Research on Denoising of Cryo-em Images Based on Deep Learning

Ouyang, Jianquan; Yi, He; Tang, Helen; Fu, Zhousong

doi:10.32604/jihpp.2020.010657

Cited by 6 publications

(4 citation statements)

References 9 publications

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“…GANs have also been recently used for denoising tasks with success. For example, [25] implement a GAN as a tool to recover structural information from cryoelectron microscopy data; [26] that apply a β-GAN combining GANs and auto-encoders to achieve a robust estimate of certain distributional parameters under Huber contamination model with statistical optimality; or [27], which also use a GAN-based method with a modified discriminator that performs regression and helps to stabilize the training process. Denoising Optical Coherence Tomography is also a task where GANs have been widely used.…”

Section: B Deep Learning (Dl) Based Methodsmentioning

confidence: 99%

Generalizable Denoising of Microscopy Images using Generative Adversarial Networks and Contrastive Learning

Fuentes-Hurtado,

Sibarita,

Viasnoff

2024

Preprint

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Microscopy images often suffer from high levels of noise, which can hinder further analysis and interpretation. Content-aware image restoration (CARE) methods have been proposed to address this issue, but they often require large amounts of training data and suffer from over-fitting. To overcome these challenges, we propose a novel framework for few-shot microscopy image denoising. Our approach combines a generative adversarial network (GAN) trained via contrastive learning (CL) with two structure preserving loss terms – Structural Similarity Index and Total Variation loss – to further improve the quality of the denoised images using little data. We demonstrate the effectiveness of our method on three well-known microscopy imaging datasets, and show that we can drastically reduce the amount of training data while retaining the quality of the denoising, thus alleviating the burden of acquiring paired data and enabling few-shot learning. The proposed framework can be easily extended to other image restoration tasks and has the potential to significantly advance the field of microscopy image analysis.

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Section: B Deep Learning (Dl) Based Methodsmentioning

confidence: 99%

Generalizable Denoising of Microscopy Images using Generative Adversarial Networks and Contrastive Learning

Fuentes-Hurtado,

Sibarita,

Viasnoff

2024

Preprint

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“…Dehaze-Net [9] processes blurred images by estimating the transmission matrix, but inaccurate transmission mapping estimation reduces the dehazing effect of the model. The idea of applying GAN network to denoising is usually analogic to the use of a generator for generating denoising images, and a discriminator for judging denoising effects [27]. GFN-Net [28] employees a dual-branch [29] convolutional neural network to extract basic features and recovery features respectively.…”

Section: Learning-based Methodsmentioning

confidence: 99%

CLGA Net: Cross Layer Gated Attention Network for Image Dehazing

Wang¹,

Huang²,

Wong³

et al. 2023

Computers, Materials &Amp; Continua

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In this paper, we propose an end-to-end cross-layer gated attention network (CLGA-Net) to directly restore fog-free images. Compared with the previous dehazing network, the dehazing model presented in this paper uses the smooth cavity convolution and local residual module as the feature extractor, combined with the channel attention mechanism, to better extract the restored features. A large amount of experimental data proves that the defogging model proposed in this paper is superior to previous defogging technologies in terms of structure similarity index (SSIM), peak signal to noise ratio (PSNR) and subjective visual quality. In order to improve the efficiency of decoding and encoding, we also describe a fusion residual module and conduct ablation experiments, which prove that the fusion residual is suitable for the dehazing problem. Therefore, we use fusion residual as a fixed module for encoding and decoding. In addition, we found that the traditional defogging model based on the U-net network may cause some information losses in space. We have achieved effective maintenance of low-level feature information through the cross-layer gating structure that better takes into account global and subtle features. We also present the application of our CLGA-Net in challenging scenarios where the best results in both quantity and quality can be obtained. Experimental results indicate that the present cross-layer gating module can be widely used in the same type of network.

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“…For example, Dehaze-Net deal with hazy images by estimating the transmission matrix, but an inaccurate estimation of the transmission map will reduce the model's dehazing effect. The method of using GAN network to denoise often uses a generator to generate a denoised image and a discriminator to judge the effect of denoising, such as [16]. AOD-Net uses a deformed atmospheric scattering model, which generalizes two unknowns in the atmospheric scattering model to a single unknown to reduce the loss in the dehazing process.…”

Section: Learning-based Methodsmentioning

confidence: 99%

FPD Net: Feature Pyramid DehazeNet

Wang¹,

Chen²,

Jin-gui³

et al. 2022

Computer Systems Science and Engineering

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We propose an end-to-end dehazing model based on deep learning (CNN network) and uses the dehazing model re-proposed by AOD-Net based on the atmospheric scattering model for dehazing. Compare to the previously proposed dehazing network, the dehazing model proposed in this paper make use of the FPN network structure in the field of target detection, and uses five feature maps of different sizes to better obtain features of different proportions and different sub-regions. A large amount of experimental data proves that the dehazing model proposed in this paper is superior to previous dehazing technologies in terms of PSNR, SSIM, and subjective visual quality. In addition, it achieved a good performance in speed by using EfficientNet B0 as a feature extractor. We find that only using high-level semantic features can not effectively obtain all the information in the image. The FPN structure used in this paper can effectively integrate the high-level semantics and the low-level semantics, and can better take into account the global and local features. The five feature maps with different sizes are not simply weighted and fused. In order to keep all their information, we put them all together and get the final features through decode layers. At the same time, we have done a comparative experiment between ResNet with FPN and EfficientNet with BiFPN. It is proved that EfficientNet with BiFPN can obtain image features more efficiently. Therefore, EfficientNet with BiFPN is chosen as our network feature extraction.

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Research on Denoising of Cryo-em Images Based on Deep Learning

Cited by 6 publications

References 9 publications

Generalizable Denoising of Microscopy Images using Generative Adversarial Networks and Contrastive Learning

Generalizable Denoising of Microscopy Images using Generative Adversarial Networks and Contrastive Learning

CLGA Net: Cross Layer Gated Attention Network for Image Dehazing

FPD Net: Feature Pyramid DehazeNet

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