Stroke Clinical Trial
We will test whether robot driven, goal directed, trajectory corrected exercise enhances motor outcome in the upper limb of stroke patients better than matched motor activity on an upper body ergometer (monark).
Upper extremity (UE) weakness post-stroke occurs in 70-80% of patients. By 3 months this
complaint persists in 40% of patients, and by 6 months this complaint persists in a similar
percentage of patients (1). Greater improvement in motor functional recovery was achieved in
patients with intact sensation. Shoulder pain persisted in 20% of patients (2). Most of the
arm recovery occurs in the initial 3 months post-stroke (2,3,4). The Copenhagen stroke study
found 79% of patients with mild UE paresis achieving functional motor recovery compared to
18% of patients with severe UE paresis (4). Katrak P et al. found early shoulder shrug and
synergistic hand movements to be useful bedside predictors of functional motor recovery of
the UE (5). The initial grade of paresis (measured on admission in the hospital) is the most
important predictor of motor recovery after stroke, with initial paralysis implying the
worst prognosis for subsequent motor recovery (6). Perceptual inattention does impact upon
UE action and functional recovery (7). The UE weakness and functional motor recovery lags
behind lower extremity (LE) weakness and functional motor recovery because of the complexity
of motor skills needed for daily living tasks.
Due to the persistence of upper extremity weakness, different rehabilitation techniques such
as Constraint Induced (CI) (8,9,10) and robotic (11,12,13) therapies were developed to help
with meaningful functional motor recovery in the paretic arm (unilateral arm training). Both
of these forced-use interventions focus on the paretic arm only. The main drawback of the CI
therapy is that subjects need to have some degree of voluntary movement both at the wrist
and the digits. Bilateral arm training with rhythmic clueing (BATRAC) has been used in
chronic stroke patients and has been found to improve functional motor performance in the
paretic UE (14). The authors in a recent paper showed BATRAC inducing reorganization in
contraleisonal motor networks based on functional MRI (15). Facilitation of paretic arm
movement by the non-paretic arm (bimanual movement) is thought to be superior to individual
paretic arm movement, which indicates both arms to be a coordinated brain unit (16).
Richards L et al., in their review article (17) and Vander Lee J et al., in their
meta-analysis of randomized stroke trials (18) on therapeutic interventions to improve UE
function, found extensive practice to be the most important factor irrespective of the type
of intervention instituted. Early repetitive sensorimotor stimulation of the arm results in
long-lasting functional motor recovery (19).
The overall goal of this study is to determine whether bilateral arm training with upper
body ergometer is as or more effective in upper extremity functional recovery than
unilateral arm training with robot in patients with a recent ischemic and hemorrhagic
stroke.
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Allocation: Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Single Group Assignment, Masking: Open Label, Primary Purpose: Treatment
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