Effects of a Robot-aided Somatosensory Training on Proprioception and Motor Function in Stroke Survivors

Yeh, I-Ling; Holst-Wolf, Jessica; Elangovan, Naveen; Cuppone, Anna Vera; Lakshminarayan, Kamakshi; Capello, Leonardo; Masia, Lorenzo; Konczak, Jürgen

doi:10.21203/rs.3.rs-89369/v1

Cited by 3 publications

(5 citation statements)

References 25 publications

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“…Robotic technology has been developed to diagnose proprioceptive dysfunction of the upper limb. For example, recent studies using a wrist/hand exoskeleton robotic system have documented its usefulness in the evaluation of the joint position sense in healthy individuals and stroke survivors [51][52][53][54]. The current study extended such application to the ankle joint, which is a critical joint for balance and locomotion.…”

Section: Clinical Implications and Limitationsmentioning

confidence: 85%

“…Coupled with an adaptive psychophysical testing paradigm, it is capable ofreliably and comprehensively assessing two major modalities of proprioceptive function -ankle position and motion sense. It yields established psychophysical measures of proprioceptive bias and precision, which are known to be affected in clinical populations with compromised proprioception, such as survivors of stroke [54] or children with developmental coordination disorder [55]. The system is easy to use and does not require extensive training, making it feasible to use as a diagnostic tool in clinical settings.…”

Section: Discussionmentioning

confidence: 99%

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Robot-Aided Assessment of Human Ankle Joint Position Sense and Motion Sense

Huang

Zhong

Elangovan

et al. 2022

Preprint

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Background-Numerous neurological and orthopedic conditions impair ankle proprioception resulting in gait and balance deficits. However, current clinical practice lacks accurate and reliable methods to assess proprioceptive function. To address this gap, we developed a robotic assessment system that provides accurate, objective, and reliable measures of human ankle position and motion sense acuitythat reflectproprioceptive function at this joint.Methods-Ankle position sense and motion sense acuity were assessed in twenty healthy adult participantsemploying a psychophysical two-alternative forced-choice paradigm.An ankle robot deliveredtightly controlled passive, open kinematic ankle dorsiflexion/plantarflexion positions or velocities. The robot passively rotated aparticipant’s ankle to two distinctplantarflexed positions for position sense testing, orthe ankle was plantarflexed at two distinct velocities for motion sense testing. After experiencing the two stimuli, participants verbally indicated which ankle position was more plantarflexedor which motionwas perceived as faster. Based on a participant’s verbal responses, a psychometric function was fitted and the respective discrimination thresholds and intervals of uncertainty were derived. Additionally, test-retest reliability of the threshold measures was determined across three different experimental sessions for a subset of five participants.Results-Analysis yielded a mean position discrimination threshold of 0.80° (SD: ± 0.10°), and a mean motion discrimination threshold of 0.73°/s (SD: ± 0.11°/s). Test-retest reliability of the threshold measures based on the intraclass correlation coefficient (ICC) was moderate to excellent in position sense (range, ICC = 0.86 [0.50 - 0.98]) and motion sense (range, ICC = 0.86 [0.57 - 0.99]) testing.Conclusion -The results demonstrated the utility and reliability ofa robot-aided assessment of human ankle proprioceptive function paving the way to employ such systemsfor the fast and accurate diagnosisof proprioceptive dysfunction in clinical populations.

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Section: Clinical Implications and Limitationsmentioning

confidence: 85%

Section: Discussionmentioning

confidence: 99%

Robot-Aided Assessment of Human Ankle Joint Position Sense and Motion Sense

Huang

Zhong

Elangovan

et al. 2022

Preprint

Self Cite

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Section: Discussionmentioning

confidence: 99%

“…Consistent with this, in a recent study of people with chronic stroke, participants experienced improved wrist position sense accuracy following just two 24-minute sessions of robotic wrist training. 42 An increase in afferent input may drive improved tactile sense following motor rehabilitation. Regardless of whether motor practice involved object manipulation, study participants experienced increased afferent input from the skin, muscle, and joint receptors during motor practice.…”

Section: Discussionmentioning

confidence: 99%

Tactile Sensation Improves Following Motor Rehabilitation for Chronic Stroke: The VIGoROUS Randomized Controlled Trial

Borstad

Nichols-Larsen

Uswatte

et al. 2022

Neurorehabil Neural Repair

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Background. Up to 85% of people with chronic stroke experience somatosensory impairment, which contributes to poor sensorimotor control and non-use of the affected limb. Neurophysiological mechanisms suggest motor rehabilitation may improve tactile sense post-stroke, however, somatosensory recovery has rarely been reported in controlled trials. Objective. To compare the effect of four upper limb motor rehabilitation programs on the recovery of tactile sensation in adults with chronic stroke. Methods. Adults with chronic stroke and mild or moderate upper extremity hemiparesis ( n = 167) were enrolled in a multi-site randomized controlled trial. Participants completed three weeks of gaming therapy, gaming therapy with additional telerehabilition, Constraint-Induced Movement therapy, or traditional rehabilitation. Here, we report the results of a secondary outcome, tactile sensation, measured with monofilaments, before and after treatment, and 6 months later. Results. A mixed-effects general linear model revealed similar positive change in tactile sensitivity regardless of the type of training. On average, participants were able to detect a stimulus that was 32% and 33% less after training and at 6-month follow-up, respectively. One-third of participants experienced recategorization of their level of somatosensory impairment (e.g., regained protective sensation) following training. Poorer tactile sensation at baseline was associated with greater change. Conclusions. About one-third of individuals with mild/moderate chronic hemiparesis experience sustained improvements in tactile sensation following motor rehabilitation, regardless of the extent of tactile input in the rehabilitation program. Potential for sensory improvement is an additional motivator for those post-stroke. Characteristics of those who improve and mechanisms of improvement are important future questions. Clinicaltrials.gov NCT02631850

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“…VTGs provide vibratory input to the paretic limb of chronic stroke survivors and have been shown to promote neural plasticity and reduce spasticity [45,46]. Other studies have used robot-assisted somatosensory training and vibrotactile biofeedback devices [47,48].…”

Section: Discussionmentioning

confidence: 99%

Cortical Reorganization of Early Somatosensory Processing in Hemiparetic Stroke

Williamson¹,

Sikora²,

Parmar³

et al. 2022

Preprint

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The cortical motor system can be reorganized following a stroke, with an increasing recruitment of the contralesional hemisphere. However, it is unknown whether a similar hemispheric shift occurs in the somatosensory system to adapt to this motor change, and whether this is related to movement impairments. This proof-of-concept study assessed somatosensory evoked potentials (SEPs), P50 and N100, in hemiparetic stroke participants and age-matched controls using high-density electroencephalograph (EEG) recordings during tactile finger stimulation. The laterality index was calculated to determine hemispheric dominance of the SEP and re-confirmed with source localization. The study found that latencies of P50 and N100 were significantly delayed in stroke brains when stimulating the paretic hand. The amplitude of P50 was negatively correlated with Fügl-Meyer Upper Extremity Motor Score in stroke. Bilateral cortical responses were detected in stroke, while only contralateral cortical responses were shown in controls, resulting in a significant difference in the laterality index. These results suggested that somatosensory reorganization after stroke involves increased recruitment of ipsilateral cortical regions. This reorganization delays the latency of somatosensory processing after a stroke. This research provided new insights related to the somatosensory reorganization after stroke, which could enrich future hypothesis-driven therapeutic rehabilitation strategies from a sensory or sensory-motor perspective.

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Effects of a Robot-aided Somatosensory Training on Proprioception and Motor Function in Stroke Survivors

Cited by 3 publications

References 25 publications

Robot-Aided Assessment of Human Ankle Joint Position Sense and Motion Sense

Robot-Aided Assessment of Human Ankle Joint Position Sense and Motion Sense

Tactile Sensation Improves Following Motor Rehabilitation for Chronic Stroke: The VIGoROUS Randomized Controlled Trial

Cortical Reorganization of Early Somatosensory Processing in Hemiparetic Stroke

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