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Motor adaptation and generalization are believed to occur via the integration of various forms of sensory feedback for a congruent representation of the body's position in space along with estimation of inertial properties of the limb segments for accurate specification of movement. Thus, motor adaptation is often studied within curated environments incorporating a "mis-match" between different sensory systems (i.e. a visual field shift via prism googles or a visuomotor rotation via virtual reality environment) and observing how motor plans change based on this mis-match. However, these adaptations are environment-specific and show little generalization outside of their restricted experimental setup. There remains a need for motor adaptation research that demonstrates motor learning that generalizes to other environments and movement types. This work could then inform physical and occupational therapy neurorehabilitation interventions targeted at addressing motor deficits.
Voluntary movement and sensory perception are fundamental aspects of the human experience. Senses such as visual and proprioceptive feedback inform movement by continuously providing the central nervous system with information on limb location, movement error, and task performance. However, the specific mechanisms behind how different forms of sensory information are used to adapt and generalize movement remain poorly understood.
Motor adaptation, or the modification of movement based on error feedback (Martin et al., 1996), is often elicited during rehabilitation but must be generalized to functional performance, such as activities of daily living, in order to successfully rehabilitate motor deficits following stroke. Motor adaptation and generalization are believed to occur via the integration of various forms of sensory feedback for a congruent representation of the body's position in space along with estimation of inertial properties of the limb segments for accurate specification of movement. Thus, motor adaptation is often studied within curated environments incorporating a "mis-match" between different sensory systems (i.e. a visual field shift via prism googles or a visuomotor rotation via virtual reality environment) and observing how motor plans change based on this mis-match. However, these adaptations are environment-specific and show little generalization outside of their restricted experimental setup. There remains a need for motor adaptation research that demonstrates motor learning that generalizes to other environments and movement types. This work could then inform physical and occupational therapy neurorehabilitation interventions targeted at addressing motor deficits.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Posterior parietal cortex group | Experimental | Posterior parietal cortex group, which will receive the stimulation to their left posterior parietal cortex |
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| Cerebellum group | Experimental | Cerebellum group, which will receive stimulation to their right cerebellum, |
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| Sham group | Sham Comparator | Sham group, which will have the electrode cap placed on their head but receive no stimulation |
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| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| Comparing motor adaptation reaching performance | Behavioral | By comparing motor adaptation reaching performance between these three groups, the investigators can examine how stimulation to each specific area of the brain modulates different aspects of motor adaptation |
| Measure | Description | Time Frame |
|---|---|---|
| Initial direction error, or difference between participant's fingertip direction | Initial direction error, or difference between participant's fingertip direction at the timepoint of peak velocity relative to a linear path to the target. As for time frame, this is a single-visit study. Initial direction error will be compared during baseline reaching and following 20 minutes of non-invasive neural stimulation. | Completion of the study visit, approx 20 minutes |
| Initial direction error variance | Initial direction error variance across multiple trials. | Completion of the study visit, approx 20 minutes |
| Measure | Description | Time Frame |
|---|---|---|
| Final position error | Secondary outcome: final position error, or distance from participant's fingertip position at the conclusion of the reach to the center of the target. Similar to above, this measure will be compared during baseline and following 20 minutes of stimulation. | Completion of the study visit, approx 20 min |
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Inclusion Criteria:
Exclusion Criteria:
Seizure and/or diagnosis of epilepsy Fainting spells Concussion with loss of consciousness Ringing in the ears (tinnitus) Cochlear implants Migraines Diagnosed psychological or neurological condition Metal in the scalp
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| Name | Role | Phone | Extension | |
|---|---|---|---|---|
| Brooke Dexheimer, PhD, OTD, OTR/L | Contact | 563-547-0125 | dexheimerb@vcu.edu |
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| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| Virginia Commonwealth University Medical Center | Recruiting | Richmond | Virginia | 23219 | United States |
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The study will have three groups: (15 people per group) 1) posterior parietal cortex group, which will receive the stimulation to their left posterior parietal cortex, 2) cerebellum group, which will receive stimulation to their right cerebellum, and 3) sham group, which will have the electrode cap placed on their head but receive no stimulation. By comparing motor adaptation reaching performance between these three groups, the investigators can examine how stimulation to each specific area of the brain modulates different aspects of motor adaptation.
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| Final position error variance across multiple trials. |
Final position error variance across multiple trials. |
| Completion of the study visit, approx 20 min |
| Deviation from linearity | Deviation from linearity, or a ratio of minimum and maximum displacement across the parallel and perpendicular planes of the reaching movement. | Completion of the study visit, approx 20 min |
| Peak tangential velocity | Peak tangential velocity, or highest tangential velocity reached during reach. | Completion of the study visit, approx 20 min |