文章摘要
喻波涛,常诗卉,曾苗苗,陶敏慧,菅喜岐.微泡对高强度聚焦超声声压场影响的仿真研究*[J].,2016,35(5):417-425
微泡对高强度聚焦超声声压场影响的仿真研究*
The simulation study of the effect of microbubbles on high intensity focused ultrasound acoustic pressure field
投稿时间:2015-12-03  修订日期:2016-08-08
中文摘要:
      微泡对高强度聚焦超声(HIFU)治疗焦域具有增效作用,而HIFU治疗中不同声学条件下微泡对HIFU形成声压场的影响尚不清楚。本文基于气液混合声波传播方程、Keller气泡运动方程、时域有限差分(FDTD)法和龙格-库塔(RK)法数值仿真研究输入声压、激励频率、气泡初始空隙率和气泡初始半径对HIFU形成声压场的影响。研究结果表明,随着输入声压的增大,焦点处声压升高但焦点处最大声压与输入声压的比值减小,焦点位置几乎不变;随着激励频率和气泡初始半径的增大,焦点处声压升高且焦点位置向远离换能器方向移动;随着气泡初始空隙率的增大,焦点处声压降低且焦点位置向换能器方向移动。
英文摘要:
      The synergy effect of microbubbles was used to enhance HIFU treatment focal region. However, the effect of microbubbles on HIFU acoustic pressure field in different acoustic conditions during HIFU therapy is not clear. In this paper, the effect of input acoustic pressure, exciting frequency, initial bubble void fraction and initial bubble radius on the acoustic pressure field of HIFU was discussed based on the gas-liquid mixing acoustic propagation equation, Keller bubble motion equation, the finite difference time domain (FDTD) method and Runge-Kutta (RK) method. The results show that, as the input acoustic pressure increasing, the acoustic pressure at focus increases but the ratio of maximum acoustic pressure at focus to input acoustic pressure decreases, the focus position is almost constant. As the exciting frequency and the initial bubble radius increasing, the acoustic pressure at focus increases and the focus moves away from the transducer side. As the initial bubble void fraction increasing, the acoustic pressure at focus decreases and the focus moves to the transducer side.
DOI:10.11684/j.issn.1000-310X.2016.05.006
中文关键词: 高强度聚焦超声,微泡,空化,空隙率,数值仿真
英文关键词: High-intensity focused ultrasound, Microbubble, Cavitation, Void fraction, Numerical simulation
基金项目:(81272495);国家自然科学基金项目(面上项目,重点项目,重大项目)
作者单位E-mail
喻波涛 天津医科大学-生物医学工程与技术学院 天津 300070 405224899@qq.com 
常诗卉 天津医科大学-生物医学工程与技术学院 天津 300070 Jessica0306@yeah.net 
曾苗苗 天津医科大学-生物医学工程与技术学院 天津 300070 277089969@qq.com 
陶敏慧 天津医科大学-生物医学工程与技术学院 天津 300070 542780398@qq.com 
菅喜岐 天津医科大学-生物医学工程与技术学院 天津 300070 jianxiqi@tmu.edu.cn 
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