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应用高帧率脉搏波成像技术于颈动脉疾病患者体内检测动脉壁力学非均质性和粥样硬化斑块特征。

Arterial wall mechanical inhomogeneity detection and atherosclerotic plaque characterization using high frame rate pulse wave imaging in carotid artery disease patients in vivo.

机构信息

Department of Biomedical Engineering, Columbia University, New York, NY, United States of America. Grigorios M Karageorgos and Iason Z Apostolakis contributed equally to this work.

出版信息

Phys Med Biol. 2020 Jan 17;65(2):025010. doi: 10.1088/1361-6560/ab58fa.

DOI:10.1088/1361-6560/ab58fa
PMID:31746784
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6980325/
Abstract

Pulse wave imaging (PWI) is a non-invasive, ultrasound-based technique, which provides information on arterial wall stiffness by estimating the pulse wave velocity (PWV) along an imaged arterial wall segment. The aims of the present study were to: (1) utilize the PWI information to automatically and optimally divide the artery into the segments with most homogeneous properties and (2) assess the feasibility of this method to provide arterial wall mechanical characterization in normal and atherosclerotic carotid arteries in vivo. A silicone phantom consisting of a soft and stiff segment along its longitudinal axis was scanned at the stiffness transition, and the PWV in each segment was estimated through static testing. The proposed algorithm detected the stiffness interface with an average error of 0.98  ±  0.49 mm and 1.04  ±  0.27 mm in the soft-to-stiff and stiff-to-soft pulse wave transmission direction, respectively. Mean PWVs estimated in the case of the soft-to-stiff pulse wave transmission direction were 2.47 [Formula: see text] 0.04 m s and 3.43 [Formula: see text] 0.08 m s for the soft and stiff phantom segments, respectively, while in the case of stiff-to-soft transmission direction PWVs were 2.60 [Formula: see text] 0.18 m s and 3.72 [Formula: see text] 0.08 m s for the soft and stiff phantom segments, respectively, which were in good agreement with the PWVs obtained through static testing (soft segment: 2.41 m s, stiff segment: 3.52 m s). Furthermore, the carotid arteries of N  =  9 young subjects (22-32 y.o.) and N  =  9 elderly subjects (60-73 y.o.) with no prior history of carotid artery disease were scanned, in vivo, as well as the atherosclerotic carotid arteries of N  =  12 (59-85 y.o.) carotid artery disease patients. One-way ANOVA with Holm-Sidak correction showed that the number of most homogeneous segments in which the artery was divided was significantly higher in the case of carotid artery disease patients compared to young (3.25 [Formula: see text] 0.86 segments versus 1.00 [Formula: see text] 0.00 segments, p -value  <  0.0001) and elderly non-atherosclerotic subjects (3.25 [Formula: see text] 0.86 segments versus 1.44 [Formula: see text] 0.51 segments p -value  <  0.0001), indicating increased wall inhomogeneity in atherosclerotic arteries. The compliance provided by the proposed algorithm was significantly higher in non-calcified/high-lipid plaques as compared with calcified plaques (3.35 [Formula: see text] 2.45 *[Formula: see text] versus 0.22 [Formula: see text] 0.18 * [Formula: see text], p -value  <  0.01) and the compliance estimated in elderly subjects (3.35 [Formula: see text] 2.45 * [Formula: see text] versus 0.79 [Formula: see text] 0.30 * [Formula: see text], p -value  <  0.01). Moreover, lower compliance was estimated in cases where vulnerable plaque characteristics were present (i.e. necrotic lipid core, thrombus), compared to stable plaque components (calcification), as evaluated through plaque histological examination. The proposed algorithm was thus capable of evaluating arterial wall inhomogeneity and characterize wall mechanical properties, showing promise in vascular disease diagnosis and monitoring.

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9280/6980325/0e555aed7254/nihms-1060208-f0009.jpg
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摘要

脉搏波成像(PWI)是一种非侵入性的超声技术,通过估计沿成像动脉壁段的脉搏波速度(PWV),提供动脉壁僵硬度的信息。本研究的目的是:(1)利用 PWI 信息自动和最优地将动脉分成具有最均匀特性的段;(2)评估这种方法在体内正常和动脉粥样硬化颈动脉中提供动脉壁机械特性的可行性。一个由软段和硬段组成的硅酮仿体在其纵轴上的刚度过渡处进行扫描,并通过静态测试估计每个段的 PWV。所提出的算法在软到硬和硬到软脉搏波传输方向上检测到刚度界面的平均误差分别为 0.98±0.49mm 和 1.04±0.27mm。在软到硬脉搏波传输方向的情况下估计的平均 PWV 分别为软和硬仿体段的 2.47[公式:见正文]0.04m/s 和 3.43[公式:见正文]0.08m/s,而在硬到软传输方向的情况下 PWV 分别为 2.60[公式:见正文]0.18m/s 和 3.72[公式:见正文]0.08m/s,与通过静态测试获得的 PWV 非常吻合(软段:2.41m/s,硬段:3.52m/s)。此外,对 9 名无颈动脉疾病史的年轻受试者(22-32 岁)和 9 名老年受试者(60-73 岁)的颈总动脉进行了体内扫描,以及 12 名(59-85 岁)有颈动脉疾病病史的患者的动脉粥样硬化颈动脉。经 Holm-Sidak 校正的单因素方差分析显示,与年轻受试者(3.25[公式:见正文]0.86 段与 1.00[公式:见正文]0.00 段,p 值<0.0001)和无动脉粥样硬化的老年非患者相比,患有动脉粥样硬化疾病患者的动脉被分割成最均匀段的数量显著更高(3.25[公式:见正文]0.86 段与 1.44[公式:见正文]0.51 段,p 值<0.0001),表明动脉粥样硬化血管的壁不均匀性增加。与钙化斑块相比,所提出的算法提供的顺应性在非钙化/高脂质斑块中显著更高(3.35[公式:见正文]2.45*[公式:见正文]与 0.22[公式:见正文]0.18*[公式:见正文],p 值<0.01),并且在老年受试者中估计的顺应性更高(3.35[公式:见正文]2.45*[公式:见正文]与 0.79[公式:见正文]0.30*[公式:见正文],p 值<0.01)。此外,与稳定斑块成分(钙化)相比,在存在易损斑块特征(即坏死脂质核心、血栓)的情况下,估计的顺应性较低,通过斑块组织学检查进行评估。因此,所提出的算法能够评估动脉壁的不均匀性并对壁机械特性进行特征化,在血管疾病诊断和监测方面具有广阔的应用前景。

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