Abstract
Generative adversarial network (GAN) has been applied for low-dose CT images to predict normal-dose CT images. However, the undesired artifacts and details bring uncertainty to the clinical diagnosis. In order to improve the visual quality while suppressing the noise, in this paper, we mainly studied the two key components of deep learning based low-dose CT (LDCT) restoration models—network architecture and adversarial loss, and proposed a disentangled noise suppression method based on GAN (DNSGAN) for LDCT. Specifically, a generator network, which contains the noise suppression and structure recovery modules, is proposed. Furthermore, a multi-scaled relativistic adversarial loss is introduced to preserve the finer structures of generated images. Experiments on simulated and real LDCT datasets show that the proposed method can effectively remove noise while recovering finer details and provide better visual perception than other state-of-the-art methods.
Highlights
Low-dose CT denoising has been a hot topic in medical imaging and numerous methods have been proposed to deal with this problem [1]
Image post processing methods need not access the measurements and many methods [8,9,10,11,12,13,14,15] proposed for natural image restoration can be directly introduced for low-dose CT (LDCT) denoising, such as non-local means [8, 9], K-means singular value decomposition (KSVD) [10], and block-matching and 3D filtering (BM3D) [13]
Proposed disentangled noise suppression method based on GAN (DNSGAN) fitted the curve of ground truth best
Summary
Low-dose CT denoising has been a hot topic in medical imaging and numerous methods have been proposed to deal with this problem [1]. These algorithms could be approximately categorized into three groups according to the processing stage: Sinogram filtering, iterative reconstruction (IR), and image post processing methods. Image post processing methods need not access the measurements and many methods [8,9,10,11,12,13,14,15] proposed for natural image restoration can be directly introduced for low-dose CT (LDCT) denoising, such as non-local means [8, 9], K-means singular value decomposition (KSVD) [10], and block-matching and 3D filtering (BM3D) [13].
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