Closed-loop EMG-informed model-based analysis of human musculoskeletal mechanics on rough terrains

This work aims at estimating the musculoskeletal forces acting in the human lower extremity during locomotion on rough terrains. We employ computational models of the human neuro-musculoskeletal system that are informed by multi-modal movement data including foot-ground reaction forces, 3D marker trajectories and lower extremity electromyograms (EMG). Data were recorded from one healthy subject locomoting on rough grounds realized using foam rubber blocks of different heights. Blocks arrangement was randomized across all locomotion trials to prevent adaptation to specific ground morphology. Data were used to generate subject-specific models that matched an individual's anthropometry and force-generating capacity. EMGs enabled capturing subject- and ground-specific muscle activation patterns employed for walking on the rough grounds. This allowed integrating realistic activation patterns in the forward dynamic simulations of the musculoskeletal system. The ability to accurately predict the joint mechanical forces necessary to walk on different terrains have implications for our understanding of human movement but also for developing intuitive human machine interfaces for wearable exoskeletons or prosthetic limbs that can seamlessly adapt to different mechanical demands matching biological limb performance.

[1]  Dario Farina,et al.  Modeling and simulating the neuromuscular mechanisms regulating ankle and knee joint stiffness during human locomotion. , 2015, Journal of neurophysiology.

[2]  David G Lloyd,et al.  Estimation of muscle forces and joint moments using a forward-inverse dynamics model. , 2005, Medicine and science in sports and exercise.

[3]  Massimo Sartori,et al.  CEINMS: A toolbox to investigate the influence of different neural control solutions on the prediction of muscle excitation and joint moments during dynamic motor tasks. , 2015, Journal of biomechanics.

[4]  Dario Farina,et al.  EMG-Driven Forward-Dynamic Estimation of Muscle Force and Joint Moment about Multiple Degrees of Freedom in the Human Lower Extremity , 2012, PloS one.

[5]  Günter Hommel,et al.  A Human--Exoskeleton Interface Utilizing Electromyography , 2008, IEEE Transactions on Robotics.

[6]  Jonathan B Dingwell,et al.  Dynamic margins of stability during human walking in destabilizing environments. , 2012, Journal of biomechanics.

[7]  Samuel R. Hamner,et al.  How muscle fiber lengths and velocities affect muscle force generation as humans walk and run at different speeds , 2013, Journal of Experimental Biology.

[8]  D. Farina,et al.  Toward modeling locomotion using electromyography‐informed 3D models: application to cerebral palsy , 2017, Wiley interdisciplinary reviews. Systems biology and medicine.

[9]  Daniel P. Ferris,et al.  Biomechanics and energetics of walking on uneven terrain , 2013, Journal of Experimental Biology.

[10]  D. Lloyd,et al.  An EMG-driven musculoskeletal model to estimate muscle forces and knee joint moments in vivo. , 2003, Journal of biomechanics.

[11]  Dario Farina,et al.  Hybrid neuromusculoskeletal modeling to best track joint moments using a balance between muscle excitations derived from electromyograms and optimization. , 2014, Journal of biomechanics.

[12]  Gabriel Cuellar-Partida,et al.  LocusTrack: Integrated visualization of GWAS results and genomic annotation , 2015, Source Code for Biology and Medicine.

[13]  A. Patla,et al.  Strategies for dynamic stability during locomotion on a slippery surface: effects of prior experience and knowledge. , 2002, Journal of neurophysiology.

[14]  Jonathan B Dingwell,et al.  Kinematic strategies for walking across a destabilizing rock surface. , 2012, Gait & posture.

[15]  May Q. Liu,et al.  Muscle contributions to support and progression over a range of walking speeds. , 2008, Journal of biomechanics.

[16]  Steven J Stanhope,et al.  Changes in knee joint function over a wide range of walking speeds. , 1997, Clinical biomechanics.

[17]  A. Patla,et al.  Adapting locomotion to different surface compliances: neuromuscular responses and changes in movement dynamics. , 2005, Journal of neurophysiology.

[18]  Ayman Habib,et al.  OpenSim: Open-Source Software to Create and Analyze Dynamic Simulations of Movement , 2007, IEEE Transactions on Biomedical Engineering.

[19]  A. Patla,et al.  Adaptations of Walking Pattern on A Compliant Surface to Regulate Dynamic Stability , 2006, Experimental Brain Research.

[20]  Scott L. Delp,et al.  A Model of the Lower Limb for Analysis of Human Movement , 2010, Annals of Biomedical Engineering.

[21]  Massimo Sartori,et al.  Estimation of musculotendon kinematics in large musculoskeletal models using multidimensional B-splines. , 2012, Journal of biomechanics.

[22]  Massimo Sartori,et al.  MOtoNMS: A MATLAB toolbox to process motion data for neuromusculoskeletal modeling and simulation , 2015, Source Code for Biology and Medicine.

[23]  David G. Lloyd,et al.  Neural Data-Driven Musculoskeletal Modeling for Personalized Neurorehabilitation Technologies , 2016, IEEE Transactions on Biomedical Engineering.