Lateral motion estimator for measurement of artery-wall displacement

2009 IEEE International Ultrasonics Symposium Pub Date : 2009-09-01 DOI:10.1109/ULTSYM.2009.5441634

H. Hasegawa, H. Kanai

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Abstract

Artery-wall motion due to the pulsation of the heart is often measured to evaluate mechanical properties of the arterial wall. Such motion is thought to occur only in the arterial radial direction because the main source of the motion is an increase of blood pressure. However, it has recently been reported that the artery also moves in the longitudinal direction. Therefore, a 2D motion estimator is required even when the artery is scanned in the longitudinal direction because the arterial wall moves both in the radial (axial) and longitudinal (lateral) directions. Methods based on 2D correlation of RF echoes are often used to estimate the lateral displacement together with axial displacement. However, these methods require much interpolation of the RF echo or correlation function to achieve a sufficient resolution in the estimation of displacement. To overcome this problem, Jensen et al. modulated the ultrasonic field in the lateral direction at a designed spatial frequency to utilize the lateral phase for the estimation of lateral motion. This method, namely, the lateral modulation method, generates complex signals whose phases change depending on the lateral motion. Therefore, the lateral displacement can be estimated with a good resolution without interpolation, although special beamformers are required. The present paper describes a method, which can be applied to ultrasonic echoes obtained by a conventional beamformer, to estimate lateral displacements using the phases of lateral fluctuations of ultrasonic echoes. In the proposed method, complex signals were generated by the Hilbert transform, and the phase shift was estimated by correlation-based estimators. The proposed method was validated using a cylindrical phantom mimicking an artery. The error in the lateral displacement estimated by the proposed method was 13.5% of the true displacement of 0.5 mm with a kernel size used for calculating the correlation function of 0.6 mm in the lateral direction, which was slightly smaller than the width at −20 dB of the maximum lateral ultrasonic field (about 0.8 mm).

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测量动脉壁位移的横向运动估计器

由心脏搏动引起的动脉壁运动常被用来评价动脉壁的力学特性。这种运动被认为只发生在动脉径向，因为这种运动的主要来源是血压升高。然而，最近有报道称动脉也在纵向运动。因此，即使在动脉纵向扫描时，也需要二维运动估计器，因为动脉壁在径向(轴向)和纵向(横向)方向上移动。基于射频回波二维相关的方法通常用于估计横向位移和轴向位移。然而，这些方法需要对射频回波或相关函数进行大量插值，以获得足够的位移估计分辨率。为了克服这个问题，Jensen等人以设计的空间频率在横向方向调制超声场，利用横向相位来估计横向运动。这种方法，即横向调制方法，产生的复杂信号，其相位随横向运动而变化。因此，尽管需要特殊的波束成像器，但可以在不插值的情况下以良好的分辨率估计横向位移。本文描述了一种利用超声回波横向波动的相位估计横向位移的方法，该方法适用于传统波束形成器获得的超声回波。该方法利用希尔伯特变换生成复信号，并利用相关估计器估计相移。采用模拟动脉的圆柱形假体验证了所提出的方法。该方法估计的横向位移误差为0.5 mm真实位移的13.5%，其核尺寸用于计算横向相关函数为0.6 mm，略小于最大横向超声场在−20 dB处的宽度(约0.8 mm)。

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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2009 IEEE International Ultrasonics Symposium

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