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Neuroradiology
Published in: Neuroradiology 4/2017

01-04-2017 | Review

Diffusion tensor imaging as a prognostic biomarker for motor recovery and rehabilitation after stroke

Authors: Josep Puig, Gerard Blasco, Gottfried Schlaug, Cathy M Stinear, Pepus Daunis-i-Estadella, Carles Biarnes, Jaume Figueras, Joaquín Serena, Maria Hernández-Pérez, Angel Alberich-Bayarri, Mar Castellanos, David S Liebeskind, Andrew M Demchuk, Bijoy K Menon, Götz Thomalla, Kambiz Nael, Max Wintermark, Salvador Pedraza

Published in: Neuroradiology | Issue 4/2017

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Abstract

Purpose

Despite improved acute treatment and new tools to facilitate recovery, most patients have motor deficits after stroke, often causing disability. However, motor impairment varies considerably among patients, and recovery in the acute/subacute phase is difficult to predict using clinical measures alone, particularly in severely impaired patients. Accurate early prediction of recovery would help rationalize rehabilitation goals and improve the design of trials testing strategies to facilitate recovery.

Methods

We review the role of diffusion tensor imaging (DTI) in predicting motor recovery after stroke, in monitoring treatment response, and in evaluating white matter remodeling. We critically appraise DTI studies and discuss their limitations, and we explore directions for future study.

Results

Growing evidence suggests that combining clinical scores with information about corticospinal tract (CST) integrity can improve predictions about motor outcome. The extent of CST damage on DTI and/or the overlap between the CST and a lesion are key prognostic factor that determines motor performance and outcome. Three main strategies to quantify stroke-related CST damage have been proposed: (i) measuring FA distal to the stroke area, (ii) measuring the number of fibers that go through the stroke with tractography, and (iii) measuring the overlap between the stroke and a CST map derived from healthy age- and gender-matched controls.

Conclusion

Recovery of motor function probably involves remodeling of the CST proper and/or a greater reliance on alternative motor tracts through spontaneous and treatment-induced plasticity. DTI-metrics represent promising clinical biomarkers to predict motor recovery and to monitor and predict the response to neurorehabilitative interventions.
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Metadata
Title
Diffusion tensor imaging as a prognostic biomarker for motor recovery and rehabilitation after stroke
Authors
Josep Puig
Gerard Blasco
Gottfried Schlaug
Cathy M Stinear
Pepus Daunis-i-Estadella
Carles Biarnes
Jaume Figueras
Joaquín Serena
Maria Hernández-Pérez
Angel Alberich-Bayarri
Mar Castellanos
David S Liebeskind
Andrew M Demchuk
Bijoy K Menon
Götz Thomalla
Kambiz Nael
Max Wintermark
Salvador Pedraza
Publication date
01-04-2017
Publisher
Springer Berlin Heidelberg
Published in
Neuroradiology / Issue 4/2017
Print ISSN: 0028-3940
Electronic ISSN: 1432-1920
DOI
https://doi.org/10.1007/s00234-017-1816-0

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