通过流动聚焦产生的单分散脂质包裹微泡造影剂的声学响应。
Acoustic responses of monodisperse lipid-encapsulated microbubble contrast agents produced by flow focusing.
作者信息
Kaya Mehmet, Feingold Steven, Hettiarachchi Kanaka, Lee Abraham P, Dayton Paul A
机构信息
University of North Carolina - North Carolina State University.
出版信息
Bubble Sci Eng Technol. 2010 Dec;2(2):33-40. doi: 10.1179/175889610x12779105661532.
Abstract
Lipid-encapsulated microbubbles are used as contrast agents in ultrasound imaging. Currently available commercially made contrast agents have a polydisperse size distribution. It has been hypothesised that improved imaging sensitivity could be achieved with a uniform microbubble radius. We have recently developed microfluidics technology to produce contrast agents with a nearly monodisperse distribution. In this manuscript, we analyze echo responses from individual microbubbles from monodisperse populations in order to establish the relationship between scattered echo, microbubble radius, and excitation frequency. Simulations of bubble response from a modified Rayleigh-Plesset type model corroborate experimental data. Results indicate that microbubble echo response can be greatly increased by optimal combinations of microbubble radius and acoustic excitation frequency. These results may have a significant impact in the formulation of contrast agents to improve ultrasonic sensitivity.
摘要
脂质包裹的微泡被用作超声成像中的造影剂。目前市售的造影剂具有多分散的尺寸分布。据推测,具有均匀的微泡半径可以提高成像灵敏度。我们最近开发了微流控技术来生产具有近乎单分散分布的造影剂。在本手稿中,我们分析了来自单分散群体中单个微泡的回波响应,以建立散射回波、微泡半径和激发频率之间的关系。来自改进的瑞利 - 普莱斯特定型模型的气泡响应模拟证实了实验数据。结果表明,微泡半径和声激发频率的最佳组合可以大大提高微泡回波响应。这些结果可能对改进超声灵敏度的造影剂配方产生重大影响。
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