Precise spatial control of cavitation erosion in a vessel phantom by using an ultrasonic standing wave

In atherosclerotic inducement in animal models, the conventionally used balloon injury is invasive, produces excessive vessel injuries at unpredictable locations and is inconvenient in arterioles. Fortunately, cavitation erosion, which plays an important role in therapeutic ultrasound in blood vesse...

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Veröffentlicht in:	Ultrasonics sonochemistry 2016-07, Vol.31, p.163-172
Hauptverfasser:	Shi, Aiwei, Huang, Peixuan, Guo, Shifang, Zhao, Lu, Jia, Yingjie, Zong, Yujin, Wan, Mingxi
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Sprache:	eng
Schlagworte:	Animals Blood Vessels Cavitation Erosion Phantoms, Imaging Phase-change nanoemulsion SonoVue Ultrasonic standing wave Ultrasonics Vessel
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creator	Shi, Aiwei Huang, Peixuan Guo, Shifang Zhao, Lu Jia, Yingjie Zong, Yujin Wan, Mingxi
description	In atherosclerotic inducement in animal models, the conventionally used balloon injury is invasive, produces excessive vessel injuries at unpredictable locations and is inconvenient in arterioles. Fortunately, cavitation erosion, which plays an important role in therapeutic ultrasound in blood vessels, has the potential to induce atherosclerosis noninvasively at predictable sites. In this study, precise spatial control of cavitation erosion for superficial lesions in a vessel phantom was realised by using an ultrasonic standing wave (USW) with the participation of cavitation nuclei and medium-intensity ultrasound pulses. The superficial vessel erosions were restricted between adjacent pressure nodes, which were 0.87mm apart in the USW field of 1MHz. The erosion positions could be shifted along the vessel by nodal modulation under a submillimetre-scale accuracy without moving the ultrasound transducers. Moreover, the cavitation erosion of the proximal or distal wall could be determined by the types of cavitation nuclei and their corresponding cavitation pulses, i.e., phase-change microbubbles with cavitation pulses of 5MHz and SonoVue microbubbles with cavitation pulses of 1MHz. Effects of acoustic parameters of the cavitation pulses on the cavitation erosions were investigated. The flow conditions in the experiments were considered and discussed. Compared to only using travelling waves, the proposed method in this paper improves the controllability of the cavitation erosion and reduces the erosion depth, providing a more suitable approach for vessel endothelial injury while avoiding haemorrhage.
doi_str_mv	10.1016/j.ultsonch.2015.12.016
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Fortunately, cavitation erosion, which plays an important role in therapeutic ultrasound in blood vessels, has the potential to induce atherosclerosis noninvasively at predictable sites. In this study, precise spatial control of cavitation erosion for superficial lesions in a vessel phantom was realised by using an ultrasonic standing wave (USW) with the participation of cavitation nuclei and medium-intensity ultrasound pulses. The superficial vessel erosions were restricted between adjacent pressure nodes, which were 0.87mm apart in the USW field of 1MHz. The erosion positions could be shifted along the vessel by nodal modulation under a submillimetre-scale accuracy without moving the ultrasound transducers. Moreover, the cavitation erosion of the proximal or distal wall could be determined by the types of cavitation nuclei and their corresponding cavitation pulses, i.e., phase-change microbubbles with cavitation pulses of 5MHz and SonoVue microbubbles with cavitation pulses of 1MHz. Effects of acoustic parameters of the cavitation pulses on the cavitation erosions were investigated. The flow conditions in the experiments were considered and discussed. 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Effects of acoustic parameters of the cavitation pulses on the cavitation erosions were investigated. The flow conditions in the experiments were considered and discussed. 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subjects	Animals Blood Vessels Cavitation Erosion Phantoms, Imaging Phase-change nanoemulsion SonoVue Ultrasonic standing wave Ultrasonics Vessel
title	Precise spatial control of cavitation erosion in a vessel phantom by using an ultrasonic standing wave
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