Saved in:
Bibliographic Details
Main Authors: Li, Yueming, Chen, Guo, Oliveira, Tiago R., Todd, Nick, Zhang, Yong-Zhi, Marar, Carolyn, Zheng, Nan, Lan, Lu, McDannold, Nathan, Cheng, Ji-Xin, Yang, Chen
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.06108
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866915377768824832
author Li, Yueming
Chen, Guo
Oliveira, Tiago R.
Todd, Nick
Zhang, Yong-Zhi
Marar, Carolyn
Zheng, Nan
Lan, Lu
McDannold, Nathan
Cheng, Ji-Xin
Yang, Chen
author_facet Li, Yueming
Chen, Guo
Oliveira, Tiago R.
Todd, Nick
Zhang, Yong-Zhi
Marar, Carolyn
Zheng, Nan
Lan, Lu
McDannold, Nathan
Cheng, Ji-Xin
Yang, Chen
contents Non-invasive stimulation of small, variably shaped brain sub-regions is crucial for advancing our understanding of brain functions. Current ultrasound neuromodulation faces two significant trade-offs when targeting brain sub-regions: miniaturization versus volumetric control and spatial resolution versus transcranial capability. Here, we present an optically-generated Bessel beam ultrasound (OBUS) device designed to overcome these limitations. This 2.33 mm-diameter miniaturized device delivers a column-shaped field achieving a lateral resolution of 152 um and an axial resolution of 1.93 mm, targeting brain sub-regions with an elongated volume of tissue activation. Immunofluorescence imaging of mouse brain slices confirms its ability to stimulate cells at a depth of 2.2 mm. Additionally, OBUS outperforms conventional Gaussian ultrasound in transcranial transmission efficiency and beam shape preservation. Electrophysiological recordings and functional MRI captured rodent brain responses evoked by OBUS, demonstrating OBUS's ability to non-invasively activate neural circuits in intact brains. This technology offers new possibilities for studying brain functions with precision and volumetric control.
format Preprint
id arxiv_https___arxiv_org_abs_2507_06108
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Miniaturized optically-generated Bessel beam ultrasound for volumetric transcranial brain stimulation
Li, Yueming
Chen, Guo
Oliveira, Tiago R.
Todd, Nick
Zhang, Yong-Zhi
Marar, Carolyn
Zheng, Nan
Lan, Lu
McDannold, Nathan
Cheng, Ji-Xin
Yang, Chen
Neurons and Cognition
Non-invasive stimulation of small, variably shaped brain sub-regions is crucial for advancing our understanding of brain functions. Current ultrasound neuromodulation faces two significant trade-offs when targeting brain sub-regions: miniaturization versus volumetric control and spatial resolution versus transcranial capability. Here, we present an optically-generated Bessel beam ultrasound (OBUS) device designed to overcome these limitations. This 2.33 mm-diameter miniaturized device delivers a column-shaped field achieving a lateral resolution of 152 um and an axial resolution of 1.93 mm, targeting brain sub-regions with an elongated volume of tissue activation. Immunofluorescence imaging of mouse brain slices confirms its ability to stimulate cells at a depth of 2.2 mm. Additionally, OBUS outperforms conventional Gaussian ultrasound in transcranial transmission efficiency and beam shape preservation. Electrophysiological recordings and functional MRI captured rodent brain responses evoked by OBUS, demonstrating OBUS's ability to non-invasively activate neural circuits in intact brains. This technology offers new possibilities for studying brain functions with precision and volumetric control.
title Miniaturized optically-generated Bessel beam ultrasound for volumetric transcranial brain stimulation
topic Neurons and Cognition
url https://arxiv.org/abs/2507.06108