Focused ultrasound excites cortical neurons via mechanosensitive calcium accumulation and ion channel amplification.

Ultrasonic neuromodulation has the unique potential to provide non-invasive control of neural activity in deep brain regions with high spatial precision and without chemical or genetic modification. However, the biomolecular and cellular mechanisms by which focused ultrasound excites mammalian neurons have remained unclear, posing significant challenges for the use of this technology in research and potential clinical applications. Here, we show that focused ultrasound excites primary murine cortical neurons in culture through a primarily mechanical mechanism mediated by specific calcium-selective mechanosensitive ion channels. The activation of these channels results in a gradual build-up of calcium, which is amplified by calcium- and voltage-gated channels, generating a burst firing response. Cavitation, temperature changes, large-scale deformation, and synaptic transmission are not required for this excitation to occur. Pharmacological and genetic inhibition of specific ion channels leads to reduced responses to ultrasound, while over-expressing these channels results in stronger ultrasonic stimulation. These findings provide a mechanistic explanation for the effect of ultrasound on neurons to facilitate the further development of ultrasonic neuromodulation and sonogenetics as tools for neuroscience research.

Introduction

Purpose Transcranial ultrasound stimulation

Study Objective To elucidate the molecular and cellular mechanisms by which focused ultrasound excites primary murine cortical neurons, particularly the role of calcium-selective mechanosensitive ion channels and downstream amplification.

Animal model / Human subject Mus musculus (mouse), C57BL/6J, embryonic day 18 (E18), sex not specified

Disease model healthy

MRI or image guidance method No MRI or stereotactic guidance — transducer was positioned in degassed water and aimed at the Mylar film culture dish using a customized holder (angled 20° relative to normal incidence; 45° in some imaging experiments) and the acoustic focus/location was calibrated/measured with a fiber‑optic hydrophone mounted on motorized stages to map the pressure profile.

Targeted brain region(s) Primary Murine Cortex (Cortical Neurons)

Target coordinates not provided

Cargo name and characteristics AAV1 viral vector delivering Syn-driven GCaMP6f calcium sensor (AAV1, 1×10^10 vp/dish); lentiviral delivery of Ace2N-4AA-mNeon voltage sensor (lentivirus, ~1×10^9–1×10^10 vp/dish) for optical voltage imaging; LentiCRISPR-mCherry constructs encoding sgRNAs for CRISPR/Cas9 knockout of ion channels (lentiviral, ~1×10^9 vp/sample); pharmacological small-molecule and peptide modulators applied in media — tetrodotoxin (TTX, 1 μM, voltage‑gated Na+ blocker), thapsigargin (TG, 500 nM, ER Ca2+ pump inhibitor), AP5 (1 μM, NMDA receptor antagonist) and CNQX (1 μM, AMPA/kainate receptor antagonist) to block synaptic transmission; cytochalasin D and vinblastine (each 1 μM, cytoskeleton disruptors), gadolinium (20 μM, nonspecific mechanosensitive channel blocker), ruthenium red (1 μM, TRP channel blocker), TTA-P2 (3 μM, T-type Ca2+ channel blocker), suramin (60 μM, GPCR inhibitor), and GsMTx4 (10 μM, peptide inhibitor of Piezo1/TRPC1).

Route of administration In vitro (direct application to cultured neurons): genetic cargo delivered by viral transduction (AAV1 for GCaMP6f; lentiviral vectors for Ace2N and CRISPR constructs) added to the culture medium; pharmacological drugs/blockers applied directly into the culture medium.

Outcomes and Safety

Summary of Outcomes Focused ultrasound mechanically activates specific calcium-permeable mechanosensitive ion channels (including TRPP1/2, TRPC1, and Piezo1) in primary murine cortical neurons, driving extracellular Ca2+ influx that is amplified by calcium- and voltage-gated channels to produce depolarization and burst firing, independent of cavitation, temperature changes, large-scale deformation, or synaptic transmission.

Duration of biological effect 200 ms

Safety-related matter The authors state that ultrasound stimulation was repeatable and non-toxic and that pharmacological doses (and actin depolymerization conditions) were carefully chosen to avoid cytotoxicity, altered viability, or changes in neuronal excitability, and combinations of blockers were avoided due to potential effects on cell viability.

Brain Region

Ultrasound Parameters

Ultrasound instrument BII-7654/300IM, Benthowave Instrument INC., Canada

FUS Frequency 300 kHz, 670 kHz

FUS Intensity 15 W/cm2

FUS Pressure 0.1 MPa

FUS Mode pulsed

Pulse duration 500 ms

Duration of a single FUS session 9 minutes 55 seconds (595 s; 30 pulses × 500 ms with 20 s inter-pulse intervals)

Focal Characteristics 24 mm

Treatment frequency multiple sessions

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