P84. High-frequency anterior thalamus stimulation interrupts cortical midline theta rhythm during drowsiness in an epileptic patient

Abstract

Deep brain stimulation (DBS) of anterior thalamic nuclei (ANT) reduces frequency and intensity of epileptic partial and secondarily-generalized seizures. However, exact mechanisms of action and the effects of ANT-DBS on cortical activity are unknown. Recently, we demonstrated in one of our patients who had non-lesional epilepsy the correlation of ANT-DBS with bilateral frontal epileptic patterns ( Bucurenciu et al., 2014 ). We report the case of a 27-years old male epileptic patient with dyscognitive focal seizures, due to a left-hemispheric inoperable lesion, interpreted as focal cortical dysplasia and polymicrogyria, comprising the upper temporal lobe, the insula and the entire parietal lobe. At the age of 25, quadripolar DBS-electrodes (Model 3389, Medtronic®, Minneapolis, MN, USA), connected to a subclavicular dual-channel programmable stimulation device (Activa PC, Medtronic®), were stereotactically implanted in both ANTs. The stimulation parameters were 5 V and 5.5 V, 180 Hz, 150 μ s pulse width, cycling mode with 1min on/3min off. Stimulation on-phases were identified based on periodical reduction of QRS-complex-amplitudes in electrocardiograms. A 20% reduction of seizure frequencies with no side effects were reported after initiation of ANT-DBS. In several long-term EEGs of the patient, prominent non-specific midline-theta frontal rhythms of uncertain significance were observed during drowsiness. During bilateral stimulation via the most upper (superior-lateral) electrode-contacts (3 and 11) a reliable interruption of midline-theta rhythm was observed in EEGs, density-spectral-arrays and power-spectra, similarly to the effect of activating the patient. When the lowest (inferio-medial) electrode contacts (0 and 8) were used for stimulation the midline-theta rhythm was less affected. Other cortical rhythms, such as occipital-alpha or sleep-spindles, were only unspecifically reduced in amplitude by stimulation of both the most upper and the lowest contact-pairs, respectively. The contact-specificity and the selective inhibition of midline-theta rhythm, associated with changes of the power-spectra shape, prove that the observed EEG-amplitude reduction during stimulation is a real desynchronization of midline-theta rhythm and not an artefact. This is the first direct proof of an acute, electrode-contact specific influence of high-frequency ANT-DBS with standard stimulation-parameters on a cortical rhythm and might be relevant for epilepsies involving frontal cortical regions.