Ultrasound intensity calculations for a vessel with simulated wall lesion

2002 IEEE Ultrasonics Symposium, 2002. Proceedings. Pub Date : 2002-10-08 DOI:10.1109/ULTSYM.2002.1192648

R.S. Thompson, C. Macaskill, L. Farnell, W. Fraser

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引用次数: 2

Abstract

Vascular disease alters the shape of the lumen of a blood vessel. The lumen is not circular from the early stages of the disease, where there is intimal thickening, through to advanced stages where a large plaque may protrude into the lumen. Using a mathematical model we investigated the ultrasound intensity distribution, both within the vessel wall and across the lumen, in the presence of a simulated wall lesion. Acoustic impedance interfaces due to wall lesions have dimensions (typically /spl sim/ 1 mm) only slightly greater than the wavelength (/spl sim/ 0.3 mm for 5 MHz ultrasound). Full wave solutions for the acoustic field are therefore required. Exact solutions in terms of Bessel functions are known for the case of a cylindrical vessel, and a collocation method based on this was developed for non-circular interfaces. By considering two such interfaces we developed a novel model representation of a vessel with a simulated wall lesion. The results of this study show how vessel wall properties may alter the ultrasound intensity distribution within the vessel wall and across the lumen. In the case of non-circular impedance interfaces there can be significant effects due to the local curvature and orientation of the interface.

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模拟血管壁病变的超声强度计算

血管疾病会改变血管腔的形状。从疾病的早期(内膜增厚)到晚期(大斑块可能突出到管腔)，管腔不是圆形的。利用数学模型，我们研究了超声强度分布，既在血管壁内，也在管腔内，在模拟壁病变的存在。由于壁损伤引起的声阻抗界面的尺寸(通常为/spl sim/ 1mm)仅略大于波长(5mhz超声为/spl sim/ 0.3 mm)。因此需要声场的全波解。在圆柱形容器的情况下，贝塞尔函数的精确解是已知的，并且基于此开发了非圆形界面的配置方法。通过考虑两个这样的界面，我们开发了一个具有模拟壁病变的血管的新模型表示。本研究结果显示了血管壁特性如何改变血管壁内和管腔内的超声强度分布。在非圆形阻抗界面的情况下，由于界面的局部曲率和方向，可能会产生显著的影响。

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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2002 IEEE Ultrasonics Symposium, 2002. Proceedings.

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