Transcranial Electrical Neuromodulation for Suppressing Epileptiform Discharges (GTEN)

One third of patients with epilepsy continue to have seizures despite receiving antiepileptic medication. The application of low frequency repetitive transcranial magnetic stimulation (rTMS) has shown promise for decreasing the frequency of epileptic seizures in drug refractory patients. The mechanism of action appears to be induction of long term depression (LTD) in the targeted cortex by the low frequency (0.5 Hz or 1 every 2 sec) pulses. Unfortunately, the electrical stimulation induced by available TMS coils is limited to the most superficial (gyral) regions of cortex, whereas epileptic foci may occur in sulci, and in deep as well as superficial cortex. The investigators have developed the ability to target currents to specific regions of cortex by aligning source and sink electrodes with flexible subsets of a 256 channel geodesic electrode array. A first step is accurate localization of the likely epileptic focus with 256 channel EEG. Detailed computational models of the electrical properties of head tissues allow optimization studies to select the best pattern of source-sink electrodes for that individual's head tissues and epileptic focus. The goal of the safety and feasibility trial is to test whether one week (5 days) of GTEN treatment can achieve a similar depression of the target cortical region as low frequency rTMS, with the decrease in excitability measured by suppression of epileptic spikes. This safety and feasibility trial has received an Investigational Device Exemption from the FDA for treating 20 patients with focal neocortical epilepsy. Pulsed (emulating rTMS) current sequences will be evaluated. The GTEN system implements a number of advanced technologies that provide improved targeting compared to conventional rTMS or tDCS, including electronics for both pulsed and sustained delivery of current with 256 electrodes; double fault safety circuits; computational modeling of the electromagnetic properties of the patient's head tissue for GTEN targeting with medical grade software; a lidocaine electrolyte that minimizes pain of the pulsed or sustained current with up to 200 µA per electrode (2 mA total); and online safety monitoring for adverse EEG changes with the 256 dEEG array. Based on FDA feedback to date, success with these trials will allow us to progress to a pivotal clinical efficacy trial (with separate funding) to support a de novo 510k approval for GTEN treatment for the temporary suppression of seizures in patients with drug-resistant epilepsy.