A computationally efficient strategy to estimate muscle forces in a finite element musculoskeletal model of the lower limb.

Concurrent multiscale simulation strategies are required in computational biomechanics to study the interdependence between body scales. However, detailed finite element models rarely include muscle recruitment due to the computational burden of both the finite element method and the optimization strategies widely used to estimate muscle forces. The aim of this study was twofold: first, to develop a computationally efficient muscle force prediction strategy based on proportional-integral-derivative (PID) controllers to track gait and chair rise experimental joint motion with a finite element musculoskeletal model of the lower limb, including a deformable knee representation with 12 degrees of freedom; and, second, to demonstrate that the inclusion of joint-level deformability affects muscle force estimation by using two different knee models and comparing muscle forces between the two solutions. The PID control strategy tracked experimental hip, knee, and ankle flexion/extension with root mean square errors below 1°, and estimated muscle, contact and ligament forces in good agreement with previous results and electromyography signals. Differences up to 11% and 20% in the vasti and biceps femoris forces, respectively, were observed between the two knee models, which might be attributed to a combination of differing joint contact geometry, ligament behavior, joint kinematics, and muscle moment arms. The tracking strategy developed in this study addressed the inevitable tradeoff between computational cost and model detail in musculoskeletal simulations and can be used with finite element musculoskeletal models to efficiently estimate the interdependence between muscle forces and tissue deformation.

[1]  M. Pandy,et al.  Muscle, ligament, and joint-contact forces at the knee during walking. , 2005, Medicine and science in sports and exercise.

[2]  Paul J. Rullkoetter,et al.  Prediction of In Vivo Knee Joint Loads Using a Global Probabilistic Analysis. , 2016, Journal of biomechanical engineering.

[3]  Clare K Fitzpatrick,et al.  A Combined Experimental and Computational Approach to Subject-Specific Analysis of Knee Joint Laxity. , 2016, Journal of biomechanical engineering.

[4]  A. Erdemir,et al.  Multiscale modeling in computational biomechanics , 2009, IEEE Engineering in Medicine and Biology Magazine.

[5]  M G Pandy,et al.  Static and dynamic optimization solutions for gait are practically equivalent. , 2001, Journal of biomechanics.

[6]  Clare K Fitzpatrick,et al.  Validation of predicted patellofemoral mechanics in a finite element model of the healthy and cruciate-deficient knee. , 2016, Journal of biomechanics.

[7]  Ahmet Erdemir,et al.  Adaptive surrogate modeling for efficient coupling of musculoskeletal control and tissue deformation models. , 2009, Journal of biomechanical engineering.

[8]  Diogo M. Geraldes,et al.  Consideration of multiple load cases is critical in modelling orthotropic bone adaptation in the femur , 2015, Biomechanics and Modeling in Mechanobiology.

[9]  Marko Ackermann,et al.  Concurrent musculoskeletal dynamics and finite element analysis predicts altered gait patterns to reduce foot tissue loading. , 2010, Journal of biomechanics.

[10]  D. Calvetti,et al.  Stochastic modelling of muscle recruitment during activity , 2015, Interface Focus.

[11]  Paul J. Rullkoetter,et al.  A Reconfigurable High-Speed Stereo-Radiography System for Sub-Millimeter Measurement of In Vivo Joint Kinematics , 2015 .

[12]  Andrew R Hopkins,et al.  Finite element models of total shoulder replacement: Application of boundary conditions , 2005, Computer methods in biomechanics and biomedical engineering.

[13]  Kevin B. Shelburne,et al.  Dependence of Muscle Moment Arms on In Vivo Three-Dimensional Kinematics of the Knee , 2017, Annals of Biomedical Engineering.

[14]  S. Delp,et al.  A modeling framework to estimate patellofemoral joint cartilage stress in vivo. , 2005, Medicine and science in sports and exercise.

[15]  M. Pandy,et al.  Pattern of anterior cruciate ligament force in normal walking. , 2004, Journal of biomechanics.

[16]  F.E. Zajac,et al.  An interactive graphics-based model of the lower extremity to study orthopaedic surgical procedures , 1990, IEEE Transactions on Biomedical Engineering.

[17]  Darryl G. Thelen,et al.  Prediction and Validation of Load-Dependent Behavior of the Tibiofemoral and Patellofemoral Joints During Movement , 2015, Annals of Biomedical Engineering.

[18]  Clare K Fitzpatrick,et al.  Evaluating knee replacement mechanics during ADL with PID-controlled dynamic finite element analysis , 2014, Computer methods in biomechanics and biomedical engineering.

[19]  Michael F. Vignos,et al.  Influence of Ligament Properties on Tibiofemoral Mechanics in Walking , 2015, The Journal of Knee Surgery.

[20]  Lowell M Smoger,et al.  Statistical modeling to characterize relationships between knee anatomy and kinematics , 2015, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[21]  Kevin B Shelburne,et al.  The interaction of muscle moment arm, knee laxity, and torque in a multi-scale musculoskeletal model of the lower limb. , 2018, Journal of biomechanics.

[22]  Pascal Schütz,et al.  Subject‐specific modeling of muscle force and knee contact in total knee arthroplasty , 2016, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[23]  Harrington Ij,et al.  A bioengineering analysis of force actions at the knee in normal and pathological gait. , 1976 .

[24]  Antonio Simón,et al.  Combination of finite element modeling and optimization for the study of lumbar spine biomechanics considering the 3D thorax-pelvis orientation. , 2004, Medical engineering & physics.

[25]  Marcus G Pandy,et al.  A Dynamic Model of the Knee and Lower Limb for Simulating Rising Movements , 2002, Computer methods in biomechanics and biomedical engineering.

[26]  Gregor Schöner,et al.  The uncontrolled manifold concept: identifying control variables for a functional task , 1999, Experimental Brain Research.

[27]  D. Thelen,et al.  Co-simulation of neuromuscular dynamics and knee mechanics during human walking. , 2014, Journal of biomechanical engineering.

[28]  G. Bergmann,et al.  Standardized Loads Acting in Hip Implants , 2014, PloS one.

[29]  F. Zajac,et al.  A musculoskeletal model of the human lower extremity: the effect of muscle, tendon, and moment arm on the moment-angle relationship of musculotendon actuators at the hip, knee, and ankle. , 1990, Journal of biomechanics.

[30]  Gordon Clapworthy,et al.  Biomechanics Modeling of the Musculoskeletal Apparatus: Status and Key Issues , 2006, Proceedings of the IEEE.

[31]  M G Pandy,et al.  Computer modeling and simulation of human movement. , 2001, Annual review of biomedical engineering.

[32]  M. Pandy,et al.  Dynamic optimization of human walking. , 2001, Journal of biomechanical engineering.

[33]  Gerald E. Loeb,et al.  Optimal isn’t good enough , 2012, Biological Cybernetics.

[34]  M L Audu,et al.  The influence of muscle model complexity in musculoskeletal motion modeling. , 1985, Journal of biomechanical engineering.

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

[36]  R. Crowninshield,et al.  A physiologically based criterion of muscle force prediction in locomotion. , 1981, Journal of biomechanics.

[37]  Joseph J Crisco,et al.  Static and dynamic error of a biplanar videoradiography system using marker-based and markerless tracking techniques. , 2011, Journal of biomechanical engineering.