Learning to Reconstruct Confocal Microscopy Stacks from Single Light Field Images

Page, Josue; Saltarin, Federico; Belyaev, Yury; Lyck, Ruth; Favaro, Paolo

doi:10.48550/arxiv.2003.11004

Cited by 2 publications

(2 citation statements)

References 35 publications

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“…With the progress of computational imaging, deep learning based 2D-to-3D super-resolution methods are gradually emerging. Page et al [30] proposed LFMNet to reconstruct confocal microscopy stacks from single light filed images. Wu et al [17] proposed Deep-Z model based on GAN, which can refocus single 2D wide-field fluorescence images to obtain 3D images.…”

Section: D-to-3d Super Resolutionmentioning

confidence: 99%

Reconstruct high-resolution multi-focal plane images from a single 2D wide field image

Ma,

Liu,

Cheng

et al. 2020

Preprint

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High-resolution 3D medical images are important for analysis and diagnosis, but axial scanning to acquire them is very time-consuming. In this paper, we propose a fast end-to-end multi-focal plane imaging network (MFPINet) to reconstruct high-resolution multi-focal plane images from a single 2D low-resolution wild filed image without relying on scanning. To acquire realistic MFP images fast, the proposed MFPINet adopts generative adversarial network framework and the strategies of postsampling and refocusing all focal planes at one time. We conduct a series experiments on cytology microscopy images and demonstrate that MFPINet performs well on both axial refocusing and horizontal super resolution. Furthermore, MFPINet is approximately 24 times faster than current refocusing methods for reconstructing the same volume images. The proposed method has the potential to greatly increase the speed of high-resolution 3D imaging and expand the application of low-resolution wide-field images.

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Section: D-to-3d Super Resolutionmentioning

confidence: 99%

Reconstruct high-resolution multi-focal plane images from a single 2D wide field image

Ma,

Liu,

Cheng

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…In this work we aim at describing a specimen volume through computationally segmenting the ZStack into object pixels of interest, making use of our previous work on refocusing [5]. The possibility of fully reconstructing a volume from an LF microscope image has been investigated in [10] and [11]. Both works utilize single-shot LF microscope images with high angular resolution.…”

Section: Introductionmentioning

confidence: 99%

Volumetric segmentation for integral microscopy with Fourier plane recording

Sergio¹,

Bregović²,

Gotchev³

2022

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Light Field (LF) microscopy has emerged as a fast growing field of interest in the last two decades for its undoubted capacity of capturing in-vivo samples from multiple perspectives. In this work we present a framework for Volumetric Segmentation of LF images created following the setup of a Fourier Integral Microscope (FIMic). In the proposed framework, we convert the FIMiccaptured LF into a three-dimensional Focal Stack (FS) to be used as an input to machine learning models with the aim to get the 3D locations of the specimen of interest. Using a synthetic dataset generated in Blender, we train three neural networks based on the U-Net architecture and merge their outputs to achieve the desired volumetric segmentation. In our main test results we achieve a precision of more than 95%, while in the related tests we still achieve a value higher than 80%.

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Learning to Reconstruct Confocal Microscopy Stacks from Single Light Field Images

Cited by 2 publications

References 35 publications

Reconstruct high-resolution multi-focal plane images from a single 2D wide field image

Reconstruct high-resolution multi-focal plane images from a single 2D wide field image

Volumetric segmentation for integral microscopy with Fourier plane recording

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