Flexible-type ultrathin holographic endoscope for microscopic imaging of unstained biological tissues

Choi, Wonjun; Kang, Munkyu; Hong, Jin Hee; Katz, Ori; Lee, Byunghak; Kim, Guang Hoon; Choi, Youngwoon; Choi, Wonshik

doi:10.1038/s41467-022-32114-5

Cited by 33 publications

(27 citation statements)

References 44 publications

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“…, where ΔD eff is the average core-to-core spacing of the fiber bundle. 31 In applications where endoscopic imaging is conducted for targets with low reflectance, such as biological tissues, it often becomes necessary to position the fiber probe close to the sample to capture more signals. In such scenarios, the reduction of the view field diameter of the previous algorithms, which is proportional to the distance, becomes a major problem.…”

Section: Comparison Between Different Lossmentioning

confidence: 99%

Object Function Retrieval by Model-Based Optimization in Fourier Holographic Endoscopy

Nguyen,

Kang,

Tran

et al. 2024

ACS Photonics

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Holographic endoscopes have garnered extensive attention not only for their compactness but also for their high-resolution and wide-field imaging capabilities. However, their practical use is challenging due to the reliance on Fesnel approximations in the underlying image reconstruction protocol, limiting their real-world applications. In this study, we present a model-based optimization algorithm that successfully retrieves an object function in a fiber bundle holographic endoscope. By developing a mathematical model that eliminates the need for approximations, our optimization extends the working range and expands the field of view of a fiber bundle holographic endoscope while preserving its advantages. These advancements significantly enhance the utility and feasibility of holographic endoscopes for various diagnostic procedures.

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Section: Comparison Between Different Lossmentioning

confidence: 99%

Object Function Retrieval by Model-Based Optimization in Fourier Holographic Endoscopy

Nguyen,

Kang,

Tran

et al. 2024

ACS Photonics

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“…Alternatively, a transmission matrix can be calibrated by illuminating the proximal end and measuring the backward propagating wavefronts from the partial reflectors at the distal tip 78 – 80 Recently, it has also been shown that a target object itself can serve as a guide star to identify the core-to-core phase retardations of the MCF and reconstruct a diffraction-limited and pixelation-free image 81 . With the reflection matrix of the MCF measured with core-to-core illumination, the singly-reflected waves from a target object can be coherently accumulated based on the adaptive algorithm, called closed-loop accumulation of single scattering 82 …”

Section: Advanced Techniquesmentioning

confidence: 99%

“…[78][79][80] Recently, it has also been shown that a target object itself can serve as a guide star to identify the core-to-core phase retardations of the MCF and reconstruct a diffractionlimited and pixelation-free image. 81 With the reflection matrix of the MCF measured with core-to-core illumination, the singly-reflected waves from a target object can be coherently accumulated based on the adaptive algorithm, called closed-loop accumulation of single scattering. 82 Another notable approach is to estimate the transmission matrix from the partial information of the matrix elements, which is possible due to the cylindrically symmetric behavior of light within conventional optical fibers with a circular cross-section, called the "rotational memory effect."…”

Section: In Situ Transmission Matrix Calibrationmentioning

confidence: 99%

Review of endomicroscopic imaging with coherent manipulation of light through an ultrathin probe

Lee

Song

et al. 2023

J. Optical Microsystems

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Endomicroscopy is a technique to visualize microscopic structures of internal tissues through tubular instruments that can be inserted through a small cut or an opening in the body. There has been a growing demand for miniaturizing endoscopic instruments while preserving a high resolution to achieve a real-time histopathologic diagnosis. Meanwhile, there has recently been tremendous progress in the coherent manipulation of light in which an optical wave is deterministically manipulated through a linear, disordered medium for optical focusing and imaging. Here, we review recent research efforts in developing new endomicroscopic imaging schemes based on the coherent formulation and manipulation of optical fibers. In contrast to the conventional schemes using optical fibers as incoherent channels for optical power, these approaches provide a route to fully exploiting useful information transmitted through an ultrathin probe, thereby potentially achieving practical endomicroscopic imaging through a submillimeter thick probe.

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“…Combined with computational imaging methods, MCF imaging technology can achieve a high imaging resolution and flexibility . [14][15][16] Choi et al reported a fully flexible ultrathin fiber endoscope obtaining 3D holographic images of unstained tissues . [15] Orth et al proved that MCF can record depth information and realize 3D imaging .…”

Section: Introductionmentioning

confidence: 99%

“…[14][15][16] Choi et al reported a fully flexible ultrathin fiber endoscope obtaining 3D holographic images of unstained tissues . [15] Orth et al proved that MCF can record depth information and realize 3D imaging . [17] However, MCFbased endoscopes have limitations such as low resolution, large footprint, and pixelated images.…”

Section: Introductionmentioning

confidence: 99%

Robust Super‐Resolution Image Transmission Based on a Ring Core Fiber with Orbital Angular Momentum

Wu,

Gao,

Zhou

et al. 2023

Laser & Photonics Reviews

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Single‐fiber imaging technology offers unique insights for research and inspection in difficult‐to‐reach and narrow spaces. In particular, ultra‐compact multimode fiber (MMF) imaging, has received increasing interest over the past decade. However, MMF imaging will be seriously distorted when subjected to dynamic perturbations due to time‐varying mode coupling, and the imaging of space objects via Gaussian beam will be relatively degraded at the edge due to insufficient contrast. Here, a robust super‐resolution image transmission method based on a ring core fiber (RCF) with orbital angular momentum (OAM) is proposed and experimentally demonstrated. The OAM modes propagating in the RCF form a series of weakly coupled mode groups, making the imaging system robust to external perturbations. In addition, a spiral phase plate is used as a vortex filter to produce OAM for edge enhancement, thus improving the image resolution. Furthermore, a few‐shot U‐Transformer neural network is proposed to enhance the resilience of the developed RCF‐OAM imaging system against environmental perturbations. Finally, the developed RCF‐OAM imaging system achieves biological image transmission, demonstrating the practicality of the scheme. This pioneering RCF OAM image transmission system may have broad applications, potentially revolutionizing fields such as biological imaging and industrial non‐destructive testing.

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Flexible-type ultrathin holographic endoscope for microscopic imaging of unstained biological tissues

Cited by 33 publications

References 44 publications

Object Function Retrieval by Model-Based Optimization in Fourier Holographic Endoscopy

Object Function Retrieval by Model-Based Optimization in Fourier Holographic Endoscopy

Review of endomicroscopic imaging with coherent manipulation of light through an ultrathin probe

Robust Super‐Resolution Image Transmission Based on a Ring Core Fiber with Orbital Angular Momentum

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