Modeling and simulating the neuromuscular mechanisms regulating ankle and knee joint stiffness during human locomotion

Modeling and simulating the neuromuscular mechanisms regulating ankle and knee joint stiffness during human locomotion

This work presents an electrophysiologically and dynamically consistent musculoskeletal model to predict stiffness in the human ankle and knee joints as derived from the joints constituent biological tissues (i.e., the spanning musculotendon units). The modeling method we propose uses electromyograp...

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Bibliographic Details
Published in:Journal of neurophysiology Vol. 114; no. 4; pp. 2509 - 2527
Main Authors: Sartori, Massimo, Maculan, Marco, Pizzolato, Claudio, Reggiani, Monica, Farina, Dario
Format: Journal Article
Language:English
Published: United States American Physiological Society 01-10-2015
Subjects:
Accelerometry
Adult
Ankle Joint - physiology
Biomechanical Phenomena
Control of Movement
Elasticity
Electromyography
Humans
Knee Joint - physiology
Leg - physiology
Male
Models, Biological
Muscle Contraction - physiology
Muscle Fibers, Skeletal - physiology
Muscle, Skeletal - physiology
Running - physiology
Signal Processing, Computer-Assisted
Tendons - physiology
Walking - physiology
human leg
stiffness
compliance
electromyography
neuromusculoskeletal modeling
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Summary:This work presents an electrophysiologically and dynamically consistent musculoskeletal model to predict stiffness in the human ankle and knee joints as derived from the joints constituent biological tissues (i.e., the spanning musculotendon units). The modeling method we propose uses electromyography (EMG) recordings from 13 muscle groups to drive forward dynamic simulations of the human leg in five healthy subjects during overground walking and running. The EMG-driven musculoskeletal model estimates musculotendon and resulting joint stiffness that is consistent with experimental EMG data as well as with the experimental joint moments. This provides a framework that allows for the first time observing 1) the elastic interplay between the knee and ankle joints, 2) the individual muscle contribution to joint stiffness, and 3) the underlying co-contraction strategies. It provides a theoretical description of how stiffness modulates as a function of muscle activation, fiber contraction, and interacting tendon dynamics. Furthermore, it describes how this differs from currently available stiffness definitions, including quasi-stiffness and short-range stiffness. This work offers a theoretical and computational basis for describing and investigating the neuromuscular mechanisms underlying human locomotion.
Bibliography:ObjectType-Article-1
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ISSN:0022-3077
1522-1598
DOI:10.1152/jn.00989.2014