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Deep Learning Driven Noise Reduction for Reduced Flux Computed Tomography

Deep neural networks have received considerable attention in clinical imaging, particularly with respect to the reduction of radiation risk. Lowering the radiation dose by reducing the photon flux inevitably results in the degradation of the scanned image quality. Thus, researchers have sought to ex...

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Autores principales: Alsamadony, Khalid L., Yildirim, Ertugrul U., Glatz, Guenther, Waheed, Umair Bin, Hanafy, Sherif M.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2021
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7967200/
https://www.ncbi.nlm.nih.gov/pubmed/33803464
http://dx.doi.org/10.3390/s21051921
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author Alsamadony, Khalid L.
Yildirim, Ertugrul U.
Glatz, Guenther
Waheed, Umair Bin
Hanafy, Sherif M.
author_facet Alsamadony, Khalid L.
Yildirim, Ertugrul U.
Glatz, Guenther
Waheed, Umair Bin
Hanafy, Sherif M.
author_sort Alsamadony, Khalid L.
collection PubMed
description Deep neural networks have received considerable attention in clinical imaging, particularly with respect to the reduction of radiation risk. Lowering the radiation dose by reducing the photon flux inevitably results in the degradation of the scanned image quality. Thus, researchers have sought to exploit deep convolutional neural networks (DCNNs) to map low-quality, low-dose images to higher-dose, higher-quality images, thereby minimizing the associated radiation hazard. Conversely, computed tomography (CT) measurements of geomaterials are not limited by the radiation dose. In contrast to the human body, however, geomaterials may be comprised of high-density constituents causing increased attenuation of the X-rays. Consequently, higher-dose images are required to obtain an acceptable scan quality. The problem of prolonged acquisition times is particularly severe for micro-CT based scanning technologies. Depending on the sample size and exposure time settings, a single scan may require several hours to complete. This is of particular concern if phenomena with an exponential temperature dependency are to be elucidated. A process may happen too fast to be adequately captured by CT scanning. To address the aforementioned issues, we apply DCNNs to improve the quality of rock CT images and reduce exposure times by more than 60%, simultaneously. We highlight current results based on micro-CT derived datasets and apply transfer learning to improve DCNN results without increasing training time. The approach is applicable to any computed tomography technology. Furthermore, we contrast the performance of the DCNN trained by minimizing different loss functions such as mean squared error and structural similarity index.
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spelling pubmed-79672002021-03-18 Deep Learning Driven Noise Reduction for Reduced Flux Computed Tomography Alsamadony, Khalid L. Yildirim, Ertugrul U. Glatz, Guenther Waheed, Umair Bin Hanafy, Sherif M. Sensors (Basel) Article Deep neural networks have received considerable attention in clinical imaging, particularly with respect to the reduction of radiation risk. Lowering the radiation dose by reducing the photon flux inevitably results in the degradation of the scanned image quality. Thus, researchers have sought to exploit deep convolutional neural networks (DCNNs) to map low-quality, low-dose images to higher-dose, higher-quality images, thereby minimizing the associated radiation hazard. Conversely, computed tomography (CT) measurements of geomaterials are not limited by the radiation dose. In contrast to the human body, however, geomaterials may be comprised of high-density constituents causing increased attenuation of the X-rays. Consequently, higher-dose images are required to obtain an acceptable scan quality. The problem of prolonged acquisition times is particularly severe for micro-CT based scanning technologies. Depending on the sample size and exposure time settings, a single scan may require several hours to complete. This is of particular concern if phenomena with an exponential temperature dependency are to be elucidated. A process may happen too fast to be adequately captured by CT scanning. To address the aforementioned issues, we apply DCNNs to improve the quality of rock CT images and reduce exposure times by more than 60%, simultaneously. We highlight current results based on micro-CT derived datasets and apply transfer learning to improve DCNN results without increasing training time. The approach is applicable to any computed tomography technology. Furthermore, we contrast the performance of the DCNN trained by minimizing different loss functions such as mean squared error and structural similarity index. MDPI 2021-03-09 /pmc/articles/PMC7967200/ /pubmed/33803464 http://dx.doi.org/10.3390/s21051921 Text en © 2021 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Alsamadony, Khalid L.
Yildirim, Ertugrul U.
Glatz, Guenther
Waheed, Umair Bin
Hanafy, Sherif M.
Deep Learning Driven Noise Reduction for Reduced Flux Computed Tomography
title Deep Learning Driven Noise Reduction for Reduced Flux Computed Tomography
title_full Deep Learning Driven Noise Reduction for Reduced Flux Computed Tomography
title_fullStr Deep Learning Driven Noise Reduction for Reduced Flux Computed Tomography
title_full_unstemmed Deep Learning Driven Noise Reduction for Reduced Flux Computed Tomography
title_short Deep Learning Driven Noise Reduction for Reduced Flux Computed Tomography
title_sort deep learning driven noise reduction for reduced flux computed tomography
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7967200/
https://www.ncbi.nlm.nih.gov/pubmed/33803464
http://dx.doi.org/10.3390/s21051921
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