Vicarious function within the human primary motor cortex?: A longitudinal fMRI stroke study

doi:10.1093/brain/awh456

Brain Advance Access originally published online on February 23, 2005
Brain 2005 128(5):1122-1138; doi:10.1093/brain/awh456

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Vicarious function within the human primary motor cortex?

A longitudinal fMRI stroke study

Assia Jaillard¹^,4, Chantal Delon Martin⁴, Katia Garambois¹, Jean François Lebas²^,4 and Marc Hommel¹^,3^,4

¹ Department of Neurology, Stroke Unit, ² Unité de RMN Service of Neuroradiology, ³ Inserm, CIC 003, University Hospital and ⁴ Inserm, U594-University Joseph Fourier, Grenoble, France

Correspondence to: Dr Assia Jaillard, Département de Neurologie—Unité Neuro-vasculaire, Centre Hospitalier Universitaire de Grenoble, BP 217-38043 Grenoble Cedex 9, France E-mail: AJaillard{at}chu-grenoble.fr

While experimental studies in the monkey have shown that motorrecovery after partial destruction of the hand motor cortexwas based on adjacent motor reorganization, functional MRI (fMRI)studies with isolated primary motor cortical stroke have notyet been reported in humans. Based on experimental data, wedesigned a study to test if recovery after stroke within primarymotor cortex (M1) was associated with reorganization withinthe surrounding motor cortex, i.e. the motor cortex was ableto vicariate. Since motor recovery is time-dependent and mightbe inflected according to the tested task, the delay after strokeand two motor tasks were included in our design. We examinedfour patients with one ischaemic stroke limited to M1, and foursex- and age-matched healthy controls in a temporally balancedprospective longitudinal fMRI study over three sessions: <20days, 4 months and 2 years after stroke. The paradigm includedtwo motor tasks, finger tapping (FT) and finger extension (FE).Distinct patterns of motor activation were observed with timefor FT and FE. At the first session, FT-related activation waslateralized in the ipsilateral hemisphere while FE-related activationwas contralateral, involving bilateral cerebellar regions forboth tasks. From 4 months, skilled motor recovery was associatedwith contralateral dorsal premotor and sensorimotor cortex andipsilateral cerebellum motor-related activations, leading tolateralized motor patterns for both tasks. For the left recoveredhand, FT and FE-related activations within M1 were more dorsalin patients than in controls. This dorsal shift progressivelyincreased over 2 years, reflecting functional reorganizationin the motor cortex adjacent to the lesion. In addition, patientsshowed a reverse representation of FT and FE within M1, correspondingto a greater dorsal shift for FT than for FE. This functionaldissociation might reflect the structural subdivision of M1with two distinct finger motor representations within M1. Recoveryof FT, located within the lesioned depth of the rolandic sulcusin controls, might be related to the re-emergence of a new representationin the intact dorsal M1, while FE, located more dorsally, underwentminor reorganization. This is the first fMRI study of humanspresenting with isolated M1 stroke comparable with experimentallesions in animals. Despite the small number of patients, ourfindings showing the re-emergence of a fingers motor task inthe intact dorsal M1 instead of in ventral M1 are consistentwith ‘vicariation’ models of stroke recovery.

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