Unpaired Image Denoising via Wasserstein GAN in Low-Dose CT Image with Multi-Perceptual Loss and Fidelity Loss

Yin, Zhixian; Xia, Kewen; He, Ziping; Zhang, Jiangnan; Wang, Sijie; Zu, Baokai

doi:10.3390/sym13010126

Cited by 29 publications

(10 citation statements)

References 28 publications

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“…Apart from that, Li et al [ 37 ] have proposed a WGAN-based self-attention GAN to overcome the limitations of CNN-based LDCT denoising methods. In addition to these applications, recently Yin et al [ 49 ] have proposed a WGAN model with unpaired CT data. They have implemented a multiperceptual loss to determine the feature distribution between the LDCT and RDCT images.…”

Section: Introductionmentioning

confidence: 99%

InNetGAN: Inception Network-Based Generative Adversarial Network for Denoising Low-Dose Computed Tomography

Kulathilake

Abdullah

Bandara

et al. 2021

Journal of Healthcare Engineering

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Low-dose Computed Tomography (LDCT) has gained a great deal of attention in clinical procedures due to its ability to reduce the patient’s risk of exposure to the X-ray radiation. However, reducing the X-ray dose increases the quantum noise and artifacts in the acquired LDCT images. As a result, it produces visually low-quality LDCT images that adversely affect the disease diagnosing and treatment planning in clinical procedures. Deep Learning (DL) has recently become the cutting-edge technology of LDCT denoising due to its high performance and data-driven execution compared to conventional denoising approaches. Although the DL-based models perform fairly well in LDCT noise reduction, some noise components are still retained in denoised LDCT images. One reason for this noise retention is the direct transmission of feature maps through the skip connections of contraction and extraction path-based DL modes. Therefore, in this study, we propose a Generative Adversarial Network with Inception network modules (InNetGAN) as a solution for filtering the noise transmission through skip connections and preserving the texture and fine structure of LDCT images. The proposed Generator is modeled based on the U-net architecture. The skip connections in the U-net architecture are modified with three different inception network modules to filter out the noise in the feature maps passing over them. The quantitative and qualitative experimental results have shown the performance of the InNetGAN model in reducing noise and preserving the subtle structures and texture details in LDCT images compared to the other state-of-the-art denoising algorithms.

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Section: Introductionmentioning

confidence: 99%

InNetGAN: Inception Network-Based Generative Adversarial Network for Denoising Low-Dose Computed Tomography

Kulathilake

Abdullah

Bandara

et al. 2021

Journal of Healthcare Engineering

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“…The L style measures the statistical difference between the image generated after the activation layer and the target image. The Wasserstein distance [33] is to solve the problem that GAN is difficult to train and difficult to converge. The advantage of using the W[p, q] to measure the difference between the generated distribution p and the real distribution q is that when there is no intersection or a small intersection between p and q.…”

Section: Loss Functionsmentioning

confidence: 99%

Improving Human Image Synthesis with Residual Fast Fourier Transformation and Wasserstein Distance

Wu¹,

Si²,

Wang³

et al. 2022

Preprint

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With the rapid development of the Metaverse, virtual humans have emerged, and human image synthesis and editing techniques, such as pose transfer, have recently become popular. Most of the existing techniques rely on GANs, which can generate good human images even with large variants and occlusions. But from our best knowledge, the existing stateof-the-art method still has the following problems: the first is that the rendering effect of the synthetic image is not realistic, such as poor rendering of some regions. And the second is that the training of GAN is unstable and slow to converge, such as model collapse. Based on the above two problems, we propose several methods to solve them. To improve the rendering effect, we use the Residual Fast Fourier Transform Block to replace the traditional Residual Block. Then, spectral normalization and Wasserstein distance are used to improve the speed and stability of GAN training. Experiments demonstrate that the methods we offer are effective at solving the problems listed above, and we get state-of-the-art scores in LPIPS and PSNR.

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“…Wolterink et al 24 were the first ones to propose a generative adversarial network (GAN) for denoising of low dose CT images. Based on the adversarial learning method and the cost function (usually multi-objective functions) different variants exist with Wasserstein GAN and cycle-GAN being the two most studied models for image denoising of low dose CT. [25][26][27][28] For clinical low dose CT, a multitude of DL denoising models have been proposed, and each investigates different combinations of network architectures and loss functions. [14][15][16] Note that, besides image-to-image DL frameworks that serve as post-reconstruction tool, alternatives are to train the DL denoising model in the projection space or to develop an end-to-end DL algorithm that directly maps a noisy sinogram to a clean image (DL-based image reconstruction).…”

Section: Introductionmentioning

confidence: 99%

Dose reduction and image enhancement in micro‐CT using deep learning

et al. 2023

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Unpaired Image Denoising via Wasserstein GAN in Low-Dose CT Image with Multi-Perceptual Loss and Fidelity Loss

Cited by 29 publications

References 28 publications

InNetGAN: Inception Network-Based Generative Adversarial Network for Denoising Low-Dose Computed Tomography

InNetGAN: Inception Network-Based Generative Adversarial Network for Denoising Low-Dose Computed Tomography

Improving Human Image Synthesis with Residual Fast Fourier Transformation and Wasserstein Distance

Dose reduction and image enhancement in micro‐CT using deep learning

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