Sangam: A Confluence of Knowledge Streams

Human Leg Model Predicts Muscle Forces, States, and Energetics during Walking

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dc.contributor Massachusetts Institute of Technology. Media Laboratory
dc.contributor Markowitz, Jared John
dc.contributor Herr, Hugh M.
dc.creator Markowitz, Jared John
dc.creator Herr, Hugh M.
dc.date 2016-06-30T19:18:28Z
dc.date 2016-06-30T19:18:28Z
dc.date 2016-05
dc.date 2015-09
dc.date.accessioned 2023-03-01T18:10:58Z
dc.date.available 2023-03-01T18:10:58Z
dc.identifier 1553-7358
dc.identifier http://hdl.handle.net/1721.1/103392
dc.identifier Markowitz, Jared, and Hugh Herr. “Human Leg Model Predicts Muscle Forces, States, and Energetics During Walking.” Edited by Adrian M Haith. PLoS Comput Biol 12, no. 5 (May 13, 2016): e1004912.
dc.identifier https://orcid.org/0000-0003-3169-1011
dc.identifier.uri http://localhost:8080/xmlui/handle/CUHPOERS/279061
dc.description Humans employ a high degree of redundancy in joint actuation, with different combinations of muscle and tendon action providing the same net joint torque. Both the resolution of these redundancies and the energetics of such systems depend on the dynamic properties of muscles and tendons, particularly their force-length relations. Current walking models that use stock parameters when simulating muscle-tendon dynamics tend to significantly overestimate metabolic consumption, perhaps because they do not adequately consider the role of elasticity. As an alternative, we posit that the muscle-tendon morphology of the human leg has evolved to maximize the metabolic efficiency of walking at self-selected speed. We use a data-driven approach to evaluate this hypothesis, utilizing kinematic, kinetic, electromyographic (EMG), and metabolic data taken from five participants walking at self-selected speed. The kinematic and kinetic data are used to estimate muscle-tendon lengths, muscle moment arms, and joint moments while the EMG data are used to estimate muscle activations. For each subject we perform an optimization using prescribed skeletal kinematics, varying the parameters that govern the force-length curve of each tendon as well as the strength and optimal fiber length of each muscle while seeking to simultaneously minimize metabolic cost and maximize agreement with the estimated joint moments. We find that the metabolic cost of transport (MCOT) values of our participants may be correctly matched (on average 0.36±0.02 predicted, 0.35±0.02 measured) with acceptable joint torque fidelity through application of a single constraint to the muscle metabolic budget. The associated optimal muscle-tendon parameter sets allow us to estimate the forces and states of individual muscles, resolving redundancies in joint actuation and lending insight into the potential roles and control objectives of the muscles of the leg throughout the gait cycle.
dc.description United States. National Aeronautics and Space Administration (grant number 6926843)
dc.format application/pdf
dc.language en_US
dc.publisher Public Library of Science
dc.relation http://dx.doi.org/10.1371/journal.pcbi.1004912
dc.relation PLOS Computational Biology
dc.rights Creative Commons Attribution 4.0 International License
dc.rights http://creativecommons.org/licenses/by/4.0/
dc.source PLOS
dc.title Human Leg Model Predicts Muscle Forces, States, and Energetics during Walking
dc.type Article
dc.type http://purl.org/eprint/type/JournalArticle


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