Subthalamic nucleus stimulation modulates motor cortex oscillatory activity in Parkinson's disease

doi:10.1093/brain/awh053

Brain Advance Access originally published online on December 22, 2003

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Brain, Vol. 127, No. 2, 408-419, 2004
© 2004 Guarantors of Brain
doi: 10.1093/brain/awh053

Subthalamic nucleus stimulation modulates motor cortex oscillatory activity in Parkinson’s disease

D. Devos¹, E. Labyt², P. Derambure², J. L. Bourriez², F. Cassim², N. Reyns³, S. Blond³, J. D. Guieu², A. Destée¹ and L. Defebvre¹

¹ Department of Neurology, ² Department of Clinical Neurophysiology and ³ Department of Neurosurgery, EA2683, Lille University Medical Centre, Lille, France

Correspondence to: Dr David Devos, Hôpital R. Salengro, Clinique Neurologique, CHRU, F-59037 Lille cedex, France E-mail: d-devos{at}chru-lille.fr

In Parkinson’s disease, impaired motor preparation hasbeen related to an increased latency in the appearance of movement-relateddesynchronization (MRD) throughout the contralateral primarysensorimotor (PSM) cortex. Internal globus pallidus (GPi) stimulationimproved movement desynchronization over the PSM cortex duringmovement execution but failed to improve impaired motor preparation.PET studies indicate that subthalamic nucleus (STN) stimulationpartly reverses the abnormal premotor pattern of brain activationduring movement. By monitoring MRD, we aimed to assess changesin premotor and PSM cortex oscillatory activity induced by bilateralSTN stimulation and to compare these changes with those inducedby L-dopa. Ten Parkinson’s disease patients and a groupof healthy, age-matched controls performed self-paced wristflexions in each of four conditions: without either stimulationor L-dopa (the ‘off’ condition), with stimulationand without L-dopa (On Stim), with L-dopa and without stimulation(‘on drug’), and with both stimulation and L-dopa(On Both). Compared with the Off condition, in both the On Stimand the On Drug condition the Unified Parkinson’s DiseaseRating Scale (UPDRS) III score decreased by about 60% and inthe On Both condition it decreased by 80%. The desynchronizationlatency over central regions contralateral to movement and themovement desynchronization over bilateral central regions weresignificantly increased by stimulation and by L-dopa, with amaximal effect when the two were associated. Furthermore, desynchronizationlatency significantly decreased over bilateral frontocentralregions in the three treatment conditions compared with theOff condition. In Parkinson’s disease, STN stimulationmay induce a change in abnormal cortical oscillatory activitypatterns (similar to that produced by L-dopa) by decreasingthe abnormal spreading of desynchronization over frontocentralregions and increasing PSM cortex activity during movement preparationand execution, with a correlated improvement in bradykinesia.Parkinsonians under treatment displayed a desynchronizationpattern close to that seen in healthy, age-matched controls,although central latencies remained shorter. The study indicatesthat it is possible to influence cortical reactivity relatedto the planning and execution of voluntary movement throughthe basal ganglia, and furthermore that the oscillatory activityof the PSM cortex (in addition to that of premotor areas) couldbe of major importance in the control of movement-associated,neural activity in Parkinson’s disease.

Key Words: Parkinson’s disease; deep brain stimulation; subthalamic nucleus; EEG; event-related desynchronization

Abbreviations: CAPIT = Core Assessment Program for Intracerebral Transplantations; GPi = globus pallidus internus; MRD = movement-related desynchronization; PSM = primary sensorimotor; STN = subthalamic nucleus; UPDRS = United Parkinson’s Disease Rating Scale

Received April 14, 2003. Revised August 14, 2003. Accepted October 10, 2003.

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