Researchers have explored a variety of neurorehabilitation approaches to restore normal walking function following a stroke. However, there is currently no objective means for prescribing and implementing treatments that are likely to maximize recovery of walking function for any particular patient. As a first step toward optimizing neurorehabilitation effectiveness, this study develops and evaluates a patient-specific synergy-controlled neuromusculoskeletal simulation framework that can predict walking motions for an individual post-stroke. The main question we addressed was whether driving a subject-specific neuromusculoskeletal model with muscle synergy controls (5 per leg) facilitates generation of accurate walking predictions compared ...
textUnderstanding the underlying coordination mechanisms that lead to a patient’s poor walking perfo...
Background: Persons with post-stroke hemiparesis usually walk slowly and asymmetrically. Stroke seve...
Individuals, post-stroke, present with an array of changes to the neuromuscular system function such...
The understanding of biomechanical deficits and impaired neural control of gait after stroke is cruc...
Neuromusculoskeletal simulation provides a promising platform to inform the design of assistive devi...
Current real-time neuromechanical model-based (NM) controllers for wearable robotics, such as exoske...
textStroke is the leading cause of long term disability with improved walking being an important goa...
It has been largely suggested in neuroscience literature that to generate a vast variety of movement...
Physics-based predictive simulations of human movement have the potential to support personalized me...
We implemented direct collocation on a full-body neuromusculoskeletal model to calculate muscle forc...
We implemented direct collocation on a full-body neuromusculoskeletal model to calculate muscle forc...
Current knowledge of neural and neuromuscular processes controlling gait and movement as well as an ...
Physics-based simulations of walking have the theoretical potential to support clinical decision-mak...
Physics-based simulations of walking have the theoretical potential to support clinical decision-mak...
textUnderstanding the underlying coordination mechanisms that lead to a patient’s poor walking perfo...
Background: Persons with post-stroke hemiparesis usually walk slowly and asymmetrically. Stroke seve...
Individuals, post-stroke, present with an array of changes to the neuromuscular system function such...
The understanding of biomechanical deficits and impaired neural control of gait after stroke is cruc...
Neuromusculoskeletal simulation provides a promising platform to inform the design of assistive devi...
Current real-time neuromechanical model-based (NM) controllers for wearable robotics, such as exoske...
textStroke is the leading cause of long term disability with improved walking being an important goa...
It has been largely suggested in neuroscience literature that to generate a vast variety of movement...
Physics-based predictive simulations of human movement have the potential to support personalized me...
We implemented direct collocation on a full-body neuromusculoskeletal model to calculate muscle forc...
We implemented direct collocation on a full-body neuromusculoskeletal model to calculate muscle forc...
Current knowledge of neural and neuromuscular processes controlling gait and movement as well as an ...
Physics-based simulations of walking have the theoretical potential to support clinical decision-mak...
Physics-based simulations of walking have the theoretical potential to support clinical decision-mak...
textUnderstanding the underlying coordination mechanisms that lead to a patient’s poor walking perfo...
Background: Persons with post-stroke hemiparesis usually walk slowly and asymmetrically. Stroke seve...
Individuals, post-stroke, present with an array of changes to the neuromuscular system function such...