Mindful SensoriMotor Therapy combined with brain modulation for the treatment of pain in individuals with disarticulation or nerve injuries: a single-arm clinical trial

Damercheli, Shahrzad; Buist, Mirka; Ortiz-Catalán, Max

doi:10.1136/bmjopen-2021-059348

Cited by 3 publications

(2 citation statements)

References 49 publications

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“…In addition, with respect to clinicians, the significance of using tDCS could be reduced consultation time. Moreover, the effectiveness and efficiency of MPR-based PLP treatments, such as Phantom motor execution, can be enhanced 29 , 40 , 41 .…”

Section: Discussionmentioning

confidence: 99%

Performance in myoelectric pattern recognition improves with transcranial direct current stimulation

Damercheli,

Morrenhof,

Ahmed

et al. 2024

Sci Rep

Self Cite

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Sensorimotor impairments, resulting from conditions like stroke and amputations, can profoundly impact an individual’s functional abilities and overall quality of life. Assistive and rehabilitation devices such as prostheses, exo-skeletons, and serious gaming in virtual environments can help to restore some degree of function and alleviate pain after sensorimotor impairments. Myoelectric pattern recognition (MPR) has gained popularity in the past decades as it provides superior control over said devices, and therefore efforts to facilitate and improve performance in MPR can result in better rehabilitation outcomes. One possibility to enhance MPR is to employ transcranial direct current stimulation (tDCS) to facilitate motor learning. Twelve healthy able-bodied individuals participated in this crossover study to determine the effect of tDCS on MPR performance. Baseline training was followed by two sessions of either sham or anodal tDCS using the dominant and non-dominant arms. Assignments were randomized, and the MPR task consisted of 11 different hand/wrist movements, including rest or no movement. Surface electrodes were used to record EMG and the MPR open-source platform, BioPatRec, was used for decoding motor volition in real-time. The motion test was used to evaluate performance. We hypothesized that using anodal tDCS to increase the excitability of the primary motor cortex associated with non-dominant side in able-bodied individuals, will improve motor learning and thus MPR performance. Overall, we found that tDCS enhanced MPR performance, particularly in the non-dominant side. We were able to reject the null hypothesis and improvements in the motion test’s completion rate during tDCS (28% change, p-value: 0.023) indicate its potential as an adjunctive tool to enhance MPR and motor learning. tDCS appears promising as a tool to enhance the learning phase of using assistive devices using MPR, such as myoelectric prostheses.

show abstract

Section: Discussionmentioning

confidence: 99%

Performance in myoelectric pattern recognition improves with transcranial direct current stimulation

Damercheli,

Morrenhof,

Ahmed

et al. 2024

Sci Rep

Self Cite

View full text Add to dashboard Cite

show abstract

“…With respect to clinicians, the signi cance of using tDCS could be reduced consultation time. Moreover, the effectiveness and e ciency of MPR-based PLP treatments, such as Phantom Motor Execution, can be enhanced [29,40,41].…”

Section: Discussionmentioning

confidence: 99%

Performance in Myoelectric Pattern Recognition Improves with transcranial Direct Current Stimulation

Damercheli,

Morrenhof,

Ortiz-Catalan

2023

Preprint

Self Cite

View full text Add to dashboard Cite

Sensorimotor impairments, resulting from conditions like stroke and amputations, can profoundly impact an individual’s functional abilities and overall quality of life. Assistive and rehabilitation devices such as prostheses, exo-skeletons, and serious gaming in virtual environments can help to restore some degree of function and alleviate pain after sensorimotor impairments. Myoelectric Pattern Recognition (MPR) has gained popularity in the past decades as it provides superior control over said devices, and therefore efforts to facilitate and improve performance in MPR can result in better rehabilitation outcomes. One possibility to enhance MPR is to employ transcranial Direct Current Stimulation (tDCS) to facilitate motor learning. Twelve healthy able-bodied individuals participated in this crossover study to determine the effect of tDCS on MPR performance. Baseline training was followed by two sessions of either sham or anodal tDCS using the dominant and non-dominant arms. Assignments were randomized, and the MPR task consisted of 11 different hand/wrist movements, including rest or no movement. Surface electrodes were used to record EMG and the MPR open-source platform, BioPatRec, was used for decoding motor volition in real-time. The Motion Test was used to evaluate performance. We hypothesized that using anodal tDCS to increase the excitability of the primary motor cortex associated with non-dominant side in able-bodied individuals, will improve motor learning and thus MPR performance. Overall, we found that tDCS enhanced MPR performance, particularly in the non-dominant side. We were able to reject the null hypothesis and improvements in the Motion Test’s Completion Rate during tDCS (28% change, p-value: 0.023) indicate its potential as an adjunctive tool to enhance MPR and motor learning. tDCS appears promising as a tool to enhance the learning phase of using assistive devices using MPR, such as myoelectric prostheses.

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Development and Validation of a Wearable Device to Provide Rich Somatosensory Stimulation for Rehabilitation After Sensorimotor Impairment

Buist

Damercheli

Truong

et al. 2023

IEEE Trans. Biomed. Circuits Syst.

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Mindful SensoriMotor Therapy combined with brain modulation for the treatment of pain in individuals with disarticulation or nerve injuries: a single-arm clinical trial

Cited by 3 publications

References 49 publications

Performance in myoelectric pattern recognition improves with transcranial direct current stimulation

Performance in myoelectric pattern recognition improves with transcranial direct current stimulation

Performance in Myoelectric Pattern Recognition Improves with transcranial Direct Current Stimulation

Development and Validation of a Wearable Device to Provide Rich Somatosensory Stimulation for Rehabilitation After Sensorimotor Impairment

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