Unsupervised denoising in spectral CT: multi-dimensional U-Net for energy channel regularisation
Unsupervised denoising in spectral CT: multi-dimensional U-Net for energy channel regularisation
Spectral Computed Tomography (CT) is a versatile imaging technique widely utilized in industry, medicine, and scientific research. This technique allows us to observe the energy-dependent X-ray attenuation throughout an object by using Photon Counting Detector (PCD) technology. However, a major drawback of spectral CT is the increase in noise due to a lower achievable photon count when using more energy channels. This challenge often complicates quantitative material identification, which is a major application of the technology. In this study, we investigate the Noise2Inverse image denoising approach for noise removal in spectral computed tomography. Our unsupervised deep learning-based model uses a multi-dimensional U-Net paired with a block-based training approach modified for additional energy-channel regularization. We conducted experiments using two simulated spectral CT phantoms, each with a unique shape and material composition, and a real scan of a biological sample containing a characteristic K-edge. Measuring the peak signal-to-noise ratio (PSNR) and structural similarity index (SSIM) for the simulated data and the contrast-to-noise ratio (CNR) for the real-world data, our approach not only outperforms previously used methods—namely the unsupervised Low2High method and the total variation-constrained iterative reconstruction method—but also does not require complex parameter tuning.
deep learning, Spectral Computed Tomography, unsupervised denoising method
Kumrular, Raziye Kubra
fe5d02e3-e6eb-46e7-b450-9b3d4033290c
Blumensath, Thomas
470d9055-0373-457e-bf80-4389f8ec4ead
Kumrular, Raziye Kubra
fe5d02e3-e6eb-46e7-b450-9b3d4033290c
Blumensath, Thomas
470d9055-0373-457e-bf80-4389f8ec4ead
Kumrular, Raziye Kubra and Blumensath, Thomas
(2024)
Unsupervised denoising in spectral CT: multi-dimensional U-Net for energy channel regularisation.
Sensors, 24 (20), [6654].
(doi:10.3390/s2420665).
Abstract
Spectral Computed Tomography (CT) is a versatile imaging technique widely utilized in industry, medicine, and scientific research. This technique allows us to observe the energy-dependent X-ray attenuation throughout an object by using Photon Counting Detector (PCD) technology. However, a major drawback of spectral CT is the increase in noise due to a lower achievable photon count when using more energy channels. This challenge often complicates quantitative material identification, which is a major application of the technology. In this study, we investigate the Noise2Inverse image denoising approach for noise removal in spectral computed tomography. Our unsupervised deep learning-based model uses a multi-dimensional U-Net paired with a block-based training approach modified for additional energy-channel regularization. We conducted experiments using two simulated spectral CT phantoms, each with a unique shape and material composition, and a real scan of a biological sample containing a characteristic K-edge. Measuring the peak signal-to-noise ratio (PSNR) and structural similarity index (SSIM) for the simulated data and the contrast-to-noise ratio (CNR) for the real-world data, our approach not only outperforms previously used methods—namely the unsupervised Low2High method and the total variation-constrained iterative reconstruction method—but also does not require complex parameter tuning.
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sensors-24-06654-v2
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Accepted/In Press date: 7 October 2024
e-pub ahead of print date: 16 October 2024
Keywords:
deep learning, Spectral Computed Tomography, unsupervised denoising method
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Local EPrints ID: 495643
URI: http://eprints.soton.ac.uk/id/eprint/495643
ISSN: 1424-8220
PURE UUID: 49fe4f7d-98d3-43fd-8ead-ba367352e65d
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Date deposited: 20 Nov 2024 17:31
Last modified: 21 Nov 2024 02:42
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Author:
Raziye Kubra Kumrular
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