What the hell did your doctor do with this in the past seven years? NOTHING?
Then get that doctor, the stroke department head, the president and the board of diectors fired. FOR INCOMPETENCE!
Changes in the activation and function of the ankle plantar flexor muscles due to gait retraining in chronic stroke survivors
2013, Journal of NeuroEngineering and Rehabilitation
Brian A Knarr 1,5*,
Trisha M Kesar 4,
Darcy S Reisman 1,2,
Stuart A Binder-Macleod 1,2
and Jill S Higginson 1,3
and Jill S Higginson 1,3
1 Biomechanics and Movement Science, University of Delaware, Newark, DE,USA.2 Department of Physical Therapy, University of Delaware, Newark, DE,USA.
3 Department of Mechanical Engineering, University of Delaware,Newark, DE, USA.
4 Department of Rehabilitation Medicine, Division of Physical Therapy, Emory University, Atlanta, GA, USA.
5 University of Delaware,126 Spencer Lab, Newark, DE 19716, USA.
A common goal of persons post-stroke is to regain community ambulation. The plantar flexor muscles play an important role in propulsion generation and swing initiation as previous musculoskeletal simulations have shown. The purpose of this study was to demonstrate that simulation results quantifying changes in plantar flexor activation and function in individuals post-stroke were consistent with (1) the purpose of an intervention designed to enhance plantar flexor function and (2) expected muscle function during gait based on previous literature.
Methods:
Three-dimensional, forward dynamic simulations were created to determine the changes in model activation and function of the paretic ankle plantar flexor muscles for eight patients post-stroke after a 12-weeksFastFES gait retraining program.
Results:
An median increase of 0.07 (Range [−0.01,0.22]) was seen in simulated activation averaged across all plantar flexors during the double support phase of gait from pre- to post-intervention. A concurrent increase in walking speed and plantar flexor induced forward center of mass acceleration by the plantar flexors was seen post-intervention for seven of the eight subject simulations. Additionally, post-training, the plantar flexors had an simulated increase in contribution to knee flexion acceleration during double support.
Conclusions:
For the first time, muscle-actuated musculoskeletal models were used to simulate the effect of a gait retraining intervention on post-stroke muscle model predicted activation and function. The simulations showed a new pattern of simulated activation for the plantar flexor muscles after training, suggesting that the subjects activated these muscles with more appropriate timing following the intervention. Functionally, simulations calculated that the plantar flexors provided greater contribution to knee flexion acceleration after training, which is important for increasing swing phase knee flexion and foot clearance.
Keywords:
Gait, Stroke, Musculoskeletal simulation, Plantar flexors, Muscle function
Background
3The degree of locomotor impairment post-stroke can vary greatly [1], but a majority of individuals post stroke have decreased walking speed and abnormal gait kinematics [2]. These post-stroke gait impairments are a criticaltarget of rehabilitation. The use of treadmills has gained popularity as an intervention for gait retraining post-stroke [3-6]. Recent studies have investigated combining treadmill walking with more targeted rehabilitation methods such as functional electrical stimulation (FES) [7].In particular, impairment of the plantar flexors, typical of stroke gait, has been the focus of recent rehabilitation approaches [8,9] because of the importance of both foot clearance and forward propulsion in post stroke gait function [10].It has been shown that functional electrical stimulation of the plantar flexors during preswing, along with the paretic ankle dorsiflexors during swing, provided additional gait benefits including increased swing phase knee flexion, plantar flexion at toe-off, and forward
* Correspondence: bknarr@udel.edu
1 Biomechanics and Movement Science, University of Delaware, Newark, DE,USA
5 University of Delaware, 126 Spencer Lab, Newark, DE 19716, USAFull list of author information is available at the end of the article
JNER
JOURNAL OF NEUROENGINEERINGAND REHABILITATION
© 2013 Knarr et al.; licensee BioMed Central Ltd. This is an Open Access article distributed under the terms of the CreativeCommons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
3 Department of Mechanical Engineering, University of Delaware,Newark, DE, USA.
4 Department of Rehabilitation Medicine, Division of Physical Therapy, Emory University, Atlanta, GA, USA.
5 University of Delaware,126 Spencer Lab, Newark, DE 19716, USA.
Abstract
Background:A common goal of persons post-stroke is to regain community ambulation. The plantar flexor muscles play an important role in propulsion generation and swing initiation as previous musculoskeletal simulations have shown. The purpose of this study was to demonstrate that simulation results quantifying changes in plantar flexor activation and function in individuals post-stroke were consistent with (1) the purpose of an intervention designed to enhance plantar flexor function and (2) expected muscle function during gait based on previous literature.
Methods:
Three-dimensional, forward dynamic simulations were created to determine the changes in model activation and function of the paretic ankle plantar flexor muscles for eight patients post-stroke after a 12-weeksFastFES gait retraining program.
Results:
An median increase of 0.07 (Range [−0.01,0.22]) was seen in simulated activation averaged across all plantar flexors during the double support phase of gait from pre- to post-intervention. A concurrent increase in walking speed and plantar flexor induced forward center of mass acceleration by the plantar flexors was seen post-intervention for seven of the eight subject simulations. Additionally, post-training, the plantar flexors had an simulated increase in contribution to knee flexion acceleration during double support.
Conclusions:
For the first time, muscle-actuated musculoskeletal models were used to simulate the effect of a gait retraining intervention on post-stroke muscle model predicted activation and function. The simulations showed a new pattern of simulated activation for the plantar flexor muscles after training, suggesting that the subjects activated these muscles with more appropriate timing following the intervention. Functionally, simulations calculated that the plantar flexors provided greater contribution to knee flexion acceleration after training, which is important for increasing swing phase knee flexion and foot clearance.
Keywords:
Gait, Stroke, Musculoskeletal simulation, Plantar flexors, Muscle function
Background
3The degree of locomotor impairment post-stroke can vary greatly [1], but a majority of individuals post stroke have decreased walking speed and abnormal gait kinematics [2]. These post-stroke gait impairments are a criticaltarget of rehabilitation. The use of treadmills has gained popularity as an intervention for gait retraining post-stroke [3-6]. Recent studies have investigated combining treadmill walking with more targeted rehabilitation methods such as functional electrical stimulation (FES) [7].In particular, impairment of the plantar flexors, typical of stroke gait, has been the focus of recent rehabilitation approaches [8,9] because of the importance of both foot clearance and forward propulsion in post stroke gait function [10].It has been shown that functional electrical stimulation of the plantar flexors during preswing, along with the paretic ankle dorsiflexors during swing, provided additional gait benefits including increased swing phase knee flexion, plantar flexion at toe-off, and forward
* Correspondence: bknarr@udel.edu
1 Biomechanics and Movement Science, University of Delaware, Newark, DE,USA
5 University of Delaware, 126 Spencer Lab, Newark, DE 19716, USAFull list of author information is available at the end of the article
JNER
JOURNAL OF NEUROENGINEERINGAND REHABILITATION
© 2013 Knarr et al.; licensee BioMed Central Ltd. This is an Open Access article distributed under the terms of the CreativeCommons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
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