The goal of this project is to understand the effects of ultrasound (US) on neural activity. US can modify action potential activity in neurons in vitro and in vivo without damaging neural tissue. This phenomenon can be applied in powerful new tools for basic and clinical neuroscience, with broad impact on public health issues related to mental and neurological disorders. To guide and hasten the development of these new tools, our research will provide insight into the physical, biophysical and neural mechanisms underlying US neurostimulation. Our approach is unique in combining technology development with mechanistic studies of US neurostimulation at levels of complexity ranging from the single cell to the whole animal. Our prior and preliminary results suggest that US radiation force causes tissue displacement, resulting in cell membrane strain and thereby affecting neural activity through changes in ion channel activity or neurotransmitter exocytosis. We will investigate this hypothesis by combining US neurostimulation with EEG recording and radiation force imaging in rats, optical displacement measurements and multielectrode recording in the salamander and rat retina in vitro and in vivo, and electrophysiological measurements of ion channel activity and exocytosis in single HEK and PC12 cells. We will also test alternative hypotheses related to two other physical effects of US, cavitation and heating. To distinguish these mechanisms from radiation force we will examine the dependence of US neurostimulation on frequency and intensity. To facilitate these experiments, we will develop and implement new US devices, allowing US to be applied with multifocal and micron-scale resolution. US neurostimulation is likely to have significant impact on public health. Brain stimulation therapies are used to treat Parkinson's disease, dystonia, and epilepsy and hold promise for many others. Compared to current brain stimulation techniques that rely on invasive implanted electrodes or have limited spatial resolution and depth penetration (e.g., transcranial magnetic stimulation), US offers an ideal combination of spatial resolution, depth penetration, and non-invasiveness. US neurostimlation can also be implemented in prosthetic devices; for example, to stimulate retinal circuitry to restore vision. In addition, US neurostimulation promises to become an enormously useful research tool in basic neuroscience, and is therefore relevant to all mental and neurological disorders of public health concern. However, all of these outcomes depend on the ability to apply US neurostimulation safely and with well-controlled, predictable results. Achieving this goal requires a detailed mechanistic understanding of US neurostimulation that our multidisciplinary research project will provide.

Public Health Relevance

Ultrasonic neurostimulation is a promising new technology that has the potential to provide revolutionary new therapies for neurological disorders including Parkinson's disease, dystonia, epilepsy, Alzheimer's, anxiety, schizophrenia, and stroke. However, development of this technology is impeded by the lack of mechanistic understanding of how ultrasound stimulates brain activity. The proposed research will provide a mechanistic understanding to catalyze development of ultrasonic neurostimulation therapies.

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Research Project (R01)
Project #
5R01EB019005-03
Application #
9088429
Study Section
Neuroscience and Ophthalmic Imaging Technologies Study Section (NOIT)
Program Officer
Krosnick, Steven
Project Start
2014-09-01
Project End
2018-06-30
Budget Start
2016-07-01
Budget End
2017-06-30
Support Year
3
Fiscal Year
2016
Total Cost
Indirect Cost
Name
Stanford University
Department
Biophysics
Type
Schools of Medicine
DUNS #
009214214
City
Stanford
State
CA
Country
United States
Zip Code
94304
Prieto, Martin Loynaz; Firouzi, Kamyar; Khuri-Yakub, Butrus T et al. (2018) Activation of Piezo1 but Not NaV1.2 Channels by Ultrasound at 43?MHz. Ultrasound Med Biol 44:1217-1232
Zheng, Yuan; Marx, Michael; Miller, G Wilson et al. (2018) High sensitivity MR acoustic radiation force imaging using transition band balanced steady-state free precession. Magn Reson Med 79:1532-1537
Kubanek, Jan; Shukla, Poojan; Das, Alakananda et al. (2018) Ultrasound Elicits Behavioral Responses through Mechanical Effects on Neurons and Ion Channels in a Simple Nervous System. J Neurosci 38:3081-3091
Ye, Patrick Peiyong; Brown, Julian R; Pauly, Kim Butts (2016) Frequency Dependence of Ultrasound Neurostimulation in the Mouse Brain. Ultrasound Med Biol 42:1512-30
Yoon, Hyo-Seon; Chang, Chienliu; Jang, Ji Hoon et al. (2016) Ex Vivo HIFU Experiments Using a $32 times 32$ -Element CMUT Array. IEEE Trans Ultrason Ferroelectr Freq Control 63:2150-2158