Abstract
Physics-based predictive simulations have been shown to capture many salient features of human walking. Yet they often fail to produce realistic stance knee and ankle mechanics. While the influence of the performance criterion on the predicted walking pattern has been previously studied, the influence of musculoskeletal mechanics has been less explored. Here, we investigated the influence of two mechanical assumptions on the predicted walking pattern: the complexity of the foot model and the stiffness of the Achilles tendon. We found, through three-dimensional muscle-driven predictive simulations of walking, that modeling the toes, and thus using two-segment instead of single-segment foot models, contributed to robustly eliciting physiological stance knee flexion angles, knee extension torques, and knee extensor activity. Modeling toes also slightly decreased the first vertical ground reaction force peak, increasing its agreement with experimental data, and improved stance ankle kinetics. It nevertheless slightly worsened predictions of ankle kinematics. Decreasing Achilles tendon stiffness improved the realism of ankle kinematics, but there remain large discrepancies with experimental data. Overall, this simulation study shows that not only the performance criterion but also mechanical assumptions affect predictive simulations of walking. Improving the realism of predictive simulations is required for their application in clinical contexts. Here, we suggest that using more complex foot models might contribute to such realism.
Highlights
Predictive simulations have advanced our understanding of gait neuromechanics and revealed gaps in our current knowledge [1]
Through 3D simulations of walking, that a two-segment foot model that allowed movement between the toes and the rest of the foot led to more accurate predictions of knee kinematics, knee kinetics, and Modeling toes produces realistic stance knee mechanics in predictive simulations of walking ankle kinetics than a single-segment foot model
We found that decreasing the Achilles tendon stiffness by up to 60% slightly improved predictions of ankle kinematics
Summary
Predictive simulations have advanced our understanding of gait neuromechanics and revealed gaps in our current knowledge [1]. Motivated by the observation that humans select temporospatial walking features (e.g., step frequency [2] and stride length [3]) that minimize metabolic energy per distance traveled, predictive simulations of walking commonly rely on the assumption of performance optimization. De novo walking patterns can be generated by solving for muscle controls that optimize a performance criterion based on a model. Modeling toes produces realistic stance knee mechanics in predictive simulations of walking
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