Simulating the effect of ankle plantarflexion and inversion-eversion exoskeleton torques on center of mass kinematics during walking

Bianco, Nicholas A.; Collins, Susan M.; Liu, Karen; Delp, Scott L.

doi:10.1101/2022.11.07.515398

Cited by 6 publications

(3 citation statements)

References 72 publications

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“…The study showed reasonable model validity for muscle activation and VL muscle fascicle velocities across different power demands and cadence conditions. Recent studies that used a direct collocation approach during walking (Bianco et al 2022) and hopping (Jessup, Kelly, and Cresswell 2023) showed a similar correspondence to experimental data. The Umberger metabolic probe also revealed a curvilinear pattern in relationship between cadence and metabolic power for all intensities, which is consistent with previous studies.…”

Section: Discussionsupporting

confidence: 65%

An in-silico investigation of the effect of changing cycling crank power and cadence on muscle energetics and active muscle volume

Riveros-Matthey,

Carroll,

Connick

et al. 2023

Preprint

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This study used musculoskeletal modelling to explore the relationship between cycling conditions (power output and cadence) and muscle activation and metabolic power. We hypothesized that the cadence that minimized the simulated average active muscle volume would be higher than that which minimized the simulated metabolic power. We validated the simulation by comparing predicted muscle activation and fascicle velocities from select muscles with experimental records of electromyography and ultrasound images. We found strong correlations for averaged muscle activations and moderate to good correlations for fascicle dynamics. These correlations tended to weaken when analyzed at the individual participant level. Our study revealed a curvilinear relationship between average active muscle volume and cadence, with the minimum active volume being aligned to the self-selected cadence. The simulated metabolic power was consistent with previous results and was minimized at lower cadences than that which minimized active muscle volume across power outputs. Whilst there are some limitations to the musculoskeletal modelling approach, the findings suggest that minimizing active muscle volume may be a more important factor than minimizing metabolic power for self-selected cycling cadence preferences. Further research is warranted to explore the potential of an active muscle volume based objective function for control schemes across a wider range of cycling conditions.

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Section: Discussionsupporting

confidence: 65%

An in-silico investigation of the effect of changing cycling crank power and cadence on muscle energetics and active muscle volume

Riveros-Matthey,

Carroll,

Connick

et al. 2023

Preprint

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“…However, ground truth joint angles and moments cannot be directly measured from experiments. We thus used a three-dimensional dynamic simulation of walking created using trajectory optimization [ 63 ], where joint angles and moments are known and residual forces and moments are also known to be zero, to generate a synthetic dataset. We used synthesized marker trajectories, along with the computed ground reaction forces and centers of pressure from the simulation, as inputs to AddBiomechanics.…”

Section: Methodsmentioning

confidence: 99%

AddBiomechanics: Automating model scaling, inverse kinematics, and inverse dynamics from human motion data through sequential optimization

Werling,

Bianco,

Raitor

et al. 2023

PLoS ONE

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Creating large-scale public datasets of human motion biomechanics could unlock data-driven breakthroughs in our understanding of human motion, neuromuscular diseases, and assistive devices. However, the manual effort currently required to process motion capture data and quantify the kinematics and dynamics of movement is costly and limits the collection and sharing of large-scale biomechanical datasets. We present a method, called AddBiomechanics, to automate and standardize the quantification of human movement dynamics from motion capture data. We use linear methods followed by a non-convex bilevel optimization to scale the body segments of a musculoskeletal model, register the locations of optical markers placed on an experimental subject to the markers on a musculoskeletal model, and compute body segment kinematics given trajectories of experimental markers during a motion. We then apply a linear method followed by another non-convex optimization to find body segment masses and fine tune kinematics to minimize residual forces given corresponding trajectories of ground reaction forces. The optimization approach requires approximately 3-5 minutes to determine a subject’s skeleton dimensions and motion kinematics, and less than 30 minutes of computation to also determine dynamically consistent skeleton inertia properties and fine-tuned kinematics and kinetics, compared with about one day of manual work for a human expert. We used AddBiomechanics to automatically reconstruct joint angle and torque trajectories from previously published multi-activity datasets, achieving close correspondence to expert-calculated values, marker root-mean-square errors less than 2 cm, and residual force magnitudes smaller than 2% of peak external force. Finally, we confirmed that AddBiomechanics accurately reproduced joint kinematics and kinetics from synthetic walking data with low marker error and residual loads. We have published the algorithm as an open source cloud service at AddBiomechanics.org, which is available at no cost and asks that users agree to share processed and de-identified data with the community. As of this writing, hundreds of researchers have used the prototype tool to process and share about ten thousand motion files from about one thousand experimental subjects. Reducing the barriers to processing and sharing high-quality human motion biomechanics data will enable more people to use state-of-the-art biomechanical analysis, do so at lower cost, and share larger and more accurate datasets.

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“…During the initial phase of SLS, the CoM moves laterally toward the supporting (SLS) leg to prepare for swinging of the opposite leg, therefore, lateral stability is challenged in the frontal plane 44 . Ankle inversion torque generated by the TA muscle during single leg stance shifts the center of pressure (CoP) laterally 45 . Given that the CoP should be continuously moved toward the CoM to keep the CoM over the base of support for maintaining balance, the older adults-speci c predominant TA activation appears to be one of the movement strategies for lateral balance control at the ankle joint level.…”

Section: Age-related Differnces In Knee Extensor Eccentric Control An...mentioning

confidence: 99%

Analysis of age-related difference in lower limb muscle activation pattern and movement strategies during walking balance control on a compliant surface

Jeon

Ramadan

Whitall

et al. 2023

Preprint

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Substantial evidence demonstrates that falls in older adults are leading causes of fatal and non-fatal injuries and lead to negative impacts on quality of life in the aging population. Most falls in elderly fallers result from unrecoverable limb collapse during falling momentum control in the single limb support (SLS) phase. To understand why older adults are more likely to fall than younger adults, we investigated age-related differences in knee extensor eccentric control, lower limb muscle activation patterns, and their relation to balance control. Ten older and ten younger healthy adults were compared during balance control while walking on a compliant surface. There was a positive correlation between knee extensor eccentric work of perturbed leg and swinging leg’s speed and margin of stability. In comparison to younger adults, older adults demonstrated 1) smaller eccentric work, reduced eccentric electromyography burst duration in the perturbed leg, 2) higher postural sway during SLS, and 3) impaired swinging leg balance control. The group specific muscle synergy showed that older adults had a prominent ankle muscle activation while a prominent hip muscle activation in younger adults. These findings provide insight into targeted balance rehabilitation directions to improve postural stability and reduce falls in older adults.

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Simulating the effect of ankle plantarflexion and inversion-eversion exoskeleton torques on center of mass kinematics during walking

Cited by 6 publications

References 72 publications

An in-silico investigation of the effect of changing cycling crank power and cadence on muscle energetics and active muscle volume

An in-silico investigation of the effect of changing cycling crank power and cadence on muscle energetics and active muscle volume

AddBiomechanics: Automating model scaling, inverse kinematics, and inverse dynamics from human motion data through sequential optimization

Analysis of age-related difference in lower limb muscle activation pattern and movement strategies during walking balance control on a compliant surface

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