Adaptive pixel-super-resolved lensfree in-line digital holography for wide-field on-chip microscopy

Zhang, Jialin; Sun, Jiasong; Chen, Qian; Li, Jiaji; Zuo, Chao

doi:10.1038/s41598-017-11715-x

Cited by 85 publications

(55 citation statements)

References 48 publications

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“…As the angle is 10 degrees, the equivalent pixel size is 0.382μm. It is smaller than the equivalent pixel size of 0.775μm in paper [8] and 0.770μm in paper [20] by the pixel size image sensor (1.67μm).…”

Section: Plos Onementioning

confidence: 75%

“…Finally, the super-resolution image of the cells can be reconstructed. When the pixel size of the linear array sensor is 2.2μm and the angle is 21 degrees, the equivalent pixel size is 0.79μm (Improved 2.8 times, and improved 2.15 times in paper [8,20]). After de-diffraction, the size error of 20μm microsphere was 3.249%, and the PSNR was improved 1.62 times, the SSIM was improved 3.96 times.…”

Section: Plos Onementioning

confidence: 99%

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A super-resolution scanning algorithm for lensless microfluidic imaging using the dual-line array image sensor

Tian

et al. 2020

PLoS ONE

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The lensless optical fluid microscopy is of great significance to the miniaturization, portability and low cost development of cell detection instruments. However, the resolution of the cell image collected directly is low, because the physical pixel size of the image sensor is the same order of magnitude as the cell size. To solve this problem, this paper proposes a super-resolution scanning algorithm using a dual-line array sensor and a microfluidic chip. For dual-line array sensor images, the multi-group velocity and acceleration of cells flowing through the line array sensor are calculated. Then the reconstruction model of the superresolution image is constructed with variable acceleration. By changing the angle between the line array image sensor and the direction of cell flow, the super-resolution image scanning and reconstruction are achieved in both horizontal and vertical directions. In addition, it is necessary to study the row by row extraction algorithm for cell foreground image. In this paper, the dual-line array sensor is implemented by adjusting the acquisition window of the image sensor with a pixel size of 2.2μm. When the tilt angle is 21 degrees, the equivalent pixel size is 0.79μm, improved 2.8 times, and after de-diffraction its average size error was 3.249%. As the angle decreases, the image resolution is higher, but the amount of information is less. This super-resolution scanning algorithm can be integrated on the chip and used with a microfluidic chip to realize on-chip instrument.

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Section: Plos Onementioning

confidence: 75%

Section: Plos Onementioning

confidence: 99%

A super-resolution scanning algorithm for lensless microfluidic imaging using the dual-line array image sensor

Tian

et al. 2020

PLoS ONE

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“…Both the subpixel super-resolution hologram and Z -stacked phase retrieval approach reduce reconstruction artifacts and enhance the resolution by up to two times. However, one of the promising results, concerning the resolution enhancement and phase recovery effects of these approaches, is reported by the Zuo group [ 23 ], who reported that only a Z -stacked image set was needed to achieve both super subpixel resolution and phase recovery. The approach makes the imaging apparatus a simple and a mobile platform compared with other 3D image generation methods, such as multi-angle [ 22 ] and multi-wavelength [ 30 ] holographic image generation to minimize the movable parts of an apparatus.…”

Section: Resultsmentioning

confidence: 99%

“…The Zuo group introduced Z -stacked hologram images to obtain high-resolution holographic images, with sub-pixel super-resolution and phase recovery, without a sub-pixel shift [ 23 ]. This approach can be adapted for simplifying the apparatus without using the nanometer resolution of the XY stage to obtain a sub-pixel hologram image.…”

Section: Discussionmentioning

confidence: 99%

“…Based on the 2D DIHM technology and its various merits, 3D section imaging technologies relating to volumetric samples have been suggested for a thick clear tissue, widespread whole blood cells, and polystyrene beads on a sliding glass, i.e., 3D imaging of CLARITY tissue [ 14 ], three-dimensional profiling and tracking [ 15 , 16 ], angled tomography [ 17 ], 3D image distortion compensation [ 18 ], and wide-field pathology slide imaging [ 19 ]. There are two significant challenges that must be overcome to achieve a wide FOV high resolution 3D image: Phase recovery and spatial under-sampling, based on an iterative reconstruction with a single shot hologram [ 20 , 21 ], multi-angle [ 22 ], multi-height [ 23 ], spatial shift [ 24 ], colorization [ 25 ] for color artifacts [ 26 ], a scattering medium [ 27 ], a diffuser [ 28 ], a scattering mask [ 29 ], and multi-wavelength [ 30 ]. In this 2D image reconstruction and phase recovery, twin image and spatial aliasing signals, along with other digital artifacts, were solved using each separate technology or an integrated propagating phaser approach based on this idea [ 31 ].…”

Section: Introductionmentioning

confidence: 99%

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Three-Dimensional High-Resolution Digital Inline Hologram Reconstruction with a Volumetric Deconvolution Method

Eom

Moon

2018

Sensors

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The digital in-line holographic microscope (DIHM) was developed for a 2D imaging technology and has recently been adapted to 3D imaging methods, providing new approaches to obtaining volumetric images with both a high resolution and wide field-of-view (FOV), which allows the physical limitations to be overcome. However, during the sectioning process of 3D image generation, the out-of-focus image of the object becomes a significant impediment to obtaining evident 3D features in the 2D sectioning plane of a thick biological sample. Based on phase retrieved high-resolution holographic imaging and a 3D deconvolution technique, we demonstrate that a high-resolution 3D volumetric image, which significantly reduces wave-front reconstruction and out-of-focus artifacts, can be achieved. The results show a 3D volumetric image that is more finely focused compared to a conventional 3D stacked image from 2D reconstructed images in relation to micron-size polystyrene beads, a whole blood smear, and a kidney tissue sample. We believe that this technology can be applicable for medical-grade images of smeared whole blood or an optically cleared tissue sample for mobile phytological microscopy and laser sectioning microscopy.

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Integrated Electrochemical and Optical Biosensing in Organs‐on‐Chip

Tawade,

Mastrangeli

2023

ChemBioChem

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Demand for biocompatible, non‐invasive, and continuous real‐time monitoring of organs‐on‐chip has driven the development of a variety of novel sensors. However, highest accuracy and sensitivity can arguably be achieved by integrated biosensing, which enables in situ monitoring of the in vitro microenvironment and dynamic responses of tissues and miniature organs recapitulated in organs‐on‐chip. This paper reviews integrated electrical, electrochemical, and optical sensing methods within organ‐on‐chip devices and platforms. By affording precise detection of analytes and biochemical reactions, these methods expand and advance the monitoring capabilities and reproducibility of organ‐on‐chip technology. The integration of these sensing techniques allows a deeper understanding of organ functions, and paves the way for important applications such as drug testing, disease modeling, and personalized medicine. By consolidating recent advancements and highlighting challenges in the field, this review aims to foster further research and innovation in the integration of biosensing in organs‐on‐chip.

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Adaptive pixel-super-resolved lensfree in-line digital holography for wide-field on-chip microscopy

Cited by 85 publications

References 48 publications

A super-resolution scanning algorithm for lensless microfluidic imaging using the dual-line array image sensor

A super-resolution scanning algorithm for lensless microfluidic imaging using the dual-line array image sensor

Three-Dimensional High-Resolution Digital Inline Hologram Reconstruction with a Volumetric Deconvolution Method

Integrated Electrochemical and Optical Biosensing in Organs‐on‐Chip

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