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超快超声成像技术对激光激发表面声波与声辐射力的比较研究。

Ultrafast ultrasound imaging of surface acoustic waves induced by laser excitation compared with acoustic radiation force.

出版信息

Opt Lett. 2020 Apr 1;45(7):1810-1813. doi: 10.1364/OL.383932.

DOI:10.1364/OL.383932
PMID:32236005
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8957894/
Abstract

Two generation mechanisms-optical perturbation and acoustic radiation force (ARF)-were investigated where high frame rate ultrasound imaging was used to track the propagation of induced SAWs. We compared ARF-induced SAWs with laser-induced SAWs generated by laser beam irradiation of the uniformly absorbing tissue-like viscoelastic phantom, where light was preferentially absorbed at the surface. We also compared the frequency content of SAWs generated by ARF versus pulsed laser light, using the same duration of excitation. Differences in the SAW bandwidth were expected because, in general, laser light can be focused into a smaller area. Finally, we compared wave generation and propagation when the wave's origin was below the surface. We also investigated the relationship between shear wave amplitude and optical fluence. The investigation reported here can potentially extend the applications of laser-induced SAW generation and imaging in life sciences and other applications.

摘要

研究了两种产生机制——光微扰和声辐射力(ARF)——利用高帧率超声成像来跟踪感应 SAW 的传播。我们将 ARF 诱导的 SAW 与激光诱导的 SAW 进行了比较,后者通过对均匀吸收组织样粘弹性仿体进行激光束辐照产生光,光优先在表面被吸收。我们还比较了 ARF 与脉冲激光产生的 SAW 的频率内容,使用相同的激励持续时间。由于一般来说,激光可以聚焦到更小的区域,因此预计 SAW 的带宽会有所不同。最后,我们比较了波的起源在表面以下时的波的产生和传播。我们还研究了剪切波幅度与光通量之间的关系。这里报道的研究可能会扩展激光诱导 SAW 产生和成像在生命科学和其他应用中的应用。

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