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利用局部谐波运动对聚焦超声手术进行体内监测。

In vivo monitoring of focused ultrasound surgery using local harmonic motion.

作者信息

Curiel Laura, Chopra Rajiv, Hynynen Kullervo

机构信息

Imaging Research, Sunnybrook Health Sciences Centre, Toronto, Ontario, Canada.

出版信息

Ultrasound Med Biol. 2009 Jan;35(1):65-78. doi: 10.1016/j.ultrasmedbio.2008.07.001. Epub 2008 Sep 21.

Abstract

The present study established the feasibility of a technique for monitoring focused ultrasound (FUS) lesion formation in vivo using localized harmonic motion (LHM) measurements. Oscillatory motion (frequencies between 50 and 300 Hz) was generated within tissues by induction of a periodic radiation force with a FUS transducer. The harmonic motion was estimated using cross correlation of RF ultrasonic signals acquired at different instances during the motion by using a confocal diagnostic ultrasound transducer. The technique was evaluated in vivo in rabbit muscle (14 locations) in an magnetic resonance (MR) imager for simultaneous ultrasound harmonic motion tracking and MR thermometry. The measured maximum amplitude of the induced harmonic motion before and after the lesion formation was significantly different for all the tested motion frequencies, and decreased between 17 and 81% depending on the frequency and location. During the FUS exposure a drop in the maximum amplitude value was observed and a threshold value could be associated to the formation of a thermal lesion. A series of controlled sonications was performed by stopping the exposure when the threshold value in LHM amplitude was reached and the presence of a thermal lesion was confirmed by MR imaging. LHM measurements were also used to perform a spatial scan of the tissues across the exposure region and the thermal lesions could be detected as a reduction in the maximum motion amplitude value at the sonication region.

摘要

本研究证实了一种利用局部谐波运动(LHM)测量在体内监测聚焦超声(FUS)损伤形成技术的可行性。通过使用FUS换能器施加周期性辐射力,在组织内产生振荡运动(频率在50至300Hz之间)。利用共聚焦诊断超声换能器,通过对运动过程中不同时刻采集的射频超声信号进行互相关,来估计谐波运动。该技术在磁共振(MR)成像仪中的兔肌肉(14个部位)进行了体内评估,用于同时进行超声谐波运动跟踪和MR温度测量。对于所有测试的运动频率,损伤形成前后诱导谐波运动的测量最大振幅存在显著差异,且根据频率和位置在17%至81%之间降低。在FUS暴露期间,观察到最大振幅值下降,并且可以将一个阈值与热损伤的形成相关联。通过在LHM振幅达到阈值时停止暴露,进行了一系列受控超声处理,并通过MR成像确认了热损伤的存在。LHM测量还用于对暴露区域的组织进行空间扫描,热损伤可被检测为超声处理区域最大运动振幅值的降低。

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