目的
尽管足弓支撑鞋垫在运动中广泛使用,但其对诸如反向纵跳(CMJ)等动态动作的时间依赖性生物力学效应仍知之甚少。本研究通过使用统计参数映射(SPM)分析,调查了不同刚度的三维(3D)足弓支撑鞋垫对CMJ的生物力学影响。
设计
随机交叉研究。
方法
12名活跃的男性大学生测试了三种不同的聚氨酯3D足弓支撑鞋垫(即软鞋垫、半刚性鞋垫和刚性鞋垫)。根据Vicon插件式步态标记集协议,在参与者的下肢总共放置了16个反光标记。使用两个同步测力板和一个八相机运动分析系统来采集下肢的运动学和动力学数据。SPM用于统计比较在CMJ的六个连续关键阶段中不同3D鞋垫之间的生物力学变化。
结果
穿上3D足弓支撑鞋垫后,在推进-飞行阶段(P = 0.022)和着陆阶段(P = 0.033),矢状面和额状面的踝关节运动学超阈值簇超过了临界阈值。在推进阶段(P = 0.038)和着陆阶段(P < 0.001),横向踝关节力矩超过了6.46的临界阈值。在推进阶段(P = 0.050)和着陆阶段(P < 0.001),膝关节额状面力的超阈值簇超过了6.555的临界阈值。横向踝关节力显示,在称重-失重阶段(P < 0.001)和早期着陆阶段(P = 0.007),超阈值簇超过了临界阈值。
结论
刚性和半刚性3D足弓支撑鞋垫显著改变了踝关节的生物力学,主要是在推进-飞行阶段和着陆阶段的额状面和横向平面。刚性3D鞋垫最有效地增强了踝关节稳定性,这对于维持平衡和预防损伤至关重要。SPM提供了CMJ期间生物力学影响的时间依赖性分析。
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