Modulations of Foot and Ankle Frontal Kinematics for Breaking and Propulsive Movement Characteristics during Side-Step Cutting with Varying Midsole Thicknesses.

Yi-Jia Lin,Chao-Chin Chang,Wei-Chun Hsu,Shih-Chi Lee,Tsung-Han Liu,Tzyy-Yuang Shiang

doi:10.1155/2018/9171502

Abstract

This study is aimed at determining the effects of midsole thickness on movement characteristic during side cutting movement. Fifteen athletes performed side-step cutting while wearing shoes with varying midsole thicknesses. Temporal-spatial and ground reaction force variables as well as foot and ankle frontal kinematics were used to describe breaking and propulsive movement characteristics and modulation strategies. Regardless of midsole thickness, temporal-spatial variables and breaking and propulsive force during side cutting were statistically unchanged. Significantly greater peaks of ankle inversion and plantarflexion with a thicker sole and greater midtarsal pronation with a thinner sole were observed. Current results demonstrated that hypotheses formed solely based on material testing were insufficient to understand the adaptations in human movement because of the redundancy of the neuromusculoskeletal system. Participants were able to maintain temporal-spatial performance during side cutting while wearing shoes with midsoles of varying thicknesses. Increased pronation for a thinner sole might help reduce the force of impact but might be associated with an increased risk of excessive stress on soft tissue. Increased peak of ankle inversion and plantarflexion for a thicker sole may be unfavorable for the stability of ankle joint. Information provided in human movement testing is crucial for understanding factors associated with movement characteristics and injury and should be considered in the future development of shoe design.

Highlights

Enhancement of sports performance and injury prevention possess both intrinsic and extrinsic factors
We investigated the effects of midsole thickness on temporalspatial movement characteristics, ground reaction force (GRF) variables, and ankle and foot kinematics during lateral side cutting (SC)
In addition to GRF variables, our study provided kinematic evidence supporting the risk of lateral ankle sprain during cutting movements

Summary

Introduction

Enhancement of sports performance and injury prevention possess both intrinsic and extrinsic factors. As footwear is an important extrinsic factor, researchers have examined the effect of certain footwear with specific design variables including material properties and thickness on lower limb muscle activities [1], proprioception, and stability [2]. Rather than using the traditional thick-sole design for its cushioning benefits, minimalist sports shoes have recently become a popular alternative [3,4,5,6,7]. The sole of a shoe increases the lever arm, contributing to increased external torque around the subtalar joint [8]. Numerous studies have demonstrated the influence of footwear on foot stability and injury, the independent effect of thickness from each element of a shoe component (i.e., upper, Applied Bionics and Biomechanics insert, midsole, and outsole) on foot and ankle joint mechanics remains unclear

Objectives

Methods

Results

Discussion

Conclusion