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EFFECTS OF HIPPOCAMPAL TRANSCRANIAL TEMPORAL INTERFERENCE STIMULATION ON SPATIAL NAVIGATION AND RELATED BRAIN OSCILLATIONS IN TBI AND HEALTHY INDIVIDUALS

Serena Reverberiand 10 co-authors

École Polytechnique Fédérale de Lausanne (EPFL)

FENS Forum 2026 (2026)
Barcelona, Spain
Board PS04-08PM-573

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Date TBA

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Board: PS04-08PM-573

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EFFECTS OF HIPPOCAMPAL TRANSCRANIAL TEMPORAL INTERFERENCE STIMULATION ON SPATIAL NAVIGATION AND RELATED BRAIN OSCILLATIONS IN TBI AND HEALTHY INDIVIDUALS poster preview

Event Information

Poster Board

PS04-08PM-573

Abstract

Aims: Spatial navigation impairments are commonly reported amongst traumatic brain injury (TBI) patients; however, avenues for amelioration remain limited. Recently, transcranial temporal interference stimulation (tTIS) delivered to the hippocampal-entorhinal complex (HC-EC) was demonstrated to improve spatial navigation abilities in healthy individuals1,2. Here, we investigate tTIS effects on navigation performance and associated oscillatory dynamics in TBI patients and healthy age-matched controls (HA). We expect intermittent theta-burst patterned tTIS (iTBS-tTIS) to improve navigation performance versus control stimulation conditions. Neurally, we expect increased frontal theta-band activity during planning and navigation versus stasis.
Methods: In this ongoing study (planned N=25 TBI, 25 HA) we deliver excitatory iTBS-tTIS, inhibitory continuous TBS-tTIS (cTBS-tTIS), or high-frequency control stimulation (HF, see Fig.1) to the individually-targeted right HC-EC while participants perform an established virtual-reality spatial navigation task consisting of encoding and recalling object locations in a virtual arena1. High-density EEG is recorded during tTIS+task performance, and during resting state preceding and following tTIS+task.
Results: In line with previous findings, pilot data (N=2 healthy young adults) demonstrate improved trial time during iTBS versus HF stimulation (relative improvement pilot1: 18%, pilot2: 8%) or cTBS (pilot1: 17%, pilot2: 12%). Application of high-pass and low-pass hardware filters proved effective in minimizing tTIS-related artefacts in EEG recordings. Two TBI patients completed the experimental protocol, demonstrating study feasibility in patients.
Conclusions: This study will provide novel data on the behavioral and neural effects of hippocampal tTIS on spatial navigation and its cortical correlates. 1Beanato et al., 2024, Science Advances; 2Zhao et al., 2025, Nature Communications


Figure 1: Experimental design. TBI patients (planned sample N=25) and healthy age-matched controls (HA; planned sample=25) perform multiple blocks of a virtual-reality spatial navigation task while receiving transcranial temporal interference stimulation (tTIS). High-density EEG recordings are collected during the task+tTIS, as well as immediately prior to, and following, the task+tTIS session (resting-state recordings). (A) Each block of task consists of an encoding phase, where participants successively learn the locations of three objects in a virtual arena, followed by a retrieval phase in which participants are cued with the object to retrieve (1), and navigate to the recalled location (2). As feedback, the object then appears at the correct location (3) and must be collected to proceed to the next trial. Speed of navigation as well as the distance between retrieved and correct location are measured. (B) tTIS is a novel non-invasive brain stimulaton method that relies on two electrode pairs delivering high-frequency current (I1, blue, and I2, red), with a small frequency shift. While the high carrier frequency does not affect neuronal activity, the envelope resulting from their superposition (black) was shown to modulate brain activity. In this study, tTIS is delivered to the right hippocampus-entorhinal complex in patterned continuous or intermittent theta-burst frequency (cTBS, iTBS) or without frequency shift, resulting in no envelope modulation (HF control).

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