Carotid plaque characterization with histology and quantitative ultrasound

2014 IEEE International Ultrasonics Symposium Pub Date : 2014-10-23 DOI:10.1109/ULTSYM.2014.0595

Xiao Wang, M. S. Salamat, T. Varghese, R. Dempsey

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引用次数: 3

Abstract

Most atherosclerotic plaques are heterogeneous, making it difficult to classify them in the clinic as calcified or lipidic plaques. We propose a novel approach to characterize localized plaque regions with different tissue types. We will compare and correlate calcified, fibrous and lipid regions within heterogeneous plaque using a one-to-one registration with histology and quantitative ultrasound imaging (QUS). Atherosclerotic plaque excised during a carotid endarterectomy procedure was imaged ex vivo using a VisualSonics Vevo 770 ultrasound system. Attenuation coefficient images were obtained from three-dimensional (3D) radiofrequency data collected and rendered into a 3D volume. Fixed plaque tissue was then longitudinally sectioned with thickness of 5 μm, and sections separated by 100 μm were utilized. Two-dimensional histopathology images were digitized using a PathScan Enabler IV, registered and reconstructed into a 3D volume using Matlab. Different regions such as the lumen, calcified, lipid and fibrous regions were segmented by a pathologist and digitally color-coded into the 3D histology volumes. Similar tissue types from the 3D histology volume were then compared to the estimated 3D attenuation coefficient obtained using quantitative ultrasound methods. Our results indicate that calcified, lipid and fibrous regions in the two volumes demonstrate good correlation. Calcified regions delineated on the histology volume correspond to high attenuation coefficient regions (2.45 dB/cm/MHz) in the 3D attenuation coefficient volume, while lipid regions tend to have lower attenuation coefficient values (1.50 dB/cm/MHz). Fibrous regions in histology, correlate to the lowest attenuation coefficient value (0.83 dB/cm/MHz). Our work demonstrates a direct correlation between histology and ultrasound quantitative imaging characterization of plaque. Using 3D histology volumes, different tissue composition within the plaque can be better identified and characterized.

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颈动脉斑块的组织学和定量超声特征

大多数动脉粥样硬化斑块是异质性的，因此在临床上很难将其分类为钙化斑块或脂质斑块。我们提出了一种新的方法来表征不同组织类型的局部斑块区域。我们将比较和关联钙化，纤维和脂质区域在异质斑块使用一对一注册与组织学和定量超声成像(QUS)。在颈动脉内膜切除术过程中切除的动脉粥样硬化斑块使用VisualSonics Vevo 770超声系统进行体外成像。衰减系数图像从收集的三维(3D)射频数据中获得，并渲染成三维体。将固定的斑块组织纵向切片，厚度为5 μm，间隔100 μm。使用PathScan Enabler IV对二维组织病理学图像进行数字化，使用Matlab进行配准并重建为三维体。不同的区域，如管腔、钙化、脂质和纤维区被病理学家分割，并以数字颜色编码到3D组织学体积中。然后将来自3D组织学体积的类似组织类型与使用定量超声方法获得的估计3D衰减系数进行比较。我们的结果表明，钙化，脂质和纤维区在两个体积显示出良好的相关性。在组织学体积上圈定的钙化区域对应于三维衰减系数体积中的高衰减系数区域(2.45 dB/cm/MHz)，而脂质区域的衰减系数值往往较低(1.50 dB/cm/MHz)。组织学上的纤维区与最低衰减系数值(0.83 dB/cm/MHz)相关。我们的工作证明了斑块的组织学和超声定量成像特征之间的直接相关性。利用三维组织学体积，可以更好地识别和表征斑块内不同的组织组成。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2014 IEEE International Ultrasonics Symposium

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