2013
DOI: 10.3389/fncom.2013.00097
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Neuromotor recovery from stroke: computational models at central, functional, and muscle synergy level

Abstract: Computational models of neuromotor recovery after a stroke might help to unveil the underlying physiological mechanisms and might suggest how to make recovery faster and more effective. At least in principle, these models could serve: (i) To provide testable hypotheses on the nature of recovery; (ii) To predict the recovery of individual patients; (iii) To design patient-specific “optimal” therapy, by setting the treatment variables for maximizing the amount of recovery or for achieving a better generalization… Show more

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Cited by 21 publications
(13 citation statements)
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“…Unsupervised learning is related to the concept of use-dependent learning, which refers to the phenomenon that the motor system can modify its performance through pure repetition of movements, without external feedback as to the success or failure of the movement [ 103 , 111 ]. Several initial models of network dynamics after stroke incorporate unsupervised learning (see review [ 25 ]). Unsupervised learning, together with homeostatic plasticity, likely plays a role in map and neural reorganization post-stroke, and presumably in decreasing movement variability and thereby improving functional performance [ 89 , 112 ].…”
Section: Reviewmentioning
confidence: 99%
See 1 more Smart Citation
“…Unsupervised learning is related to the concept of use-dependent learning, which refers to the phenomenon that the motor system can modify its performance through pure repetition of movements, without external feedback as to the success or failure of the movement [ 103 , 111 ]. Several initial models of network dynamics after stroke incorporate unsupervised learning (see review [ 25 ]). Unsupervised learning, together with homeostatic plasticity, likely plays a role in map and neural reorganization post-stroke, and presumably in decreasing movement variability and thereby improving functional performance [ 89 , 112 ].…”
Section: Reviewmentioning
confidence: 99%
“…There are also models that have focused on altered network dynamics following injury (e.g. [ 21 24 ]), and now, the first few models that have incorporated specific aspects of rehabilitation into their dynamics (see below and related reviews [ 25 , 26 ]). What is new about the computational neurorehabilitation approach is that it attempts to mathematically model the mechanisms underlying the rehabilitation process itself in order to understand the recovery of motor behavior, again via both restitution and compensation.…”
Section: Introductionmentioning
confidence: 99%
“…Uncovering a common underlying neural framework for the modular control of movements and its dysfunction represents an interesting avenue for future work. Casadio et al ( 2013 ) review the state of the art of computational models for neuromotor recovery from stroke through exercise, and their implications for treatment. The review specifically covers models of recovery at central, functional and muscle synergy level.…”
Section: Reviews and Perspectivesmentioning
confidence: 99%
“…The purpose of muscle synergies analysis in people who suffered from motor deficits due to inappropriate muscle coordination is to reveal the underlying physiological mechanisms and offer suggestions on efficient recovery process (Safavynia et al, 2011 ; Casadio et al, 2013 ). Some studies have been conducted to find out how muscle synergies were affected after stroke.…”
Section: Introductionmentioning
confidence: 99%