Stroke Clinical Trial
Official title:
Interhemispheric Contributions to Neuroplasticity and Motor Learning After Stroke
After a stroke the excitability of the brain decreases on the stroke side and increases on
the opposite, non-stroke side. These changes make use of the stroke-affected arm difficult
and slow recovery. Rehabilitation exercises that increase arm use after stroke help increase
brain excitability, but the net effect of this approach is low. New therapies are needed
that restore more equal levels of brain excitability between the two sides. Brain
stimulation is a noninvasive way to affect activity the excitability of brain cells. Pairing
brain stimulation with exercises that require patients to learn new movements may help the
brain to learn. Using stimulation that reduces activity in the side opposite to the stroke
can increase activity on the stroke -affected side, through connections between the two
brain hemispheres. The purpose of this study is to test if brain stimulation on the side
opposite to the stroke, paired with arm movement exercises, can help patients learn new arm
movements and improve arm function.
In this study people with stroke will receive brain stimulation over two different areas on
the side of the brain opposite to the stroke: 1) those areas responsible for movement and 2)
those responsible for sensation. These experiments will test both the short and long term
effects of brain stimulation on patients' learning and arm function and will allow us to
identify which area of the brain best improves learning and arm function. These experiments
have the potential to improve the effectiveness of rehabilitation after stroke. The proposed
study is among the first to test stimulation over the side of the brain opposite to the
stroke damage and at multiple sites. This unique approach may help stimulate the development
of new methods for stroke rehabilitation.
The overall objective of this proposal is to examine the efficacy of new approaches to
stroke recovery based on recent reports of interhemispheric contributions to neuroplastic
change and motor skill learning. After stroke, cortical excitability is decreased in the
ipsilesional and increased in the contralesional primary motor cortices (M1). Combined,
these changes hamper hemiparetic arm use and impede functional recovery. Increasing
hemiparetic arm use elevates the excitability of the ipsilesional cortex and improves
function. Importantly, skilled motor practice raises cortical excitability to an even
greater extent than merely increasing generalized use. However, the impact of increasing
cortical excitability on recovery of function after stroke is limited, perhaps because the
rate of change associated with both increasing use and learning new motor skills is low.
Repetitive transcranial magnetic stimulation (rTMS) is a noninvasive method of brain
stimulation. In humans, rTMS applied at high frequencies can increase cortical excitability;
conversely, at low frequencies it can decrease cortical excitability. While rTMS in
isolation can change cortical excitability after stroke its impact on neuroplastic change is
small, likely reflecting a lack of consolidation in the absence of paired motor behaviour.
Modulating the activity in a given neural network with brain stimulation prior to motor
skill practice may in essence prime the system and enhance the neuroplastic effects
associated with learning new motor skills. Yet to date, few studies have paired rTMS with
practice of a novel motor task and assessed changes in motor function or behaviour.
Intuitively, it seems simplest to employ high frequency rTMS in the ipsilesional cortex to
enhance cortical excitability. However, because of the difficulty of locating stimulation
targets in the damaged hemisphere, low-frequency rTMS applied over the contralesional cortex
may be the better approach. Though the direct effect of low-frequency rTMS in the human
cortex is to suppress activity in the stimulated region it also indirectly enhances distant
activity. Low-frequency rTMS over M1 increases cortical activity in the contralateral M1
homologue. We recently extended this finding to the primary sensory cortex (S1);
demonstrating that low-frequency rTMS over left S1 increased excitability in (i.e.,
disinhibited) right S1. Therefore, suppressing the contralesional cortex to enhance
ipsilesional cortical activity may facilitate a neural environment that is conducive for
neuroplastic change.
Taken together these data suggest that inhibitory brain stimulation over the contralesional
cortex, paired with skilled motor practice, may offer a new approach for stroke
rehabilitation. To better understand whether this approach has merit, we propose to test two
specific aims in separate experiments.
Specific Aim: To test the cumulative effects of repeated sessions that pair brain
stimulation over M1c versus S1c with skilled motor practice in individuals with stroke.
We will assess hemiparetic arm motor and sensory function, motor performance/ motor skill
acquisition (repeated sequence response times), cortical excitability, and neuroelectric
activity in individuals with chronic sub-cortical stroke. Pre-brain stimulation measures
will be compared with those obtained after 5 days of training paired with brain stimulation
at a separate no-rTMS retention test to assess the cumulative effects of brain stimulation.
;
Allocation: Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Parallel Assignment, Masking: Double Blind (Subject, Outcomes Assessor), Primary Purpose: Treatment
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