Litcius/Paper detail

The Effects of Prosthesis Inversion/Eversion Stiffness on Balance-Related Variability During Level Walking: A Pilot Study

Myunghee Kim, Hannah Lyness, Tianjian Chen, Steven H. Collins

2020Journal of Biomechanical Engineering23 citationsDOI

Abstract

Prosthesis features that enhance balance are desirable to people with transtibial amputation. Ankle inversion/eversion compliance is intended to improve balance on uneven ground, but its effects remain unclear on level ground. We posited that increasing ankle inversion/eversion stiffness during level-ground walking would reduce balance-related effort by assisting in recovery from small disturbances in frontal-plane motions. We performed a pilot test with an ankle-foot prosthesis emulator programmed to apply inversion/eversion torques in proportion to the deviation from a nominal inversion/eversion position trajectory. We applied a range of stiffnesses to clearly understand the effect of the stiffness on balance-related effort, hypothesizing that positive stiffness would reduce effort while negative stiffness would increase effort. Nominal joint angle trajectories were calculated online as a moving average over several steps. In experiments with K3 ambulators with unilateral transtibial amputation (N = 5), stiffness affected step-width variability, average step width, margin of stability, intact-foot center of pressure variability, and user satisfaction (p ≤ 0.05, Friedman's test), but not intact-limb evertor average, intact-limb evertor variability, and metabolic rate (p ≥ 0.38, Friedman's test). Compared to zero stiffness, high positive stiffness reduced step-width variability by 13%, step width by 3%, margin of stability by 3%, and intact-foot center of pressure variability by 14%, whereas high negative stiffness had opposite effects and decreased satisfaction by 63%. The results of this pilot study suggest that positive ankle inversion stiffness can reduce active control requirements during level walking.

Topics & Concepts

StiffnessAnkleCenter of pressure (fluid mechanics)ProsthesisPhysical medicine and rehabilitationGround reaction forceBalance (ability)BiomechanicsOrthodonticsControl theory (sociology)MathematicsMedicineStructural engineeringComputer scienceEngineeringPhysicsSurgeryKinematicsAnatomyMechanicsClassical mechanicsAerodynamicsArtificial intelligenceControl (management)Prosthetics and Rehabilitation RoboticsMuscle activation and electromyography studiesBalance, Gait, and Falls Prevention