Resolution enhancement of lung 4D-CT data using multiscale interphase iterative nonlocal means

Purpose: Four-dimensional computer tomography (4D-CT) has been widely used in lung cancer radiotherapy due to its capability in providing important tumor motion information. However, the prolonged scanning duration required by 4D-CT causes considerable increase in radiation dose. To minimize the rad...

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Published in	Medical physics (Lancaster) Vol. 40; no. 5; pp. 051916 - n/a
Main Authors	Zhang, Yu, Yap, Pew-Thian, Wu, Guorong, Feng, Qianjin, Lian, Jun, Chen, Wufan, Shen, Dinggang
Format	Journal Article
Language	English
Published	United States American Association of Physicists in Medicine 01.05.2013
Subjects	60 APPLIED LIFE SCIENCES ALGORITHMS cancer CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS Computed tomography Computerised tomographs computerised tomography COMPUTERIZED TOMOGRAPHY Digital computing or data processing equipment or methods, specially adapted for specific applications DOSIMETRY Dosimetry/exposure assessment FOUR-DIMENSIONAL CALCULATIONS Four-Dimensional Computed Tomography - methods HEALTH HAZARDS Humans Image data processing or generation, in general Image enhancement IMAGE PROCESSING image reconstruction INTERPOLATION ITERATIVE METHODS lung Lung - diagnostic imaging lung 4D‐CT LUNGS medical image processing Medical image reconstruction Medical imaging nonlocal means Numerical approximation and analysis PEAKS Pneumodyamics, respiration RADIATION DOSES RADIATION PROTECTION AND DOSIMETRY radiation therapy RADIOLOGY AND NUCLEAR MEDICINE RADIOTHERAPY Reconstruction resolution enhancement SENSITIVITY SIGNAL-TO-NOISE RATIO SPATIAL RESOLUTION tumours X‐ray imaging nonlocal means lung 4D-CT resolution enhancement
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ISSN	0094-2405 2473-4209 1522-8541 2473-4209
DOI	10.1118/1.4802747

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Abstract	Purpose: Four-dimensional computer tomography (4D-CT) has been widely used in lung cancer radiotherapy due to its capability in providing important tumor motion information. However, the prolonged scanning duration required by 4D-CT causes considerable increase in radiation dose. To minimize the radiation-related health risk, radiation dose is often reduced at the expense of interslice spatial resolution. However, inadequate resolution in 4D-CT causes artifacts and increases uncertainty in tumor localization, which eventually results in extra damages of healthy tissues during radiotherapy. In this paper, the authors propose a novel postprocessing algorithm to enhance the resolution of lung 4D-CT data. Methods: The authors' premise is that anatomical information missing in one phase can be recovered from the complementary information embedded in other phases. The authors employ a patch-based mechanism to propagate information across phases for the reconstruction of intermediate slices in the longitudinal direction, where resolution is normally the lowest. Specifically, the structurally matching and spatially nearby patches are combined for reconstruction of each patch. For greater sensitivity to anatomical details, the authors employ a quad-tree technique to adaptively partition the image for more fine-grained refinement. The authors further devise an iterative strategy for significant enhancement of anatomical details. Results: The authors evaluated their algorithm using a publicly available lung data that consist of 10 4D-CT cases. The authors’ algorithm gives very promising results with significantly enhanced image structures and much less artifacts. Quantitative analysis shows that the authors’ algorithm increases peak signal-to-noise ratio by 3–4 dB and the structural similarity index by 3%–5% when compared with the standard interpolation-based algorithms. Conclusions: The authors have developed a new algorithm to improve the resolution of 4D-CT. It outperforms the conventional interpolation-based approaches by producing images with the markedly improved structural clarity and greatly reduced artifacts.
AbstractList	Four-dimensional computer tomography (4D-CT) has been widely used in lung cancer radiotherapy due to its capability in providing important tumor motion information. However, the prolonged scanning duration required by 4D-CT causes considerable increase in radiation dose. To minimize the radiation-related health risk, radiation dose is often reduced at the expense of interslice spatial resolution. However, inadequate resolution in 4D-CT causes artifacts and increases uncertainty in tumor localization, which eventually results in extra damages of healthy tissues during radiotherapy. In this paper, the authors propose a novel postprocessing algorithm to enhance the resolution of lung 4D-CT data. The authors' premise is that anatomical information missing in one phase can be recovered from the complementary information embedded in other phases. The authors employ a patch-based mechanism to propagate information across phases for the reconstruction of intermediate slices in the longitudinal direction, where resolution is normally the lowest. Specifically, the structurally matching and spatially nearby patches are combined for reconstruction of each patch. For greater sensitivity to anatomical details, the authors employ a quad-tree technique to adaptively partition the image for more fine-grained refinement. The authors further devise an iterative strategy for significant enhancement of anatomical details. The authors evaluated their algorithm using a publicly available lung data that consist of 10 4D-CT cases. The authors' algorithm gives very promising results with significantly enhanced image structures and much less artifacts. Quantitative analysis shows that the authors' algorithm increases peak signal-to-noise ratio by 3-4 dB and the structural similarity index by 3%-5% when compared with the standard interpolation-based algorithms. The authors have developed a new algorithm to improve the resolution of 4D-CT. It outperforms the conventional interpolation-based approaches by producing images with the markedly improved structural clarity and greatly reduced artifacts. Purpose: Four-dimensional computer tomography (4D-CT) has been widely used in lung cancer radiotherapy due to its capability in providing important tumor motion information. However, the prolonged scanning duration required by 4D-CT causes considerable increase in radiation dose. To minimize the radiation-related health risk, radiation dose is often reduced at the expense of interslice spatial resolution. However, inadequate resolution in 4D-CT causes artifacts and increases uncertainty in tumor localization, which eventually results in extra damages of healthy tissues during radiotherapy. In this paper, the authors propose a novel postprocessing algorithm to enhance the resolution of lung 4D-CT data. Methods: The authors' premise is that anatomical information missing in one phase can be recovered from the complementary information embedded in other phases. The authors employ a patch-based mechanism to propagate information across phases for the reconstruction of intermediate slices in the longitudinal direction, where resolution is normally the lowest. Specifically, the structurally matching and spatially nearby patches are combined for reconstruction of each patch. For greater sensitivity to anatomical details, the authors employ a quad-tree technique to adaptively partition the image for more fine-grained refinement. The authors further devise an iterative strategy for significant enhancement of anatomical details. Results: The authors evaluated their algorithm using a publicly available lung data that consist of 10 4D-CT cases. The authors’ algorithm gives very promising results with significantly enhanced image structures and much less artifacts. Quantitative analysis shows that the authors’ algorithm increases peak signal-to-noise ratio by 3–4 dB and the structural similarity index by 3%–5% when compared with the standard interpolation-based algorithms. Conclusions: The authors have developed a new algorithm to improve the resolution of 4D-CT. It outperforms the conventional interpolation-based approaches by producing images with the markedly improved structural clarity and greatly reduced artifacts. Four-dimensional computer tomography (4D-CT) has been widely used in lung cancer radiotherapy due to its capability in providing important tumor motion information. However, the prolonged scanning duration required by 4D-CT causes considerable increase in radiation dose. To minimize the radiation-related health risk, radiation dose is often reduced at the expense of interslice spatial resolution. However, inadequate resolution in 4D-CT causes artifacts and increases uncertainty in tumor localization, which eventually results in extra damages of healthy tissues during radiotherapy. In this paper, the authors propose a novel postprocessing algorithm to enhance the resolution of lung 4D-CT data.PURPOSEFour-dimensional computer tomography (4D-CT) has been widely used in lung cancer radiotherapy due to its capability in providing important tumor motion information. However, the prolonged scanning duration required by 4D-CT causes considerable increase in radiation dose. To minimize the radiation-related health risk, radiation dose is often reduced at the expense of interslice spatial resolution. However, inadequate resolution in 4D-CT causes artifacts and increases uncertainty in tumor localization, which eventually results in extra damages of healthy tissues during radiotherapy. In this paper, the authors propose a novel postprocessing algorithm to enhance the resolution of lung 4D-CT data.The authors' premise is that anatomical information missing in one phase can be recovered from the complementary information embedded in other phases. The authors employ a patch-based mechanism to propagate information across phases for the reconstruction of intermediate slices in the longitudinal direction, where resolution is normally the lowest. Specifically, the structurally matching and spatially nearby patches are combined for reconstruction of each patch. For greater sensitivity to anatomical details, the authors employ a quad-tree technique to adaptively partition the image for more fine-grained refinement. The authors further devise an iterative strategy for significant enhancement of anatomical details.METHODSThe authors' premise is that anatomical information missing in one phase can be recovered from the complementary information embedded in other phases. The authors employ a patch-based mechanism to propagate information across phases for the reconstruction of intermediate slices in the longitudinal direction, where resolution is normally the lowest. Specifically, the structurally matching and spatially nearby patches are combined for reconstruction of each patch. For greater sensitivity to anatomical details, the authors employ a quad-tree technique to adaptively partition the image for more fine-grained refinement. The authors further devise an iterative strategy for significant enhancement of anatomical details.The authors evaluated their algorithm using a publicly available lung data that consist of 10 4D-CT cases. The authors' algorithm gives very promising results with significantly enhanced image structures and much less artifacts. Quantitative analysis shows that the authors' algorithm increases peak signal-to-noise ratio by 3-4 dB and the structural similarity index by 3%-5% when compared with the standard interpolation-based algorithms.RESULTSThe authors evaluated their algorithm using a publicly available lung data that consist of 10 4D-CT cases. The authors' algorithm gives very promising results with significantly enhanced image structures and much less artifacts. Quantitative analysis shows that the authors' algorithm increases peak signal-to-noise ratio by 3-4 dB and the structural similarity index by 3%-5% when compared with the standard interpolation-based algorithms.The authors have developed a new algorithm to improve the resolution of 4D-CT. It outperforms the conventional interpolation-based approaches by producing images with the markedly improved structural clarity and greatly reduced artifacts.CONCLUSIONSThe authors have developed a new algorithm to improve the resolution of 4D-CT. It outperforms the conventional interpolation-based approaches by producing images with the markedly improved structural clarity and greatly reduced artifacts. Purpose: Four-dimensional computer tomography (4D-CT) has been widely used in lung cancer radiotherapy due to its capability in providing important tumor motion information. However, the prolonged scanning duration required by 4D-CT causes considerable increase in radiation dose. To minimize the radiation-related health risk, radiation dose is often reduced at the expense of interslice spatial resolution. However, inadequate resolution in 4D-CT causes artifacts and increases uncertainty in tumor localization, which eventually results in extra damages of healthy tissues during radiotherapy. In this paper, the authors propose a novel postprocessing algorithm to enhance the resolution of lung 4D-CT data. Methods: The authors' premise is that anatomical information missing in one phase can be recovered from the complementary information embedded in other phases. The authors employ a patch-based mechanism to propagate information across phases for the reconstruction of intermediate slices in the longitudinal direction, where resolution is normally the lowest. Specifically, the structurally matching and spatially nearby patches are combined for reconstruction of each patch. For greater sensitivity to anatomical details, the authors employ a quad-tree technique to adaptively partition the image for more fine-grained refinement. The authors further devise an iterative strategy for significant enhancement of anatomical details. Results: The authors evaluated their algorithm using a publicly available lung data that consist of 10 4D-CT cases. The authors' algorithm gives very promising results with significantly enhanced image structures and much less artifacts. Quantitative analysis shows that the authors' algorithm increases peak signal-to-noise ratio by 3-4 dB and the structural similarity index by 3%-5% when compared with the standard interpolation-based algorithms. Conclusions: The authors have developed a new algorithm to improve the resolution of 4D-CT. It outperforms the conventional interpolation-based approaches by producing images with the markedly improved structural clarity and greatly reduced artifacts.
Author	Wu, Guorong Yap, Pew-Thian Zhang, Yu Shen, Dinggang Feng, Qianjin Lian, Jun Chen, Wufan
Author_xml	– sequence: 1 givenname: Yu surname: Zhang fullname: Zhang, Yu email: gz.akita.zy@gmail.com organization: School of Biomedical Engineering, Southern Medical University, Guangzhou 510515, China and Department of Radiology and BRIC, University of North Carolina, Chapel Hill, North Carolina 27599 – sequence: 2 givenname: Pew-Thian surname: Yap fullname: Yap, Pew-Thian organization: Department of Radiology and BRIC, University of North Carolina, Chapel Hill, North Carolina 27599 – sequence: 3 givenname: Guorong surname: Wu fullname: Wu, Guorong organization: Department of Radiology and BRIC, University of North Carolina, Chapel Hill, North Carolina 27599 – sequence: 4 givenname: Qianjin surname: Feng fullname: Feng, Qianjin organization: School of Biomedical Engineering, Southern Medical University, Guangzhou 510515, China – sequence: 5 givenname: Jun surname: Lian fullname: Lian, Jun organization: Department of Radiation Oncology, University of North Carolina, Chapel Hill, North Carolina 27599 – sequence: 6 givenname: Wufan surname: Chen fullname: Chen, Wufan email: wufanchen@gmail.com, dinggang_shen@med.unc.edu organization: School of Biomedical Engineering, Southern Medical University, Guangzhou 510515, China – sequence: 7 givenname: Dinggang surname: Shen fullname: Shen, Dinggang email: wufanchen@gmail.com, dinggang_shen@med.unc.edu organization: Department of Radiology and BRIC, University of North Carolina, Chapel Hill, North Carolina 27599 and Department of Brain and Cognitive Engineering, Korea University, Seoul 136-713, Korea
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Snippet	Purpose: Four-dimensional computer tomography (4D-CT) has been widely used in lung cancer radiotherapy due to its capability in providing important tumor... Purpose: Four‐dimensional computer tomography (4D‐CT) has been widely used in lung cancer radiotherapy due to its capability in providing important tumor... Four-dimensional computer tomography (4D-CT) has been widely used in lung cancer radiotherapy due to its capability in providing important tumor motion... Purpose: Four-dimensional computer tomography (4D-CT) has been widely used in lung cancer radiotherapy due to its capability in providing important tumor...
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SubjectTerms	60 APPLIED LIFE SCIENCES ALGORITHMS cancer CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS Computed tomography Computerised tomographs computerised tomography COMPUTERIZED TOMOGRAPHY Digital computing or data processing equipment or methods, specially adapted for specific applications DOSIMETRY Dosimetry/exposure assessment FOUR-DIMENSIONAL CALCULATIONS Four-Dimensional Computed Tomography - methods HEALTH HAZARDS Humans Image data processing or generation, in general Image enhancement IMAGE PROCESSING image reconstruction INTERPOLATION ITERATIVE METHODS lung Lung - diagnostic imaging lung 4D‐CT LUNGS medical image processing Medical image reconstruction Medical imaging nonlocal means Numerical approximation and analysis PEAKS Pneumodyamics, respiration RADIATION DOSES RADIATION PROTECTION AND DOSIMETRY radiation therapy RADIOLOGY AND NUCLEAR MEDICINE RADIOTHERAPY Reconstruction resolution enhancement SENSITIVITY SIGNAL-TO-NOISE RATIO SPATIAL RESOLUTION tumours X‐ray imaging
Title	Resolution enhancement of lung 4D-CT data using multiscale interphase iterative nonlocal means
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