Deep and Complex Vascular Anatomy in the Rat Brain Described With Ultrasound Localization Microscopy in 3D

IEEE open journal of ultrasonics, ferroelectrics, and frequency control Pub Date : 2023-12-21 DOI:10.1109/OJUFFC.2023.3342751

Arthur Chavignon;Baptiste Heiles;Vincent Hingot;Cyrille Orset;Denis Vivien;Olivier Couture

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Abstract

Ultrasound Localization Microscopy (ULM) enables imaging microvessels in the brain with a resolution of a few tens of micrometers in-vivo. The planar architecture of arterioles and venules was revealed with a 2D ultrasound scanner in the cortex of the rat brain. However, deeper in the brain, where the vascularization becomes tri-dimensional, 2D imaging remains limited by the elevation projection. In this study, volumetric ultrasound imaging was performed in the craniotomized rat brain to yield 3D ULM in vivo within 7.5 min of acquisition with a commercial system. For instance, it highlighted the thalamus or the circle of Willis with small vessels down to

$21 ~\mu \text{m}$

. Microbubbles tracking also gave access to the 3D velocity vector of blood flow allowing to distinguish flow directions. Volumetric ULM resolved deep complex tri-dimensional vascular structures and was compared to 2D ULM. It is a safe, simple and repeatable system to image wide field of view in the brain.

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用三维超声定位显微镜描述大鼠大脑深层复杂的血管解剖结构

超声定位显微镜（ULM）可对大脑中的微血管进行成像，活体成像分辨率可达几十微米。二维超声扫描仪可显示大鼠大脑皮层中动脉和静脉的平面结构。然而，在大脑深部，血管变成了三维的，二维成像仍然受到仰角投影的限制。在这项研究中，使用商用系统对开颅大鼠大脑进行了容积超声成像，在 7.5 分钟的采集时间内获得了体内三维 ULM。例如，它突出显示了丘脑或威利斯圈的小血管，最小可达 21 ~\mu \text{m}$ 。微气泡跟踪还可以获得三维血流速度矢量，从而区分血流方向。容积式超短波成像可以解析深部复杂的三维血管结构，并与二维超短波成像进行了比较。这是一种安全、简单、可重复的系统，可用于脑部宽视野成像。

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IEEE open journal of ultrasonics, ferroelectrics, and frequency control

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