AI Article Synopsis
- The human ankle joint is crucial for walking, and understanding its biomechanics sheds light on normal and abnormal gait patterns.
- Recent studies have started to quantify how the ankle's mechanical impedance changes during walking, focusing on its stiffness, damping, and inertia.
- The findings indicate that while stiffness significantly increases during the stance phase, damping changes very little, and both remain low during the swing phase.
- Future research aims to explore ankle impedance during the "push off" phase and in other movement planes.
Article Abstract
The human ankle joint plays a critical role during walking and understanding the biomechanical factors that govern ankle behavior and provides fundamental insight into normal and pathologically altered gait. Previous researchers have comprehensively studied ankle joint kinetics and kinematics during many biomechanical tasks, including locomotion; however, only recently have researchers been able to quantify how the mechanical impedance of the ankle varies during walking. The mechanical impedance describes the dynamic relationship between the joint position and the joint torque during perturbation, and is often represented in terms of stiffness, damping, and inertia. The purpose of this short communication is to unify the results of the first two studies measuring ankle mechanical impedance in the sagittal plane during walking, where each study investigated differing regions of the gait cycle. Rouse measured ankle impedance from late loading response to terminal stance, where Lee quantified ankle impedance from pre-swing to early loading response. While stiffness component of impedance increases significantly as the stance phase of walking progressed, the change in damping during the gait cycle is much less than the changes observed in stiffness. In addition, both stiffness and damping remained low during the swing phase of walking. Future work will focus on quantifying impedance during the "push off" region of stance phase, as well as measurement of these properties in the coronal plane.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC5067112 | PMC |
| http://dx.doi.org/10.1109/JTEHM.2016.2601613 | DOI Listing |
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