Orientation of Temporal Interference for Non-invasive Deep Brain Stimulation in Epilepsy

• Published in: Frontiers in neuroscience Vol. 15; p. 633988
• Main Authors: Missey, Florian, Rusina, Evgeniia, Acerbo, Emma, Botzanowski, Boris, Trébuchon, Agnès, Bartolomei, Fabrice, Jirsa, Viktor, Carron, Romain, Williamson, Adam
• Format: Journal Article
• Language: English
• Published: Lausanne Frontiers Research Foundation 07.06.2021; Frontiers; Frontiers Media S.A
• Subjects: Cognitive science; Convulsions & seizures; cortex; Deep brain stimulation; Drug resistance; Electric fields; electrical stimulation; Electrical stimuli; Electrodes; Epilepsy; Finite element analysis; Hippocampus; Localization; Magnetic fields; Neuroscience; Oscillations; Seizures; temporal interference; Transcranial magnetic stimulation; epilepsy; cortex; electrical stimulation; seizures; temporal interference; hippocampus
• ISSN: 1662-453X; 1662-4548; 1662-453X
• DOI: 10.3389/fnins.2021.633988

In patients with focal drug-resistant epilepsy, electrical stimulation from intracranial electrodes is frequently used for the localization of seizure onset zones and related pathological networks. The ability of electrically stimulated tissue to generate beta and gamma range oscillations, called rapid-discharges, is a frequent indication of an epileptogenic zone. However, a limit of intracranial stimulation is the fixed physical location and number of implanted electrodes, leaving numerous clinically and functionally relevant brain regions unexplored. Here, we demonstrate an alternative technique relying exclusively on non-penetrating surface electrodes, namely an orientation-tunable form of temporally interfering (TI) electric fields to target the CA3 of the mouse hippocampus which focally evokes seizure-like events (SLEs) having the characteristic frequencies of rapid-discharges, but without the necessity of the implanted electrodes. The orientation of the topical electrodes with respect to the orientation of the hippocampus is demonstrated to strongly control the threshold for evoking SLEs. Additionally, we demonstrate the use of Pulse-width-modulation of square waves as an alternative to sine waves for TI stimulation. An orientation-dependent analysis of classic implanted electrodes to evoke SLEs in the hippocampus is subsequently utilized to support the results of the minimally invasive temporally interfering fields. The principles of orientation-tunable TI stimulation seen here can be generally applicable in a wide range of other excitable tissues and brain regions, overcoming several limitations of fixed electrodes which penetrate tissue and overcoming several limitations of other non-invasive stimulation methods in epilepsy, such as transcranial magnetic stimulation (TMS).