Robust Real-Time Musculoskeletal Modeling Driven by Electromyograms

Durandau, Guillaume; Farina, Dario; Sartori, Massimo

doi:10.1109/tbme.2017.2704085

Cited by 127 publications

(137 citation statements)

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“…The complex geometric interactions-sliding and wrapping-between muscles and other mechanical body structures pose a considerable computational challenge for real-time applications (Blana et al, 2017). The engineering trade-off between complexity, performance, and accuracy pushed the development of simplified biomechanical limb models that assumed constant moment arm and posture relationships (Crouch and Huang, 2016) or reduced the span of musculotendon anatomy to ease computational demand (Durandau et al, 2018). Here, we report a method of capturing the kinematic MS transformations within the biomechanical model of the forearm and hand that does not require these simplifications.…”

Section: Discussionmentioning

confidence: 99%

“…Interest in MS approximations has been steadily increasing with the development of computational tools for human motion analysis, e.g., OpenSim (Delp et al, 2007). Accuracy of these approximations has been demonstrated with B-spline models (Durandau et al, 2018;Sartori et al, 2012) and computational efficiency has been achieved with polynomial models (Chadwick et al, 2009;Menegaldo et al, 2004). The optimal polynomials derived in this manuscript have the benefits of both accuracy and computational efficiency.…”

Section: Autogenerating Modelsmentioning

confidence: 94%

“…Another approach developed by Sartori and colleagues (Sartori et al, 2012) emphasizes the quality of approximation using cubic splines. Albeit being computationally expensive, the ability of this approach to operate at realtime has been shown in a 3-DOF per muscle model (Durandau et al, 2018). The drawback of cubic splines, however, are their limited scalability: the number of spline coefficients increases exponentially with the number of DOFs that the muscle crosses.…”

Section: Introductionmentioning

confidence: 99%

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Approximating complex musculoskeletal biomechanics using multidimensional autogenerating polynomials

Sobinov

Boots

Gritsenko

et al. 2019

Preprint

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Computational models of the musculoskeletal system are scientific tools used to study human movement, quantify the effects of injury and disease, and plan surgical interventions. Additionally, these models could also be used to intuitively link biological control signals and realistic high-dimensional articulated prosthetic limbs. However, implementing fast and accurate musculoskeletal computations that can be used to control a prosthetic limb in real-time is a challenging problem. As muscles typically span multiple joints, the wrapping over complex geometrical constraints changes their moment arms and length as a function of joint angle and, thus, their ability to generate joint torques. As a result of these biomechanical complexities, calculating these muscle state variables in real-time is a difficult simulation problem. Here, we report a method to accurately and efficiently calculate these variables for the forearm muscles that actuate the hand and wrist across multiple postures. The posture dependent muscle geometry, moment arms and lengths of modeled muscles, were captured using autogenerating polynomials that expanded their optimal selection of terms using information measurements. The iterative process approximated 33 musculotendon actuators, each spanning up to 6 DOFs in an 18 DOF model of the human arm and hand, defined over the full physiological range of motion. Using these polynomials, the entire forearm anatomy could be computed in <10 µs, which is far better than what is required for real-time performance, and with low errors in moment arms (below 5%) and lengths (below 0.4%). Moreover, we demonstrate that the number of elements in these autogenerating polynomials does not increase exponentially with the increase in complexity of muscles, increasing linearly instead. The similar structure and function of muscles are represented with specific invariant polynomial terms. Dimensionality reduction using the polynomial terms alone resulted in clusters comprised of muscles with similar functions, suggesting that the polynomials themselves captured biologically relevant features of muscle structure and function. We propose that this novel method of describing musculoskeletal biomechanics might further improve the applications of detailed and scalable models for the description of human movement.

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Section: Discussionmentioning

confidence: 99%

Section: Autogenerating Modelsmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Approximating complex musculoskeletal biomechanics using multidimensional autogenerating polynomials

Sobinov

Boots

Gritsenko

et al. 2019

Preprint

View full text Add to dashboard Cite

show abstract

“…While muscle co‐contraction indices (or more appropriately, co‐activation indices) can be computed using different methodologies, using these indices alone to predict joint loading may lead to erroneous conclusions. When estimation of joint loading is not possible, co‐contraction indices that are based on muscle joint moments (instead of muscle activation) may provide a better alternative . From a clinical perspective, decreased knee joint loading (and not excessive loading) at early post‐injury time points has been associated with knee osteoarthritis (OA), at least in a population that opts for reconstructive surgery .…”

Section: Discussionmentioning

confidence: 99%

“…When estimation of joint loading is not possible, cocontraction indices that are based on muscle joint moments (instead of muscle activation) may provide a better alternative. 19,34,35 From a clinical perspective, decreased knee joint loading (and not excessive loading) at early post-injury time points has been associated with knee osteoarthritis (OA), at least in a population that opts for reconstructive surgery. 36 For rehabilitation, evaluating knee joint loading can aid in determining the success of non-operative management in delaying the OA progression, and inform guidelines about returning to sport.…”

Section: Discussionmentioning

confidence: 99%

High muscle co‐contraction does not result in high joint forces during gait in anterior cruciate ligament deficient knees

Khandha

Manal

Capin

et al. 2018

Journal Orthopaedic Research

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The mechanism of knee osteoarthritis development after anterior cruciate ligament injuries is poorly understood. The objective of this study was to evaluate knee gait variables, muscle co-contraction indices and knee joint loading in young subjects with anterior cruciate ligament deficiency (ACLD, n = 36), versus control subjects (n = 12). A validated, electromyography-informed model was used to estimate joint loading. For the involved limb of ACLD subjects versus control, muscle co-contraction indices were higher for the medial (p = 0.018, effect size = 0.93) and lateral (p = 0.028, effect size = 0.83) agonist-antagonist muscle pairs. Despite higher muscle co-contraction, medial compartment contact force was lower for the involved limb, compared to both the uninvolved limb (mean difference = 0.39 body weight, p = 0.009, effect size = 0.70) as well as the control limb (mean difference = 0.57 body weight, p = 0.007, effect size = 1.14). Similar observations were made for total contact force. For involved versus uninvolved limb, the ACLD group demonstrated lower vertical ground reaction force (mean difference = 0.08 body weight, p = 0.010, effect size = 0.70) and knee flexion moment (mean difference = 1.32% body weight * height, p = 0.003, effect size = 0.76), during weight acceptance. These results indicate that high muscle co-contraction does not always result in high knee joint loading, which is thought to be associated with knee osteoarthritis. Long-term follow-up is required to evaluate how gait alterations progress in non-osteoarthritic versus osteoarthritic subjects. © 2018 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res.

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Multiscale modeling of the neuromuscular system: Coupling neurophysiology and skeletal muscle mechanics

Röhrle

Yavuz

Klotz

et al. 2019

WIREs Mechanisms of Disease

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Mathematical models and computer simulations have the great potential to substantially increase our understanding of the biophysical behavior of the neuromuscular system. This, however, requires detailed multiscale, and multiphysics models. Once validated, such models allow systematic in silico investigations that are not necessarily feasible within experiments and, therefore, have the ability to provide valuable insights into the complex interrelations within the healthy system and for pathological conditions. Most of the existing models focus on individual parts of the neuromuscular system and do not consider the neuromuscular system as an integrated physiological system. Hence, the aim of this advanced review is to facilitate the prospective development of detailed biophysical models of the entire neuromuscular system. For this purpose, this review is subdivided into three parts. The first part introduces the key anatomical and physiological aspects of the healthy neuromuscular system necessary for modeling the neuromuscular system. The second part provides an overview on state‐of‐the‐art modeling approaches representing all major components of the neuromuscular system on different time and length scales. Within the last part, a specific multiscale neuromuscular system model is introduced. The integrated system model combines existing models of the motor neuron pool, of the sensory system and of a multiscale model describing the mechanical behavior of skeletal muscles. Since many sub‐models are based on strictly biophysical modeling approaches, it closely represents the underlying physiological system and thus could be employed as starting point for further improvements and future developments. This article is categorized under: Physiology > Mammalian Physiology in Health and Disease Analytical and Computational Methods > Computational Methods Models of Systems Properties and Processes > Organ, Tissue, and Physiological Models

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Robust Real-Time Musculoskeletal Modeling Driven by Electromyograms

Cited by 127 publications

References 50 publications

Approximating complex musculoskeletal biomechanics using multidimensional autogenerating polynomials

Approximating complex musculoskeletal biomechanics using multidimensional autogenerating polynomials

High muscle co‐contraction does not result in high joint forces during gait in anterior cruciate ligament deficient knees

Multiscale modeling of the neuromuscular system: Coupling neurophysiology and skeletal muscle mechanics

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