Ultrasound surgery monitoring using vibroacoustography-a simulation study

2000 IEEE Ultrasonics Symposium. Proceedings. An International Symposium (Cat. No.00CH37121) Pub Date : 2000-10-22 DOI:10.1109/ULTSYM.2000.921624

E. Konofagou, J. Thierman, K. Hynynen

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引用次数: 1

Abstract

Similar to other therapeutic methods, ultrasound surgery requires an imaging modality to monitor the extent of tissue damage during treatment. Currently, MRI is considered the gold standard method for monitoring tissue ablation, but it is considered to be costly and restrictive in its applications. In this paper, we considered the method of ultrasound-stimulated acoustic emission that uses two ultrasonic beams at high frequency (MHz) (same as that used for ablation) to locally perturb the tissue by generating a low difference frequency (kHz) radiation force. Recording of the tissue response at several locations yields an image. The amplitude of the tissue response depends on the mechanical and acoustic tissue properties, namely its stiffness and absorption. Those two properties were initially hypothesized to have opposite effects in the response amplitude, i.e., the amplitude should increase with absorption and decrease with stiffness. To check this hypothesis as well as the degree to which those properties influence the response, finite-element simulations of a uniform lesion formed in a homogeneous medium were used. The results show that the hypothesis holds at lower frequencies. At resonance and higher frequencies, those two properties have a synergistic effect on the tissue response to the applied radiation force.

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超声手术监测的振动声图模拟研究

与其他治疗方法类似，超声手术需要一种成像方式来监测治疗过程中组织损伤的程度。目前，MRI被认为是监测组织消融的金标准方法，但在应用中被认为是昂贵和限制性的。在本文中，我们考虑了超声刺激声发射的方法，即使用高频(MHz)的两束超声波束(与用于消融的相同)通过产生低差频(kHz)的辐射力来局部扰动组织。记录几个位置的组织反应产生图像。组织响应的振幅取决于组织的力学和声学特性，即组织的刚度和吸收。这两种性质最初被假设对响应振幅有相反的影响，即振幅应随吸收而增加，随刚度而减小。为了验证这一假设以及这些特性对响应的影响程度，使用了在均匀介质中形成均匀损伤的有限元模拟。结果表明，该假设在较低的频率下成立。在共振和更高的频率下，这两种特性对组织对施加的辐射力的响应具有协同效应。

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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2000 IEEE Ultrasonics Symposium. Proceedings. An International Symposium (Cat. No.00CH37121)

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