A cerebellar-like terminal and postural tremor induced in normal man by transcranial magnetic stimulation

doi:10.1093/brain/122.8.1551

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Brain, Vol. 122, No. 8, 1551-1562, August 1999
© 1999 Oxford University Press

A cerebellar-like terminal and postural tremor induced in normal man by transcranial magnetic stimulation

H. Topka¹, S. Mescheriakov¹, A. Boose¹, R. Kuntz², I. Hertrich¹, L. Seydel¹, J. Dichgans¹ and J. Rothwell³

¹ Departments of Neurology and ² Neuroradiology, University of Tübingen, Germany and ³ MRC Human Movement and Balance Unit, The Institute of Neurology, London, UK

Correspondence to: Helge Topka, MD, Department of Neurology, University of Tübingen, Hoppe-Seyler-Strasse 3, 72076 Tübingen, Germany E-mail: topka{at}uni-tuebingen.de

Trains of repetitive transcranial magnetic stimulation (TMS)at 10–30 Hz and intensities of 90–120% motor thresholdwere delivered through a figure of eight coil over the motorcortex while normal subjects made either rapid, self-terminated(ballistic) wrist movements or maintained the position of theirwrist at a fixed angle. Movement kinematics and EMG activityin antagonistic forearm muscles were analysed. In the ballistictask, repetitive TMS had little effect on the velocity or accelerationof the initial segment of the movement, although it inducedlarge terminal oscillations (tremor) around the target positionat frequencies between 4.4 and 7.2 Hz. The likelihood that tremorwould occur increased with increasing stimulus intensities orfrequencies. It was maximal with stimulation over the forearmarea, and decreased with stimulation over the leg area, or overparietal sites; there was no tremor during stimulation of cervicalnerve roots. The frequency of the induced tremor was independentof the rate of stimulation and did not depend on the presenceof excitatory and inhibitory motor responses to the stimulus.Stimulation could also induce tremor of the same frequency inthe fixed task, but only during co-contraction of forearm muscles.The amplitude of tremor was proportional to the level of co-contraction.Clinically, the tremor induced by repetitive TMS appeared verysimilar to cerebellar tremors. In order to confirm this we investigatedtwo cerebellar patients, one with autosomal dominant cerebellarataxia and the other with multiple sclerosis. Both of them hada terminal tremor of 6–7 Hz in the wrist movement task.In the holding task, the amplitude of their postural tremorincreased with the level of co-contraction in forearm muscles.Since the frequency of repetitive TMS-induced tremor was independentof stimulus parameters, we conclude that it represents someintrinsic property of the CNS. We suggest that the tremor iscaused by disruption of cortical processes involved in terminatinga voluntary movement or maintaining a posture. Similaritiesto cerebellar patients suggest that repetitive TMS may causetremor by interfering with adaptive cerebellar afferent inflowto motor cortex. Repetitive TMS-induced tremor, therefore, mayrepresent a model of some forms of cerebellar tremor in man.

intention tremor; postural tremor; cerebellar; transcranial magnetic stimulation

ADCA = autosomal dominant cerebellar ataxia; ANOVA = analysis of variance; MEP = motor evoked potential; MT = motor threshold; SMA = supplementary motor area; TMS = transcranial magnetic stimulation

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