High-resolution adaptive optical imaging within thick scattering media using closed-loop accumulation of single scattering

Sungsam Kang; Pilsung Kang; Seungwon Jeong; Yongwoo Kwon; Taeseok D. Yang; Jin Hee Hong; Moonseok Kim; Kyung Deok Song; Jin Hyoung Park; Jun Ho Lee; Myoung Joon Kim; Ki Hean Kim; Wonshik Choi

doi:10.1038/s41467-017-02117-8

High-resolution adaptive optical imaging within thick scattering media using closed-loop accumulation of single scattering

Sungsam Kang, Pilsung Kang, Seungwon Jeong, Yongwoo Kwon, Taeseok D. Yang, Jin Hee Hong, Moonseok Kim, Kyung Deok Song, Jin Hyoung Park, Jun Ho Lee, Myoung Joon Kim, Ki Hean Kim, Wonshik Choi

Research output: Contribution to journal › Article › peer-review

49 Citations (Scopus)

Abstract

Thick biological tissues give rise to not only the multiple scattering of incoming light waves, but also the aberrations of remaining signal waves. The challenge for existing optical microscopy methods to overcome both problems simultaneously has limited sub-micron spatial resolution imaging to shallow depths. Here we present an optical coherence imaging method that can identify aberrations of waves incident to and reflected from the samples separately, and eliminate such aberrations even in the presence of multiple light scattering. The proposed method records the time-gated complex-field maps of backscattered waves over various illumination channels, and performs a closed-loop optimization of signal waves for both forward and phase-conjugation processes. We demonstrated the enhancement of the Strehl ratio by more than 500 times, an order of magnitude or more improvement over conventional adaptive optics, and achieved a spatial resolution of 600 nm up to an imaging depth of seven scattering mean free paths.

Original language	English
Article number	2157
Journal	Nature communications
Volume	8
Issue number	1
DOIs	https://doi.org/10.1038/s41467-017-02117-8
Publication status	Published - 2017 Dec 1

ASJC Scopus subject areas

General
Physics and Astronomy(all)
Chemistry(all)
Biochemistry, Genetics and Molecular Biology(all)

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title = "High-resolution adaptive optical imaging within thick scattering media using closed-loop accumulation of single scattering",

abstract = "Thick biological tissues give rise to not only the multiple scattering of incoming light waves, but also the aberrations of remaining signal waves. The challenge for existing optical microscopy methods to overcome both problems simultaneously has limited sub-micron spatial resolution imaging to shallow depths. Here we present an optical coherence imaging method that can identify aberrations of waves incident to and reflected from the samples separately, and eliminate such aberrations even in the presence of multiple light scattering. The proposed method records the time-gated complex-field maps of backscattered waves over various illumination channels, and performs a closed-loop optimization of signal waves for both forward and phase-conjugation processes. We demonstrated the enhancement of the Strehl ratio by more than 500 times, an order of magnitude or more improvement over conventional adaptive optics, and achieved a spatial resolution of 600 nm up to an imaging depth of seven scattering mean free paths.",

author = "Sungsam Kang and Pilsung Kang and Seungwon Jeong and Yongwoo Kwon and Yang, {Taeseok D.} and Hong, {Jin Hee} and Moonseok Kim and Song, {Kyung Deok} and Park, {Jin Hyoung} and Lee, {Jun Ho} and Kim, {Myoung Joon} and Kim, {Ki Hean} and Wonshik Choi",

note = "Funding Information: This research was supported by IBS-R023-D1, and the Global Frontier Program (2014M3A6B3063710) through the National Research Foundation of Korea (NRF) funded by the Ministry of Science, ICT & Future Planning. It was also supported by the Korea Health Technology R&D Project (HI14C0748) funded by the Ministry of Health & Welfare, Republic of Korea. This research was supported in part by Engineering Research Center (2011-0030075) of the National Research Foundation (NRF) funded by the Korea Government (MEST). Publisher Copyright: {\textcopyright} 2017 The Author(s).",

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doi = "10.1038/s41467-017-02117-8",

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AU - Kang, Sungsam

AU - Kang, Pilsung

AU - Jeong, Seungwon

AU - Kwon, Yongwoo

AU - Yang, Taeseok D.

AU - Hong, Jin Hee

AU - Kim, Moonseok

AU - Song, Kyung Deok

AU - Park, Jin Hyoung

AU - Lee, Jun Ho

AU - Kim, Myoung Joon

AU - Kim, Ki Hean

AU - Choi, Wonshik

N1 - Funding Information: This research was supported by IBS-R023-D1, and the Global Frontier Program (2014M3A6B3063710) through the National Research Foundation of Korea (NRF) funded by the Ministry of Science, ICT & Future Planning. It was also supported by the Korea Health Technology R&D Project (HI14C0748) funded by the Ministry of Health & Welfare, Republic of Korea. This research was supported in part by Engineering Research Center (2011-0030075) of the National Research Foundation (NRF) funded by the Korea Government (MEST). Publisher Copyright: © 2017 The Author(s).

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N2 - Thick biological tissues give rise to not only the multiple scattering of incoming light waves, but also the aberrations of remaining signal waves. The challenge for existing optical microscopy methods to overcome both problems simultaneously has limited sub-micron spatial resolution imaging to shallow depths. Here we present an optical coherence imaging method that can identify aberrations of waves incident to and reflected from the samples separately, and eliminate such aberrations even in the presence of multiple light scattering. The proposed method records the time-gated complex-field maps of backscattered waves over various illumination channels, and performs a closed-loop optimization of signal waves for both forward and phase-conjugation processes. We demonstrated the enhancement of the Strehl ratio by more than 500 times, an order of magnitude or more improvement over conventional adaptive optics, and achieved a spatial resolution of 600 nm up to an imaging depth of seven scattering mean free paths.

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High-resolution adaptive optical imaging within thick scattering media using closed-loop accumulation of single scattering

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