Subthalamic high frequency stimulation resets subthalamic firing and reduces abnormal oscillations

doi:10.1093/brain/awh616

Brain Advance Access originally published online on August 25, 2005
Brain 2005 128(10):2372-2382; doi:10.1093/brain/awh616

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Subthalamic high frequency stimulation resets subthalamic firing and reduces abnormal oscillations

Wassilios Meissner¹^,3, Arthur Leblois¹^,2, David Hansel², Bernard Bioulac¹, Christian E. Gross¹, Abdelhamid Benazzouz¹ and Thomas Boraud¹

¹ Basal Gang, Laboratoire de Neurophysiologie, CNRS UMR 5543, Université Victor Ségalen, Bordeaux, ² Neurophysique et Physiologie du Système Moteur, CNRS UMR 8119, Université Paris V, Paris, France and ³ Neurologische Klinik, Charité Campus Virchow-Klinikum, Humboldt Universitaet, Berlin, Germany

Correspondence to: Dr. Wassilios Meissner, Basal Gang, Laboratoire de Neurophysiologie, CNRS UMR 5543, Université Victor Ségalen, 146 rue Léo Saignat, 33076 Bordeaux Cedex, France E-mail: wassilios.meissner{at}umr5543.u-bordeaux2.fr

High frequency stimulation (HFS) of the subthalamic nucleus(STN) is a well-established therapeutic approach for the treatmentof late-stage Parkinson's disease. Although the underlying causeof this illness remains a mystery, changes in firing rate andsynchronized activity in different basal ganglia nuclei havebeen related to its symptoms. Here we investigated the impactof STN-HFS on firing rate as well as correlated and oscillatoryactivity in the STN network in 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine(MPTP)-lesioned non-human primates by using simultaneous extracellularsingle-unit recordings. STN-HFS reduced (i) the firing rateof STN neurons, (ii) the oscillatory activity at an individualSTN neuron level as well as (iii) the correlated and oscillatoryactivity between pairs of STN neurons, while contralateral rigiditywas improved. A detailed analysis showed that the decrease ofmean firing rate resulted from the resetting of firing probabilityto virtually zero by the stimulus pulse. Subsequently, STN neuronsresumed their activity after a mean duration of 2.9 ±0.1 ms and their firing probability returned to baseline values $~$ 7 ms after the onset of the stimulus pulse, the recovery ofthe firing probability being represented by a sigmoid function.Thus, the overall decrease of the mean firing rate resultedfrom the repetition of this dynamical process with a frequencyof 130 Hz (interstimulus interval $~$ 7.7 ms), allowing the neuronto fire with its baseline firing rate only for a very shortperiod. Although the mechanisms underlying the desynchronizationof neuronal activity in the STN network remain unclear, theresetting of STN neuron firing probability by the electricalstimulus would rather be expected to increase oscillatory activityat an individual neuron level as well as correlated and oscillatoryactivity between pairs of STN neurons. However, assuming theresetting of firing rate to be the consequence of a transientGABAergic inhibition through excitation of presynaptic GABAergicaxon terminals, different recovery periods of STN neurons mightdelay the appearance of synchronized oscillations, particularlyif they are not generated locally. In conclusion, our studyprovides new evidence that STN-HFS decreases oscillatory activityin the STN network. Although the exact relation between oscillatoryactivity and Parkinson's disease symptoms remains to be determined,the present results suggest that STN-HFS might at least partiallyexert its beneficial effects through the reduction of oscillatoryactivity in the STN network and consequently in the entire cortex-basalganglia-cortex network.

Key Words: Parkinson's disease; MPTP; non-human primate; electrophysiology; correlation function

Abbreviations: AC = auto-correlogram; CC = cross-correlogram; HFS = high frequency stimulation; MPTP = 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine; STN = subthalamic nucleus; TH-IR = tyrosine hydroxylase immunoreactive

Received September 10, 2004. Revised July 7, 2005. Accepted July 19, 2005.

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