Untrained neural network enhances the resolution of structured illumination microscopy under strong background and noise levels

Yao, Yunhua; He, Ying; Huang, Zhangcheng; Qi, Dalong; Zhang, Chonglei; Huang, Xiaoshuai; Shi, Kebin; Ding, Pengpeng; Jin, Cheng; Deng, Lianzhong; Sun, Zhenrong; Yuan, Xiaocong; Zhang, Shian

doi:10.1117/1.apn.2.4.046005

Adv. Photon. Nexus

2023

DOI: 10.1117/1.apn.2.4.046005

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Untrained neural network enhances the resolution of structured illumination microscopy under strong background and noise levels

Yunhua Yao

Ying He

Zhangcheng Huang

et al.

Abstract: Structured illumination microscopy (SIM) has been widely applied in the superresolution imaging of subcellular dynamics in live cells. Higher spatial resolution is expected for the observation of finer structures. However, further increasing spatial resolution in SIM under the condition of strong background and noise levels remains challenging. Here, we report a method to achieve deep resolution enhancement of SIM by combining an untrained neural network with an alternating direction method of multipliers (ADM… Show more

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Cited by 3 publications

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Unsupervised reconstruction with a registered time-unsheared image constraint for compressed ultrafast photography

Zhou,

Song,

Yao

et al. 2024

Opt. Express

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Compressed ultrafast photography (CUP) is a computational imaging technology capable of capturing transient scenes in picosecond scale with a sequence depth of hundreds of frames. Since the inverse problem of CUP is an ill-posed problem, it is challenging to further improve the reconstruction quality under the condition of high noise level and compression ratio. In addition, there are many articles adding an external charge-coupled device (CCD) camera to the CUP system to form the time-unsheared view because the added constraint can improve the reconstruction quality of images. However, since the images are collected by different cameras, slight affine transformation may have great impacts on the reconstruction quality. Here, we propose an algorithm that combines the time-unsheared image constraint CUP system with unsupervised neural networks. Image registration network is also introduced into the network framework to learn the affine transformation parameters of input images. The proposed algorithm effectively utilizes the implicit image prior in the neural network as well as the extra hardware prior information brought by the time-unsheared view. Combined with image registration network, this joint learning model enables our proposed algorithm to further improve the quality of reconstructed images without training datasets. The simulation and experiment results demonstrate the application prospect of our algorithm in ultrafast event capture.

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Unsupervised reconstruction with a registered time-unsheared image constraint for compressed ultrafast photography

Zhou,

Song,

Yao

et al. 2024

Opt. Express

View full text Add to dashboard Cite

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High-speed super-resolution structured illumination microscopy with a large field-of-view

Guo,

Yao,

Huang

et al. 2024

Opt. Express

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Structured illumination microscopy (SIM) has been extensively employed for observing subcellular structures and dynamics. However, achieving high-speed super-resolution SIM with a large field of view (FOV) remains challenging due to the trade-offs among spatial resolution, imaging speed and FOV under limited bandwidth constraints. Here, we report a novel SIM technique to address this issue. By utilizing a high-speed camera and a rolling image reconstruction strategy to accelerate super-resolution image acquisition, as well as using a deep resolution enhancement to further improve spatial resolution, this SIM technique achieves imaging with a spatial resolution of 94 nm, a FOV of 102 × 102 µm2, and an imaging speed of 1333 frames per second. The exceptional imaging performance of this proposed SIM technique is experimentally demonstrated through the successful recording of the Brownian motion of fluorescent microspheres and the photobleaching of fluorescently labeled microtubules. This work offers a potential tool for the high-throughput observation of high-speed subcellular dynamics, which would bring significant applications in biomedical research.

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Untrained neural network enabling fast and universal structured-illumination microscopy

Ye,

Li,

Sun

et al. 2024

Opt. Lett.

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Structured-illumination microscopy (SIM) offers a twofold resolution enhancement beyond the optical diffraction limit. At present, SIM requires several raw structured-illumination (SI) frames to reconstruct a super-resolution (SR) image, especially the time-consuming reconstruction of speckle SIM, which requires hundreds of SI frames. Considering this, we herein propose an untrained structured-illumination reconstruction neural network (USRNN) with known illumination patterns to reduce the amount of raw data that is required for speckle SIM reconstruction by 20 times and thus improve its temporal resolution. Benefiting from the unsupervised optimizing strategy and CNNs’ structure priors, the high-frequency information is obtained from the network without the requirement of datasets; as a result, a high-fidelity SR image with approximately twofold resolution enhancement can be reconstructed using five frames or less. Experiments on reconstructing non-biological and biological samples demonstrate the high-speed and high-universality capabilities of our method.

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Untrained neural network enhances the resolution of structured illumination microscopy under strong background and noise levels

Cited by 3 publications

References 41 publications

Unsupervised reconstruction with a registered time-unsheared image constraint for compressed ultrafast photography

Unsupervised reconstruction with a registered time-unsheared image constraint for compressed ultrafast photography

High-speed super-resolution structured illumination microscopy with a large field-of-view

Untrained neural network enabling fast and universal structured-illumination microscopy

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