Multimodal imaging of brain reorganization in motor areas of the contralesional hemisphere of well recovered patients after capsular stroke

doi:10.1093/brain/awh713

Brain Advance Access originally published online on December 19, 2005
Brain 2006 129(3):791-808; doi:10.1093/brain/awh713

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Multimodal imaging of brain reorganization in motor areas of the contralesional hemisphere of well recovered patients after capsular stroke

Christian Gerloff¹^,2, Khalaf Bushara², Alexandra Sailer¹, Eric M. Wassermann⁴, Robert Chen², Takahiro Matsuoka², Daniel Waldvogel², George F. Wittenberg³, Kenji Ishii², Leonardo G. Cohen³ and Mark Hallett²

¹ Cortical Physiology Research Group, Department of Neurology, Eberhard–Karls University Medical School, Tuebingen, Germany; Sections of ² Human Motor Control and ³ Human Cortical Physiology, Medical Neurology Branch and ⁴ Brain Stimulation Unit, National Institute of Neurological Disorders and Stroke, National Institutes of Health, Bethesda, MD, USA

Correspondence to: Christian Gerloff, MD, Department of General Neurology, Hertie Institute for Clinical Brain Research, University of Tuebingen, Hoppe-Seyler Street 3, 72076 Tuebingen, Germany E-mail: christian.gerloff{at}uni-tuebingen.de or Mark Hallett, MD, NINDS, National Institutes of Health, 10 Center Drive, MSC-1428, Bethesda, Maryland 20892, USA, E-mail: hallettm{at}ninds.nih.gov

Clinical recovery after stroke can be significant and has beenattributed to plastic reorganization and recruitment of novelareas previously not engaged in a given task. As equivocal resultshave been reported in studies using single imaging or electrophysiologicalmethods, here we applied an integrative multimodal approachto a group of well-recovered chronic stroke patients (n = 11;aged 50–81 years) with left capsular lesions. Focal activationduring recovered hand movements was assessed with EEG spectralanalysis and H₂¹⁵O-PET with EMG monitoring, cortico–corticalconnectivity with EEG coherence analysis (cortico–corticalcoherence) and corticospinal connectivity with transcranialmagnetic stimulation (TMS). As seen from comparisons with age-matchedcontrols, our patients showed enhanced recruitment of the lateralpremotor cortex of the lesioned hemisphere [Brodmann area (BA)6], lateral premotor and to a lesser extent primary sensorimotorand parietal cortex of the contralesional hemisphere (CON-H;BA 4 and superior parietal lobule) and left cerebellum (patientsversus controls, Z > 3.09). EEG coherence analysis showedthat after stroke cortico–cortical connections were reducedin the stroke hemisphere but relatively increased in the CON-H(ANOVA, contrast analysis, P < 0.05), suggesting a shiftof functional connectivity towards the CON-H. Nevertheless,fast conducting corticospinal transmission originated exclusivelyfrom the lesioned hemisphere. No direct ipsilateral motor evokedpotentials (MEPs) could be elicited with TMS over the contralesionalprimary motor cortex (iM1) in stroke patients. We conclude that(i) effective recovery is based on enhanced utilization of ipsi-and contralesional resources, (ii) basic corticospinal commandsarise from the lesioned hemisphere without recruitment of (‘latent’)uncrossed corticospinal tract fibres and (iii) increased contralesionalactivity probably facilitates control of recovered motor functionby operating at a higher-order processing level, similar tobut not identical with the extended network concerned with complexmovements in healthy subjects.

Key Words: Plasticity; stroke; recovery; motor control; motor cortex

Abbreviations: APB = abductor pollicis brevis muscle; BA = Brodmann area; COG = center of gravity; CON-H = contralesional hemisphere; DAM-H = damaged (stroke) hemisphere; EOI = electrode of interest; EDC = extensor digitorum communis; ERD = event-related desynchronization; FWHM = full width at half maximum; iM1 = ipsilateral (= contralesional) primary motor cortex; M1 = primary motor cortex; MEP = motor evoked potential; MRC = Medical Research Council; MT = motor threshold; NAP = number of active positions (from which TMS responses are elicited); OP = optimal point for eliciting a defined muscle response with TMS; POI = (electrode) pairs of interest; PT = pyramidal tract; rCBF = regional cerebral blood flow; ROI = region of interest; SMA = supplementary motor area; SPL = superior parietal lobule; SPM = statistical parametric map; tDCS = transcranial direct current stimulation; tanh^–1 = inverse hyperbolic tangent; TMS = transcranial magnetic stimulation; TRCoh = task-related coherence; TrlogPow = task-related log-transformed power; TRPow = task-related power; TRtanh^–1Coh = task-related inverse hyperbolic tangent-transformed coherence

Received July 31, 2005. Revised September 29, 2005. Accepted November 7, 2005.

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