Related papers: 3D Wasserstein generative adversarial network with dense U-Net based discriminator for preclinical fMRI denoising

3D Wasserstein generative adversarial network with dense U-Net based discriminator for preclinical fMRI denoising

URL: http://arxiv.org/abs/2411.19345v1
Date: Thu, 28 Nov 2024 19:47:43 GMT
Title: 3D Wasserstein generative adversarial network with dense U-Net based discriminator for preclinical fMRI denoising
Authors: Sima Soltanpour, Arnold Chang, Dan Madularu, Praveen Kulkarni, Craig Ferris, Chris Joslin,
Abstract summary: Functional magnetic resonance imaging (fMRI) is extensively used in clinical and preclinical settings to study brain function. Denoising is one of the main preprocessing steps in any fMRI analysis pipeline. We propose a structure-preserved algorithm based on a 3D Wasserstein generative adversarial network with a 3D dense U-net based discriminator called, 3D U-WGAN.
Score: 0.6597195879147555
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Abstract: Functional magnetic resonance imaging (fMRI) is extensively used in clinical and preclinical settings to study brain function, however, fMRI data is inherently noisy due to physiological processes, hardware, and external noise. Denoising is one of the main preprocessing steps in any fMRI analysis pipeline. This process is challenging in preclinical data in comparison to clinical data due to variations in brain geometry, image resolution, and low signal-to-noise ratios. In this paper, we propose a structure-preserved algorithm based on a 3D Wasserstein generative adversarial network with a 3D dense U-net based discriminator called, 3D U-WGAN. We apply a 4D data configuration to effectively denoise temporal and spatial information in analyzing preclinical fMRI data. GAN-based denoising methods often utilize a discriminator to identify significant differences between denoised and noise-free images, focusing on global or local features. To refine the fMRI denoising model, our method employs a 3D dense U-Net discriminator to learn both global and local distinctions. To tackle potential over-smoothing, we introduce an adversarial loss and enhance perceptual similarity by measuring feature space distances. Experiments illustrate that 3D U-WGAN significantly improves image quality in resting-state and task preclinical fMRI data, enhancing signal-to-noise ratio without introducing excessive structural changes in existing methods. The proposed method outperforms state-of-the-art methods when applied to simulated and real data in a fMRI analysis pipeline.

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