Jinrong Hu scite author profile

Structure-preserved denoising of 3D magnetic resonance imaging (MRI) images is a critical step in medical image analysis. Over the past few years, many algorithms with impressive performances have been proposed. In this paper, inspired by the idea of deep learning, we introduce an MRI denoising method based on the residual encoder-decoder Wasserstein generative adversarial network (RED-WGAN). Specifically, to explore the structure similarity between neighboring slices, a 3D configuration is utilized as the basic processing unit. Residual autoencoders combined with deconvolution operations are introduced into the generator network. Furthermore, to alleviate the oversmoothing shortcoming of the traditional mean squared error (MSE) loss function, the perceptual similarity, which is implemented by calculating the distances in the feature space extracted by a pretrained VGG-19 network, is incorporated with the MSE and adversarial losses to form the new loss function. Extensive experiments are implemented to assess the performance of the proposed method. The experimental results show that the proposed RED-WGAN achieves performance superior to several state-of-the-art methods in both simulated and real clinical data. In particular, our method demonstrates powerful abilities in both noise suppression and structure preservation.

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VisDrone-VID2019: The Vision Meets Drone Object Detection in Video Challenge Results

Zhu

Zhang

Bo³

et al. 2019

144

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A new CT metal artifacts reduction algorithm based on fractional-order sinogram inpainting

Zhang

et al. 2011

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Robust Multimodal Image Registration Using Deep Recurrent Reinforcement Learning

Sun

Yao

et al. 2019

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The crucial components of a conventional image registration method are the choice of the right feature representations and similarity measures. These two components, although elaborately designed, are somewhat handcrafted using human knowledge. To this end, these two components are tackled in an end-to-end manner via reinforcement learning in this work. Specifically, an artificial agent, which is composed of a combined policy and value network, is trained to adjust the moving image toward the right direction. We train this network using an asynchronous reinforcement learning algorithm, where a customized reward function is also leveraged to encourage robust image registration. This trained network is further incorporated with a lookahead inference to improve the registration capability. The advantage of this algorithm is fully demonstrated by our superior performance on clinical MR and CT image pairs to other state-of-the-art medical image registration methods.

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Jinrong Hu

Denoising of 3D magnetic resonance images using a residual encoder–decoder Wasserstein generative adversarial network

VisDrone-VID2019: The Vision Meets Drone Object Detection in Video Challenge Results

A new CT metal artifacts reduction algorithm based on fractional-order sinogram inpainting

Robust Multimodal Image Registration Using Deep Recurrent Reinforcement Learning

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