Musculoskeletal modeling and simulation techniques have been used to gain insights into movement disabilities for many populations, such as ambulatory children with cerebral palsy (CP). The individuals who can benefit from these techniques are often limited to those who can walk without assistive devices, due to challenges in accurately modeling these devices. Specifically, many children with CP require the use of ankle-foot orthoses (AFOs) to improve their walking ability, and modeling these devices is important to understand their role in walking mechanics. The purpose of this study was to quantify the effects of AFO mechanical property assumptions, including rotational stiffness, damping, and equilibrium angle of the ankle and subtalar joints, on the estimation of lower-limb muscle forces during stance for children with CP. We analyzed two walking gait cycles for two children with CP while they were wearing their own prescribed AFOs. We generated 1000-trial Monte Carlo simulations for each of the walking gait cycles, resulting in a total of 4000 walking simulations. We found that AFO mechanical property assumptions influenced the force estimates for all the muscles in the model, with the ankle muscles having the largest resulting variability. Muscle forces were most sensitive to assumptions of AFO ankle and subtalar stiffness, which should therefore be measured when possible. Muscle force estimates were less sensitive to estimates of damping and equilibrium angle. When stiffness measurements are not available, limitations on the accuracy of muscle force estimates for all the muscles in the model, especially the ankle muscles, should be acknowledged.
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March 2017
Research-Article
Evaluating the Effects of Ankle-Foot Orthosis Mechanical Property Assumptions on Gait Simulation Muscle Force Results
Amy K. Hegarty,
Amy K. Hegarty
Department of Mechanical Engineering,
Colorado School of Mines,
Golden, CO 80401
Colorado School of Mines,
Golden, CO 80401
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Anthony J. Petrella,
Anthony J. Petrella
Department of Mechanical Engineering,
Colorado School of Mines,
Golden, CO 80401
Colorado School of Mines,
Golden, CO 80401
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Max J. Kurz,
Max J. Kurz
Department of Physical Therapy,
Munroe-Meyer Institute for Genetics
and Rehabilitation,
University of Nebraska Medical Center,
Omaha, NE 68198
Munroe-Meyer Institute for Genetics
and Rehabilitation,
University of Nebraska Medical Center,
Omaha, NE 68198
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Anne K. Silverman
Anne K. Silverman
Department of Mechanical Engineering,
Colorado School of Mines,
1500 Illinois Street,
Golden, CO 80401
e-mail: asilverm@mines.edu
Colorado School of Mines,
1500 Illinois Street,
Golden, CO 80401
e-mail: asilverm@mines.edu
Search for other works by this author on:
Amy K. Hegarty
Department of Mechanical Engineering,
Colorado School of Mines,
Golden, CO 80401
Colorado School of Mines,
Golden, CO 80401
Anthony J. Petrella
Department of Mechanical Engineering,
Colorado School of Mines,
Golden, CO 80401
Colorado School of Mines,
Golden, CO 80401
Max J. Kurz
Department of Physical Therapy,
Munroe-Meyer Institute for Genetics
and Rehabilitation,
University of Nebraska Medical Center,
Omaha, NE 68198
Munroe-Meyer Institute for Genetics
and Rehabilitation,
University of Nebraska Medical Center,
Omaha, NE 68198
Anne K. Silverman
Department of Mechanical Engineering,
Colorado School of Mines,
1500 Illinois Street,
Golden, CO 80401
e-mail: asilverm@mines.edu
Colorado School of Mines,
1500 Illinois Street,
Golden, CO 80401
e-mail: asilverm@mines.edu
1Corresponding author.
Manuscript received July 21, 2016; final manuscript received November 21, 2016; published online January 23, 2017. Assoc. Editor: Tammy L. Haut Donahue.
J Biomech Eng. Mar 2017, 139(3): 031009 (8 pages)
Published Online: January 23, 2017
Article history
Received:
July 21, 2016
Revised:
November 21, 2016
Citation
Hegarty, A. K., Petrella, A. J., Kurz, M. J., and Silverman, A. K. (January 23, 2017). "Evaluating the Effects of Ankle-Foot Orthosis Mechanical Property Assumptions on Gait Simulation Muscle Force Results." ASME. J Biomech Eng. March 2017; 139(3): 031009. https://doi.org/10.1115/1.4035472
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