Benjamin Clennell1, Tom G J Steward1, Meg Elley1, Eunju Shin2, Miles Weston3, Bruce W Drinkwater4, Daniel J Whitcomb5. 1. Bristol Medical School, Faculty of Health Sciences, University of Bristol, Bristol, BS1 3NY, UK. 2. Neuroscience and Mental Health Research Institute, Cardiff University, Cardiff, CF24 4HQ, UK. 3. TWI Technology Centre, Port Talbot, SA13 1SB, UK. 4. Faculty of Engineering, University of Bristol, Bristol, BS8 1TR, UK. 5. Bristol Medical School, Faculty of Health Sciences, University of Bristol, Bristol, BS1 3NY, UK. Electronic address: d.j.whitcomb@bristol.ac.uk.
Abstract
BACKGROUND: Transcranial ultrasound stimulation can acutely modulate brain activity, but the lasting effects on neurons are unknown. OBJECTIVE: To assess the excitability profile of neurons in the hours following transient ultrasound stimulation. METHODS: Primary rat cortical neurons were stimulated with a 40 s, 200 kHz pulsed ultrasound stimulation or sham-stimulation. Intrinsic firing properties were investigated through whole-cell patch-clamp recording by evoking action potentials in response to somatic current injection. Recordings were taken at set timepoints following ultrasound stimulation: 0-2 h, 6-8 h, 12-14 h and 24-26 h. Transmission electron microscopy was used to assess synaptic ultrastructure at the same timepoints. RESULTS: In the 0-2 h window, neurons stimulated with ultrasound displayed an increase in the mean frequency of evoked action potentials of 32% above control cell levels (p = 0.023). After 4-6 h this increase was measured as 44% (p = 0.0043). By 12-14 h this effect was eliminated and remained absent 24-26 h post-stimulation. These changes to action potential firing occurred in conjunction with statistically significant differences between control and ultrasound-stimulated neurons in action potential half-width, depolarisation rate, and repolarisation rate, that were similarly eliminated by 24 h following stimulation. These effects occurred in the absence of alterations to intrinsic membrane properties or synaptic ultrastructure. CONCLUSION: We report that stimulating neurons with 40 s of ultrasound enhances their excitability for up to 8 h in conjunction with modifications to action potential kinetics. This occurs in the absence of major ultrastructural change or modification of intrinsic membrane properties. These results can inform the application of transcranial ultrasound in experimental and therapeutic settings.
BACKGROUND: Transcranial ultrasound stimulation can acutely modulate brain activity, but the lasting effects on neurons are unknown. OBJECTIVE: To assess the excitability profile of neurons in the hours following transient ultrasound stimulation. METHODS: Primary rat cortical neurons were stimulated with a 40 s, 200 kHz pulsed ultrasound stimulation or sham-stimulation. Intrinsic firing properties were investigated through whole-cell patch-clamp recording by evoking action potentials in response to somatic current injection. Recordings were taken at set timepoints following ultrasound stimulation: 0-2 h, 6-8 h, 12-14 h and 24-26 h. Transmission electron microscopy was used to assess synaptic ultrastructure at the same timepoints. RESULTS: In the 0-2 h window, neurons stimulated with ultrasound displayed an increase in the mean frequency of evoked action potentials of 32% above control cell levels (p = 0.023). After 4-6 h this increase was measured as 44% (p = 0.0043). By 12-14 h this effect was eliminated and remained absent 24-26 h post-stimulation. These changes to action potential firing occurred in conjunction with statistically significant differences between control and ultrasound-stimulated neurons in action potential half-width, depolarisation rate, and repolarisation rate, that were similarly eliminated by 24 h following stimulation. These effects occurred in the absence of alterations to intrinsic membrane properties or synaptic ultrastructure. CONCLUSION: We report that stimulating neurons with 40 s of ultrasound enhances their excitability for up to 8 h in conjunction with modifications to action potential kinetics. This occurs in the absence of major ultrastructural change or modification of intrinsic membrane properties. These results can inform the application of transcranial ultrasound in experimental and therapeutic settings.
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