Abstract
We propose a Generative Adversarial Network (GAN) optimized for noise reduction in CT-scans. The objective of CT scan denoising is to obtain higher quality imagery using a lower radiation exposure to the patient. Recent work in computer vision has shown that the use of Charbonnier distance as a term in the perceptual loss of a GAN can improve the performance of image reconstruction and video super-resolution. However, the use of a Charbonnier structural loss term has not yet been applied or evaluated for the purpose of CT scan denoising. Our proposed GAN makes use of a Wasserstein adversarial loss, a pretrained VGG19 perceptual loss, as well as a Charbonnier distance structural loss. We evaluate our approach using both applied Poisson noise distribution in order to simulate low-dose CT imagery, as well as using an anthropomorphic thoracic phantom at different exposure levels. Our evaluation criteria are Peek Signal to Noise (PSNR) as well as Structured Similarity (SSIM) of the denoised images, and we compare the results of our method versus recent state of the art deep denoising GANs. In addition, we report global noise through uniform soft tissue mediums. Our findings show that the incorporation of the Charbonnier Loss with the VGG-19 network improves the performance of the denoising as measured with the PSNR and SSIM, and that the method greatly reduces soft tissue noise to levels comparable to the NDCT scan.
Highlights
C OMPUTED Tomography (CT) is an x-ray imaging procedure where a narrow beam of x-rays enters the patient’s body from many angles and offsets; these are reconstructed to form cross-sectional images or “slices” of the body
We demonstrate that our proposed CL-Generative Adversarial Network (GAN) architecture improves the overall quality of CT scan images and compares favorably against related deep denoising GANs that have been developed for this task
We compare against a L1 structural loss GAN, the Mean Squared Error (MSE) structural loss GAN, and the Wasserstein adversarial loss GAN
Summary
C OMPUTED Tomography (CT) is an x-ray imaging procedure where a narrow beam of x-rays enters the patient’s body from many angles and offsets; these are reconstructed to form cross-sectional images or “slices” of the body. These slices are in turn analyzed for diagnostic purposes. Most studies of CT-scan denoising, including ours, attempt to simulate LDCT for evaluation purposes by applying Poisson noise to the image. Radiologists prefer CT-scans with lower image noise when attempting to identify low-contrast structures for diagnostic purposes
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