Functional Strength Training and Movement Performance Therapy for Upper Limb Recovery Early Poststroke-Efficacy, Neural Correlates, Predictive Markers, and Cost-Effectiveness: FAST-INdiCATE Trial

Variation in physiological deficits underlying upper limb paresis after stroke could influence how people recover and to which physical therapy they best respond. To determine whether functional strength training (FST) improves upper limb recovery more than movement performance therapy (MPT). To ide...

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Published in:Frontiers in neurology 2018-01, Vol.8, p.733-733
Main Authors: Hunter, Susan M, Johansen-Berg, Heidi, Ward, Nick, Kennedy, Niamh C, Chandler, Elizabeth, Weir, Christopher John, Rothwell, John, Wing, Alan M, Grey, Michael J, Barton, Garry, Leavey, Nick Malachy, Havis, Claire, Lemon, Roger N, Burridge, Jane, Dymond, Amy, Pomeroy, Valerie M
Format: Article
Language:English
Subjects:
magnetic resonance imaging
Neuroscience
physical therapy
rehabilitation
stroke
transcranial magnetic stimulation
upper limb
prediction
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Summary:Variation in physiological deficits underlying upper limb paresis after stroke could influence how people recover and to which physical therapy they best respond. To determine whether functional strength training (FST) improves upper limb recovery more than movement performance therapy (MPT). To identify: (a) neural correlates of response and (b) whether pre-intervention neural characteristics predict response. Explanatory investigations within a randomised, controlled, observer-blind, and multicentre trial. Randomisation was computer-generated and concealed by an independent facility until baseline measures were completed. Primary time point was outcome, after the 6-week intervention phase. Follow-up was at 6 months after stroke. With some voluntary muscle contraction in the paretic upper limb, not full dexterity, when recruited up to 60 days after an anterior cerebral circulation territory stroke. Conventional physical therapy (CPT) plus either MPT or FST for up to 90 min-a-day, 5 days-a-week for 6 weeks. FST was "hands-off" progressive resistive exercise cemented into functional task training. MPT was "hands-on" sensory/facilitation techniques for smooth and accurate movement. The primary efficacy measure was the Action Research Arm Test (ARAT). Neural measures: fractional anisotropy (FA) corpus callosum midline; asymmetry of corticospinal tracts FA; and resting motor threshold (RMT) of motor-evoked potentials. Covariance models tested ARAT change from baseline. At outcome: correlation coefficients assessed relationship between change in ARAT and neural measures; an interaction term assessed whether baseline neural characteristics predicted response. 288 Participants had: mean age of 72.2 (SD 12.5) years and mean ARAT 25.5 (18.2). For 240 participants with ARAT at baseline and outcome the mean change was 9.70 (11.72) for FST + CPT and 7.90 (9.18) for MPT + CPT, which did not differ statistically (  = 0.298). Correlations between ARAT change scores and baseline neural values were between 0.199,  = 0.320 for MPT + CPT RMT (  = 27) and -0.147,  = 0.385 for asymmetry of corticospinal tracts FA (  = 37). Interaction effects between neural values and ARAT change between baseline and outcome were not statistically significant. There was no significant difference in upper limb improvement between FST and MPT. Baseline neural measures did not correlate with upper limb recovery or predict therapy response. Current Controlled Trials: ISRCT 19090862, http://www.con
ISSN:1664-2295
1664-2295
DOI:10.3389/fneur.2017.00733