Three-dimensional fluorescence imaging through dynamic scattering media by motionless optical scanning holography

Yoneda, Naru; Saita, Yusuke; Nomura, Takanori

doi:10.1063/5.0066358

Cited by 20 publications

(7 citation statements)

References 49 publications

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“…Besides OSH and FINCH, many research groups reported holographic fluorescence microscopy systems with different types of interferometers: a Michelson interferometer [45,186,187], a single-path off-axis self-interference system [188,189], and a single-path self-interference system using a grating for quadriwave lateral shearing interferometry [190]. As other research achievements in IDHM, 3D fluorescence imaging through static or moving scattering media was performed with an OSH system [191], which exploits the nature of single-pixel DH. IDHM was also combined with lattice light-sheet microscopy for depth-resolved holographic 3D imaging [192] and Raman scattering microscopy for 3D imaging of surface-enhanced Raman scattering light [193].…”

Section: Other Remarks For Applications Of Idh (Tatsuki Tahara)mentioning

confidence: 99%

Roadmap of incoherent digital holography

et al. 2022

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This roadmap article focuses on spatially incoherent digital holography (IDH). Representative IDH methods such as optical scanning holography (OSH), Fresnel incoherent correlation holography (FINCH), coded aperture correlation holography (COACH), IDH with a Fresnel zone aperture, and IDH with an interferometer along with a state-of-the-art optical device are introduced as modern IDH methods. We describe these IDH techniques with applications of three-dimensional (3D) imagers, 3D thermography, and 3D microscopy.

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Section: Other Remarks For Applications Of Idh (Tatsuki Tahara)mentioning

confidence: 99%

Roadmap of incoherent digital holography

et al. 2022

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“…Any light source including self-luminous light and natural light can be recorded as a hologram. Various techniques such as 3D microscopy for self-luminous light (Schilling et al, 1997;Rosen and Brooker, 2008;Jang et al, 2015;Yanagawa et al, 2015;Quan et al, 2017;Liebel et al, 2020a;Liebel et al, 2020b;Kumar et al, 2020;Marar and Kner, 2020;Potcoava et al, 2021), 3D imaging with a single image sensor (Kim, 2013;Clark and Kim, 2015;Jang et al, 2015;Vijayakumar et al, 2016;Vijayakumar and Rosen, 2017;Nobukawa et al, 2018;Choi et al, 2019;Nobukawa et al, 2019;Wu et al, 2020;Tahara et al, 2021d;Wu et al, 2021;Yoneda et al, 2021;Tahara et al, 2022), 3D thermal measurement (Imbe, 2019), and spectroscopic 3D imaging (Yoshimori, 2001;Teeranutranont and Yoshimori, 2013;Naik et al, 2014;Kalenkov et al, 2019) have been proposed to date. Research on applications of IDH is ongoing and a challenging theme.…”

Section: Applications Of Incoherent Digital Holographymentioning

confidence: 99%

Review of Incoherent Digital Holography: Applications to Multidimensional Incoherent Digital Holographic Microscopy and Palm-Sized Digital Holographic Recorder—Holosensor

Tahara

2022

Front. Photon.

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We review advancements in incoherent digital holography (IDH) with an image sensor and its applications to multidimensional microscopy and a palm-sized hologram recorder termed “holosensor”. There are two types of representative IDH technique: IDH with a structured illumination and a single photodetector termed optical scanning holography and self-interference IDH. The latter IDH is a technique to obtain an incoherent digital hologram by modulating an incoherent light wave between an object and an image sensor. Multidimensional information such as three-dimensional space and wavelengths is simultaneously recorded without changing optical filters by introducing interferometric techniques invented in laser holography. Applications to high-speed color-multiplexed holographic fluorescence microscopy, single-shot incoherent full-color holographic microscopy with white light, and a palm-sized multidimensional incoherent hologram recorder have been developed using multidimensional IDH systems. Schematics and experimental results obtained using IDH techniques, incoherent holographic microscopy systems, and compact IDH systems are introduced.

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“…For these reasons, OSH is an incoherent digital holography with the advantages of SPI. OSH has been applied to various applications such as multicolor imaging [16], stereo-lightning reconstruction [17], imaging through scattering media [18], fluorescence imaging [19], polarization imaging [20], and so on. Interestingly, by using a pinhole just before the detector at a Fourier plane of the object, holograms detected with a laser, coherent holograms, can be obtained, which means OSH can also be applied to quantitative phase imaging [21].…”

Section: Introductionmentioning

confidence: 99%

Spatially divided two-step phase-shifting method for computational optical scanning holography

Yoneda,

Matoba

2023

J. Opt.

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Computational optical scanning holography (COSH) is one of the single-pixel incoherent digital holographic techniques; therefore, three-dimensional (3D) fluorescent objects can be measured as a digital hologram with a single-pixel detector.However, due to the requirement of a phase-shifting method to remove unnecessary components from holograms, the number of measurements of COSH is larger than the number of pixels.To reduce the number of measurements, the spatially divided phase-shifting method has been proposed.Similar to the parallel four-step phase-shifting digital holography, the spatially divided phase-shifting method can obtain four phase-shifted holograms simultaneously.However, the spatially divided phase-shifting method has a problem in that the spatial resolution is lower than the original COSH.In this paper, spatially divided two-step phase-shifting method is proposed to improve spatial resolution.The numerical evaluation results indicate the feasibility of the proposed method.

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Three-dimensional fluorescence imaging through dynamic scattering media by motionless optical scanning holography

Cited by 20 publications

References 49 publications

Roadmap of incoherent digital holography

Roadmap of incoherent digital holography

Review of Incoherent Digital Holography: Applications to Multidimensional Incoherent Digital Holographic Microscopy and Palm-Sized Digital Holographic Recorder—Holosensor

Spatially divided two-step phase-shifting method for computational optical scanning holography

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