Virtual and real-world implementation of deep-learning-based image denoising model on projection domain in digital tomosynthesis and cone-beam computed tomography data

David Shih Chun Jin; Li Sheng Chang; Yu Hong Wang; Jyh Cheng Chen; Snow H. Tseng; Tse Ying Liu

doi:10.1088/2057-1976/ac997d

Virtual and real-world implementation of deep-learning-based image denoising model on projection domain in digital tomosynthesis and cone-beam computed tomography data

David Shih Chun Jin, Li Sheng Chang, Yu Hong Wang, Jyh Cheng Chen^*, Snow H. Tseng, Tse Ying Liu

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Reducing the radiation dose will cause severe image noise and artifacts, and degradation of image quality will also affect the accuracy of diagnosis. To find a solution, we comprise a 2D and 3D concatenating convolutional encoder-decoder (CCE-3D) and the structural sensitive loss (SSL), via transfer learning (TL) denoising in the projection domain for low-dose computed tomography (LDCT), radiography, and tomosynthesis. The simulation and real-world practicing results show that many of the figures-of-merit (FOMs) increase in both projections (2-3 times) and CT imaging (1.5-2 times). From the PSNR and structural similarity index of measurement (SSIM), the CCE-3D model is effective in denoising but keeps the shape of the structure. Hence, we have developed a denoising model that can be served as a promising tool to be implemented in the next generation of x-ray radiography, tomosynthesis, and LDCT systems.

Original language	English
Article number	065021
Journal	Biomedical Physics and Engineering Express
Volume	8
Issue number	6
DOIs	https://doi.org/10.1088/2057-1976/ac997d
State	Published - Nov 2022

Keywords

3D concatenating convolutional encoder-decoder (CCE-3D)
denoising model
low-dose computed tomography (LDCT)
structural sensitive loss (SSL)
transfer learning (TL)

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10.1088/2057-1976/ac997d

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title = "Virtual and real-world implementation of deep-learning-based image denoising model on projection domain in digital tomosynthesis and cone-beam computed tomography data",

abstract = "Reducing the radiation dose will cause severe image noise and artifacts, and degradation of image quality will also affect the accuracy of diagnosis. To find a solution, we comprise a 2D and 3D concatenating convolutional encoder-decoder (CCE-3D) and the structural sensitive loss (SSL), via transfer learning (TL) denoising in the projection domain for low-dose computed tomography (LDCT), radiography, and tomosynthesis. The simulation and real-world practicing results show that many of the figures-of-merit (FOMs) increase in both projections (2-3 times) and CT imaging (1.5-2 times). From the PSNR and structural similarity index of measurement (SSIM), the CCE-3D model is effective in denoising but keeps the shape of the structure. Hence, we have developed a denoising model that can be served as a promising tool to be implemented in the next generation of x-ray radiography, tomosynthesis, and LDCT systems.",

keywords = "3D concatenating convolutional encoder-decoder (CCE-3D), denoising model, low-dose computed tomography (LDCT), structural sensitive loss (SSL), transfer learning (TL)",

author = "Jin, {David Shih Chun} and Chang, {Li Sheng} and Wang, {Yu Hong} and Chen, {Jyh Cheng} and Tseng, {Snow H.} and Liu, {Tse Ying}",

note = "Publisher Copyright: {\textcopyright} 2022 IOP Publishing Ltd.",

year = "2022",

month = nov,

doi = "10.1088/2057-1976/ac997d",

language = "English",

volume = "8",

journal = "Biomedical Physics and Engineering Express",

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publisher = "IOP Publishing Ltd.",

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Virtual and real-world implementation of deep-learning-based image denoising model on projection domain in digital tomosynthesis and cone-beam computed tomography data. / Jin, David Shih Chun; Chang, Li Sheng; Wang, Yu Hong et al.
In: Biomedical Physics and Engineering Express, Vol. 8, No. 6, 065021, 11.2022.

Research output: Contribution to journal › Article › peer-review

TY - JOUR

T1 - Virtual and real-world implementation of deep-learning-based image denoising model on projection domain in digital tomosynthesis and cone-beam computed tomography data

AU - Jin, David Shih Chun

AU - Chang, Li Sheng

AU - Wang, Yu Hong

AU - Chen, Jyh Cheng

AU - Tseng, Snow H.

AU - Liu, Tse Ying

PY - 2022/11

Y1 - 2022/11

N2 - Reducing the radiation dose will cause severe image noise and artifacts, and degradation of image quality will also affect the accuracy of diagnosis. To find a solution, we comprise a 2D and 3D concatenating convolutional encoder-decoder (CCE-3D) and the structural sensitive loss (SSL), via transfer learning (TL) denoising in the projection domain for low-dose computed tomography (LDCT), radiography, and tomosynthesis. The simulation and real-world practicing results show that many of the figures-of-merit (FOMs) increase in both projections (2-3 times) and CT imaging (1.5-2 times). From the PSNR and structural similarity index of measurement (SSIM), the CCE-3D model is effective in denoising but keeps the shape of the structure. Hence, we have developed a denoising model that can be served as a promising tool to be implemented in the next generation of x-ray radiography, tomosynthesis, and LDCT systems.

AB - Reducing the radiation dose will cause severe image noise and artifacts, and degradation of image quality will also affect the accuracy of diagnosis. To find a solution, we comprise a 2D and 3D concatenating convolutional encoder-decoder (CCE-3D) and the structural sensitive loss (SSL), via transfer learning (TL) denoising in the projection domain for low-dose computed tomography (LDCT), radiography, and tomosynthesis. The simulation and real-world practicing results show that many of the figures-of-merit (FOMs) increase in both projections (2-3 times) and CT imaging (1.5-2 times). From the PSNR and structural similarity index of measurement (SSIM), the CCE-3D model is effective in denoising but keeps the shape of the structure. Hence, we have developed a denoising model that can be served as a promising tool to be implemented in the next generation of x-ray radiography, tomosynthesis, and LDCT systems.

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ER -

Virtual and real-world implementation of deep-learning-based image denoising model on projection domain in digital tomosynthesis and cone-beam computed tomography data

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