Spatio-temporal characterization of causal electrophysiological activity stimulated by single pulse focused ultrasound: An ex vivo study on hippocampal brain slices

TL;DR

This study characterizes the spatial and temporal neural responses to single-pulse focused ultrasound stimulation in ex vivo hippocampal slices, revealing repeatable local field potentials and network activity spread.

Contribution

It introduces a novel combined FUS/MEA platform to analyze the immediate neural effects of single ultrasound pulses on brain tissue.

Findings

FUS induces local field potentials with variable amplitudes and durations

FUS-evoked responses are repeatable across pulses

Neural activity spreads across hippocampal slices after FUS stimulation

Abstract

Objective: The brain operates via generation, transmission and integration of neuronal signals and most neurological disorders are related to perturbation of these processes. Neurostimulation by Focused Ultrasound (FUS) is a promising technology with potential to rival other clinically-used techniques for the investigation of brain function and treatment of numerous neurological diseases. The purpose of this study was to characterize spatial and temporal aspects of causal electrophysiological signals directly stimulated by short, single pulses of focused ultrasound (FUS) on ex vivo mouse hippocampal brain slices. Approach: MicroElectrode Arrays (MEA) are used to study the spatio-temporal dynamics of extracellular neuronal activities both at the single neuron and neural networks scales. Hence, MEAs provide an excellent platform for characterization of electrical activity generated, modulated and transmitted in response to FUS exposure. In this study, a novel mixed FUS/MEA platform was designed for the spatio-temporal description of the causal responses generated by single 1.78 MHz FUS pulses in ex vivo mouse hippocampal brain slices. Main results: Our results show that FUS pulses can generate local field potentials (LFPs), sustained by synchronized neuronal post-synaptic potentials, and reproducing network activities. LFPs induced by FUS stimulation were found to be repeatable to consecutive FUS pulses though exhibiting a wide range of amplitudes (50-600 $\mu$V), durations (20-200 ms), and response delays (10-60 ms). Moreover, LFPs were spread across the hippocampal slice following single FUS pulses thus demonstrating that FUS may be capable of stimulating different neural structures within the hippocampus. Significance: Current knowledge on neurostimulation by ultrasound describes neuronal activity generated by trains of repetitive ultrasound pulses. This novel study details the causal neural responses produced by single-pulse FUS neurostimulation while illustrating the distribution and propagation properties of this neural activity along major neural pathways of the hippocampus.