Authors
Rintoul, J. L., Butler, C., Cleveland, R. O., Grossman, N.
Abstract
Non-invasive brain stimulation offers therapeutic potential without the risks of surgery, yet current electrical approaches lack spatial precision and depth due to the long wavelengths of electric fields. Here we demonstrate that the acoustoelectric interaction - the nonlinear coupling between applied acoustic and electric fields - can overcome these limitations to achieve spatially focused, non-invasive neuromodulation. Using in vitro and in vivo rodent electrophysiology, we show motor-evoked potentials that depend on both the amplitude and frequency of the acoustoelectric field, with artefactual controls excluding purely acoustic or electrical origins. We further identify an acoustoelectric contribution to conventional ultrasound stimulation, arising from the interaction between ultrasound-induced electrical signals and propagating acoustic waves. These findings establish acoustoelectric neuromodulation as a distinct mechanism of neural activation and a significant contributor to how ultrasound stimulation influences brain activity, opening new directions for precise, non-invasive neuromodulation and neurotherapeutic development.
Preprint server:
bioRxiv
The authors list and abstract were imported from bioRxiv on 05 Nov 2025.
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