9B-2 Microbubble Interactions at High Mechanical Index: Ultrasound Stimulated Behaviour of SonoVue from Optically Predefined 'Stand-Off' Positions

J. M. Burns, P. Prentice, P. Campbell
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Abstract

Introduction of a temporally periodic pressure field within a fluid can induce forced oscillations to bubbles present therein. The resultant [radial] bubble dynamics are a complex function of several parameters, including the driving pressure amplitude, and proximity to nearby boundaries, such as vessel walls, or indeed, other bubbles. Recently, experimentation gauged towards the development of a quantitative understanding of [acoustically] driven bubbles of micrometer dimensions, especially when close to boundaries, has become a challenge of heightened academic and industrial interest. In pursuit of this, the present authors pioneered a new approach to such measurements that exploits optical trapping to locate microbubbles at prescribed displacements from a boundary [1,2]. Here, we extend our previous method and report the first comprehensive study that has observed the dynamical behavior of isolated single micro-bubbles (the commercially available ultrasound contrast agent: SonoVue) that had been optically trapped over a range of well-defined displacements from a rigid boundary. All of the measurements were conducted at a mechanical index (MI) > 3. We noted a distinct variance in micro-bubble behavior across all quiescent radii and stand-off parameter, and also correlated bubble outcome statistics with measured radial dynamics. Finally, we suggest that the procedure outlined can be exploited to design ‘next-generation’ microbubbles with specific response characteristics.
9B-2微泡在高机械指数下的相互作用:超声刺激下SonoVue从光学预定义的“对峙”位置的行为
在流体中引入一个时间周期压力场可以诱导存在于其中的气泡产生强迫振荡。由此产生的[径向]气泡动力学是几个参数的复杂函数,包括驱动压力振幅、邻近边界(如容器壁)或其他气泡的接近程度。最近,对微米尺寸的[声学]驱动气泡进行定量理解的实验,特别是在接近边界时,已经成为学术界和工业界高度关注的挑战。为了实现这一目标,本文作者开创了一种新的测量方法,即利用光学捕获来定位边界规定位移处的微气泡[1,2]。在这里,我们扩展了我们以前的方法,并报告了第一项全面的研究,该研究观察了孤立的单个微泡(市售超声造影剂:SonoVue)的动力学行为,这些微泡已被光学捕获在刚性边界的一系列明确定义的位移上。所有测量均在力学指数(MI) > 3时进行。我们注意到微泡行为在所有静态半径和隔离参数上的明显差异,并将气泡结果统计与测量的径向动力学相关联。最后,我们建议可以利用概述的程序来设计具有特定响应特性的“下一代”微泡。
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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