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Ultrasonic sculpting of virtual optical waveguides in tissue

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...

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Bibliographic Details
Published in:Nature communications 2019-01, Vol.10 (1), p.92-92, Article 92
Main Authors: Chamanzar, Maysamreza, Scopelliti, Matteo Giuseppe, Bloch, Julien, Do, Ninh, Huh, Minyoung, Seo, Dongjin, Iafrati, Jillian, Sohal, Vikaas S., Alam, Mohammad-Reza, Maharbiz, Michel M.
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Language:English
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Summary: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. Optical imaging of tissue is a powerful technique but delivering light deep into scattering tissue is not possible without using invasive methods. Here, the authors demonstrate that patterned ultrasound can define and control the trajectory of light in tissue using pressure-induced index contrasts.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-018-07856-w