High-brightness laser imaging with tunable speckle reduction enabled by electroactive micro-optic diffusers

Farrokhi, Hamid; Rohith, Thazhe Madam; Boonruangkan, Jeeranan; Han, Seunghwoi; Kim, Hyun-Woong; Kim, Seung-Woo; Kim, Young‐Jin

doi:10.1038/s41598-017-15553-9

Cited by 32 publications

(17 citation statements)

References 29 publications

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“…In future, we will improve the image quality through the following approaches: We will further reduce the speckle noise using the angular‐diverse illumination [30] or implementing the moving diffuser [31,32], which will help analyze the cellular details. Although the imaging depth demonstrated in this preliminary study, ~200 µm, might be sufficient for examining the epithelial layer, where many of the disease‐associated cellular changes are present, a larger imaging depth will be desirable for imaging deeper regions.…”

Section: Discussionmentioning

confidence: 99%

Scattering‐Based Light‐Sheet Microscopy for Rapid Cellular Imaging of Fresh Tissue

et al. 2020

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Background and Objectives Light‐sheet microscopy (LSM) is a novel imaging technology that has been used for imaging fluorescence contrast in basic life science research. In this paper, we have developed a scattering‐based LSM (sLSM) for rapidly imaging the cellular morphology of fresh tissues without any exogenous fluorescent dyes. Study Design/Materials and Methods In the sLSM device, a thin light sheet with the central wavelength of 834 nm was incident on the tissue obliquely, 45° relative to the tissue surface. The detection optics was configured to map the light sheet‐illuminated area onto a two‐dimensional imaging sensor. The illumination numerical aperture (NA) was set as 0.0625, and the detection NA 0.3. Results The sLSM device achieved a light sheet thickness of less than 6.7 µm over 284 µm along the illumination optical axis. The detection optics of the sLSM device had a resolution of 1.8 µm. The sLSM images of the swine kidney ex vivo visualized tubules with similar sizes and shapes to those observed in histopathologic images. The swine duodenum sLSM images revealed cell nuclei and villi architecture in superficial lesions and glands in deeper regions. Conclusions The preliminary results suggest that sLSM may have the potential for rapidly examining the freshly‐excised tissue ex vivo or intact tissue in vivo at microscopic resolution. Further optimization and performance evaluation of the sLSM technology will be needed in the future. Lasers Surg. Med. © 2020 Wiley Periodicals LLC

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Section: Discussionmentioning

confidence: 99%

Scattering‐Based Light‐Sheet Microscopy for Rapid Cellular Imaging of Fresh Tissue

et al. 2020

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“…High‐brightness and high‐coherence continuous‐wave (CW) lasers have been utilized in QPI for efficient light–specimen interaction and phase‐sensitive interferometric imaging. [ 15,16 ] However, the high coherence inevitably superimposes unexpected coherent noise (e.g., speckle, diffraction, and parasitic interferogram) to the target interferograms, which significantly hampers sensitive phase detection and successful phase reconstruction. [ 17,18 ] The coherent noise gets even more severe when imaging through the scattering media, e.g., biological tissues, plasmonic nanoparticles, and nonideal optics with surface roughness or contamination.…”

Section: Introductionmentioning

confidence: 99%

Coherence‐Tailored Multiwavelength High‐Speed Quantitative Phase Imaging with a High Phase Stability via a Frequency Comb

Boonruangkan

Farrokhi

Rohith

et al. 2020

Advanced Photonics Research

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Coherent imaging enables noninvasive, label‐free, and quantitative monitoring of the dynamic motions of transparent microobjects requested in life sciences, biochemistry, material sciences, and fluid mechanics. Quantitative phase imaging (QPI), a coherent imaging technique, provides full‐field optical phase information through light interference. The use of coherence, however, inevitably accompanies phase ambiguity and coherent artifacts, such as speckle, diffraction, and parasitic interference, which severely deteriorate the interferograms to hinder successful phase reconstruction. Herein, it is demonstrated that a frequency comb can newly provide a wide coherence tunability for higher visibility interferograms, phase‐coherent multiple wavelengths for extracting physical height information from refractive index, and higher phase stability (2.39 × 10−3 at 10 s averaging time) at a higher speed up to 16.9 kHz. These superior characteristics of frequency‐comb‐referenced QPI will enable in‐depth understanding of dynamic motions in cellular, biomolecular, and microphysical samples.

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“…Therefore, speckle formation can be changed by controlling the coherence of light. A number of techniques have been proposed to generate partially coherent or totally incoherent light [6][7][8]. One of the attractive methods is to use a multimode fiber (MMF) since it supports hundreds of waveguide modes which could effectively reduce the spatial coherence when light is propagating through MMF [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Tailoring of spatial coherence in a multimode fiber by selectively exciting groups of eigenmodes

Zhang

Manuylovich

et al. 2020

Opt. Express

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Control of the properties of speckle patterns produced by mutual interference of light waves is important for various applications of multimode optical fibers. It has been shown previously that a high signal-to-noise ratio in a multimode fiber can be achieved by preferential excitation of lower order spatial eigenmodes in optical fiber communication. Here we demonstrate that signal spatial coherence can be tailored by changing relative contributions of the lower and higher order multimode fiber eigenmodes for the research of speckle formation and spatial coherence. It is found that higher order spatial eigenmodes are more conducive to the final speckle formation. The minimum speckle contrast occurs in the lower order spatial eigenmodes dominated regime. This work paves the way for control and manipulation of the spatial coherence of light in a multimode fiber varying from partially coherent or totally incoherent light.

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High-brightness laser imaging with tunable speckle reduction enabled by electroactive micro-optic diffusers

Cited by 32 publications

References 29 publications

Scattering‐Based Light‐Sheet Microscopy for Rapid Cellular Imaging of Fresh Tissue

Scattering‐Based Light‐Sheet Microscopy for Rapid Cellular Imaging of Fresh Tissue

Coherence‐Tailored Multiwavelength High‐Speed Quantitative Phase Imaging with a High Phase Stability via a Frequency Comb

Tailoring of spatial coherence in a multimode fiber by selectively exciting groups of eigenmodes

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