Simulation Study on the Dynamics of Cavitation Bubbles in Multi-Frequency Ultrasound.

Q3 Medicine

Journal of Biomedical Physics and Engineering Pub Date : 2025-04-01 DOI:10.31661/jbpe.v0i0.2410-1841

Hu Dong, Gang Liu, Gaofeng Peng

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引用次数: 0

Abstract

Background: High-intensity focused ultrasound (HIFU) therapy is an effective minimally invasive treatment technique.

Objective: This work aimed to present a theoretical foundation for transient cavitation control in HIFU treatment and investigate cavitation bubbles in multi-frequency ultrasound.

Material and methods: In this theoretical study, the nonlinear vibrations of bubbles in different mediums (water, urine, kidney, and muscle) were simulated using Gilmore-Akulichev and modified Keller-Miksis equations. The dynamic changes of bubble radius during irradiation by multi-frequency combined ultrasound were analyzed, and the effects of multi-frequency ultrasound combinations and frequency differences on the maximum and minimum values of bubble expansion radius and bubble collapse time were investigated.

Results: At the same highest frequency, the triple-frequency produced the largest bubble expansion radius (R_max) while the single-frequency resulted in the smallest bubble expansion radius (R_min). At the same lowest frequency, the single-frequency had the biggest bubble expansion radius and the triple-frequency had the smallest bubble expansion radius. Compared to the combination with a large frequency difference at high frequency, the triple-frequency combination with a small frequency difference at low frequency exhibited a noticeably larger R_max, but R_min showed the opposite behavior. R_max/R_min decreased for the same ultrasonic combination when the medium viscosity increased. The bubble expansion radius ratio R_max/R_min was positively correlated with the bubble collapse time.

Conclusion: There was a strong correlation between the frequency difference and the multi-frequency ultrasound combination and the maximum and minimum values of the cavitation bubble radius and the collapse time.

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多频超声空化气泡动力学仿真研究。

背景：高强度聚焦超声（HIFU）治疗是一种有效的微创治疗技术。目的：为HIFU治疗过程中瞬态空化控制提供理论基础，探讨多频超声空化气泡。材料和方法：在本理论研究中，使用Gilmore-Akulichev和修正的Keller-Miksis方程模拟了气泡在不同介质（水、尿液、肾脏和肌肉）中的非线性振动。分析了多频组合超声辐照过程中气泡半径的动态变化，研究了多频组合超声和频率差对气泡膨胀半径最大值和最小值以及气泡坍缩时间的影响。结果：在相同的最高频率下，三频产生的气泡膨胀半径（Rmax）最大，而单频产生的气泡膨胀半径（Rmin）最小。在同一最低频率下，单频气泡膨胀半径最大，三频气泡膨胀半径最小。与高频频率差较大的组合相比，低频频率差较小的三频组合的Rmax明显较大，而Rmin则相反。随着介质粘度的增加，相同超声组合的Rmax/Rmin减小。气泡膨胀半径比Rmax/Rmin与气泡破裂时间呈正相关。结论：频率差与多频超声组合、空化泡半径最大值和最小值与塌陷时间有较强的相关性。

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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来源期刊

Journal of Biomedical Physics and Engineering Medicine-Radiology, Nuclear Medicine and Imaging

CiteScore

2.90

自引率

0.00%

发文量

审稿时长

10 weeks

期刊介绍： The Journal of Biomedical Physics and Engineering (JBPE) is a bimonthly peer-reviewed English-language journal that publishes high-quality basic sciences and clinical research (experimental or theoretical) broadly concerned with the relationship of physics to medicine and engineering.