组织中虚拟光导波的超声雕刻。

Ultrasonic sculpting of virtual optical waveguides in tissue.

机构信息

Electrical and Computer Engineering Department, Carnegie Mellon University, Pittsburgh, 15213, PA, USA.

Electrical Engineering and Computer Science Department, University of California, Berkeley, 94720, CA, USA.

出版信息

Nat Commun. 2019 Jan 9;10(1):92. doi: 10.1038/s41467-018-07856-w.

DOI:10.1038/s41467-018-07856-w

PMID:30626873

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6327026/

Abstract

Optical imaging and stimulation are widely used to study biological events. However, scattering processes limit the depth to which externally focused light can penetrate tissue. Optical fibers and waveguides are commonly inserted into tissue when delivering light deeper than a few millimeters. This approach, however, introduces complications arising from tissue damage. In addition, it makes it difficult to steer light. Here, we demonstrate that ultrasound can be used to define and steer the trajectory of light within scattering media by exploiting local pressure differences created by acoustic waves that result in refractive index contrasts. We show that virtual light pipes can be created deep into the tissue (>18 scattering mean free paths). We demonstrate the application of this technology in confining light through mouse brain tissue. This technology is likely extendable to form arbitrary light patterns within tissue, extending both the reach and the flexibility of light-based methods.

摘要

光学成象和激发被广泛用于研究生物事件。然而，散射过程限制了外部聚焦光能够穿透组织的深度。当需要将光输送到几毫米深以上时，通常会将光纤和波导插入组织中。然而，这种方法会带来组织损伤引起的并发症。此外，这使得难以控制光的方向。在这里，我们证明可以利用由声波产生的局部压力差来操纵光在散射介质中的轨迹，从而利用超声来定义和控制光在散射介质中的轨迹，这会导致折射率对比。我们表明，可以在组织深处（>18 个散射平均自由程）创建虚拟光管。我们演示了该技术在限制通过小鼠脑组织的光的应用。这项技术很可能可以扩展到在组织内形成任意的光图案，从而扩展基于光的方法的作用范围和灵活性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d0f5/6327026/b5f2af2bca0f/41467_2018_7856_Fig1_HTML.jpg

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组织中虚拟光导波的超声雕刻。

Ultrasonic sculpting of virtual optical waveguides in tissue.

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