Einzeltreffer — DigiBib

Objective: To develop high-quality synthetic CT (sCT) generation method from low-dose cone-beam CT (CBCT) images by using attention-guided generative adversarial networks (AGGAN) and apply these images to dose calculations in radiotherapy.

Methods: The CBCT/planning CT images of 170 patients undergoing thoracic radiotherapy were used for training and testing. The CBCT images were scanned under a fast protocol with 50% less clinical projection frames compared with standard chest M20 protocol. Training with aligned paired images was performed using conditional adversarial networks (so-called pix2pix), and training with unpaired images was carried out with cycle-consistent adversarial networks (cycleGAN) and AGGAN, through which sCT images were generated. The image quality and Hounsfield unit (HU) value of the sCT images generated by the three neural networks were compared. The treatment plan was designed on CT and copied to sCT images to calculated dose distribution.

Results: The image quality of sCT images by all the three methods are significantly improved compared with original CBCT images. The AGGAN achieves the best image quality in the testing patients with the smallest mean absolute error (MAE, 43.5 ± 6.69), largest structural similarity (SSIM, 93.7 ± 3.88) and peak signal-to-noise ratio (PSNR, 29.5 ± 2.36). The sCT images generated by all the three methods showed superior dose calculation accuracy with higher gamma passing rates compared with original CBCT image. The AGGAN offered the highest gamma passing rates (91.4 ± 3.26) under the strictest criteria of 1 mm/1% compared with other methods. In the phantom study, the sCT images generated by AGGAN demonstrated the best image quality and the highest dose calculation accuracy.

Conclusions: High-quality sCT images were generated from low-dose thoracic CBCT images by using the proposed AGGAN through unpaired CBCT and CT images. The dose distribution could be calculated accurately based on sCT images in radiotherapy.

Titel:	Generating synthetic CT from low-dose cone-beam CT by using generative adversarial networks for adaptive radiotherapy.
Autor/in / Beteiligte Person:	Gao, L ; Xie, K ; Wu, X ; Lu, Z ; Li, C ; Sun, J ; Lin, T ; Sui, J ; Ni, X
Link:	Zum Volltext
Zeitschrift:	Radiation oncology (London, England), Jg. 16 (2021-10-14), Heft 1, S. 202
Veröffentlichung:	[London] : BioMed Central, 2006-, 2021
Medientyp:	academicJournal
ISSN:	1748-717X (electronic)
DOI:	10.1186/s13014-021-01928-w
Schlagwort:	Bone Neoplasms diagnostic imaging Bone Neoplasms radiotherapy Cone-Beam Computed Tomography methods Deep Learning Humans Image Processing, Computer-Assisted methods Lung Neoplasms diagnostic imaging Lung Neoplasms radiotherapy Organs at Risk radiation effects Prognosis Radiotherapy Dosage Soft Tissue Neoplasms diagnostic imaging Soft Tissue Neoplasms radiotherapy Tomography, X-Ray Computed methods Bone Neoplasms pathology Lung Neoplasms pathology Neural Networks, Computer Phantoms, Imaging Radiotherapy Planning, Computer-Assisted methods Radiotherapy, Intensity-Modulated methods Soft Tissue Neoplasms pathology
Sonstiges:	Nachgewiesen in: MEDLINE Sprachen: English Publication Type: Journal Article Language: English [Radiat Oncol] 2021 Oct 14; Vol. 16 (1), pp. 202. <i>Date of Electronic Publication: </i>2021 Oct 14. MeSH Terms: Neural Networks, Computer* ; Phantoms, Imaging* ; Bone Neoplasms / pathology ; Lung Neoplasms / pathology ; Radiotherapy Planning, Computer-Assisted / methods ; Radiotherapy, Intensity-Modulated / methods ; Soft Tissue Neoplasms / *pathology ; Bone Neoplasms / diagnostic imaging ; Bone Neoplasms / radiotherapy ; Cone-Beam Computed Tomography / methods ; Deep Learning ; Humans ; Image Processing, Computer-Assisted / methods ; Lung Neoplasms / diagnostic imaging ; Lung Neoplasms / radiotherapy ; Organs at Risk / radiation effects ; Prognosis ; Radiotherapy Dosage ; Soft Tissue Neoplasms / diagnostic imaging ; Soft Tissue Neoplasms / radiotherapy ; Tomography, X-Ray Computed / methods References: Phys Med Biol. 2018 Sep 10;63(18):185001. (PMID: 30109989) ; Med Phys. 2020 Jun;47(6):2472-2483. (PMID: 32141618) ; Phys Med Biol. 2015 May 7;60(9):3567-87. (PMID: 25860299) ; Med Phys. 2019 Sep;46(9):3998-4009. (PMID: 31206709) ; Strahlenther Onkol. 2011 May;187(5):284-91. (PMID: 21533757) ; IEEE Trans Med Imaging. 2018 Jun;37(6):1488-1497. (PMID: 29870376) ; Phys Med Biol. 2010 Nov 21;55(22):6695-720. (PMID: 21030750) ; Med Phys. 2001 Apr;28(4):469-74. (PMID: 11339743) ; Med Phys. 2016 Oct;43(10):5635. (PMID: 27782706) ; Cancer Radiother. 2006 Sep;10(5):252-7. (PMID: 16884940) ; Med Image Comput Comput Assist Interv. 2017 Sep;10435:417-425. (PMID: 30009283) ; Phys Med Biol. 2019 Jul 16;64(14):145010. (PMID: 31170699) ; Radiother Oncol. 2020 Dec;153:205-212. (PMID: 33075394) ; Phys Med Biol. 2020 Apr 28;65(9):095002. (PMID: 32143207) ; Phys Med Biol. 2020 Jun 24;:. (PMID: 32580174) ; J Appl Clin Med Phys. 2013 Nov 04;14(6):4346. (PMID: 24257276) ; Med Phys. 2017 Oct;44(10):e339-e352. (PMID: 29027235) ; Med Phys. 2017 Sep;44(9):4437-4451. (PMID: 28556204) ; Med Phys. 2015 Aug;42(8):4449-59. (PMID: 26233175) ; Br J Radiol. 2019 Apr;92(1096):20180383. (PMID: 30433821) ; Radiat Oncol. 2020 Aug 12;15(1):192. (PMID: 32787941) ; Strahlenther Onkol. 2015 Dec;191(12):970-8. (PMID: 26403913) ; Med Phys. 2020 Mar;47(3):1115-1125. (PMID: 31853974) ; Phys Med Biol. 2019 Jan 24;64(3):035011. (PMID: 30523998) ; Med Phys. 2018 Nov;45(11):4916-4926. (PMID: 30199101) ; Med Phys. 2010 Oct;37(10):5395-406. (PMID: 21089775) ; Med Phys. 2020 Mar;47(3):998-1010. (PMID: 31840269) ; Phys Med Biol. 2019 Jun 10;64(12):125002. (PMID: 31108465) ; Med Phys. 2020 Oct;47(10):4683-4693. (PMID: 32654160) ; Med Phys. 2013 May;40(5):051915. (PMID: 23635285) ; J Contemp Brachytherapy. 2016 Apr;8(2):122-7. (PMID: 27257416) ; Med Phys. 2020 Nov;47(11):5632-5647. (PMID: 32949051) ; Int J Radiat Oncol Biol Phys. 2008 Jan 1;70(1):272-9. (PMID: 17980510) ; Phys Med. 2017 Jan;33:68-76. (PMID: 27998666) Grant Information: M2020006 General Program of Jiangsu Provincial Health Commission; CM20193005 Changzhou Key Laboratory of Medical Physics; CJ20200099 Changzhou Science and Technology Bureau; CZQM2020075 Young Talent Development Plan of Changzhou Health Commission; CZQM2020067 Young Talent Development Plan of Changzhou Health Commission; QN201932 Science and Technology Programs for Young Talents of Changzhou Health Commission Contributed Indexing: Keywords: Adaptive radiotherapy; Attention-guided GAN; Low-dose CBCT; Synthetic CT; Unpaired Entry Date(s): Date Created: 20211015 Date Completed: 20220207 Latest Revision: 20220207 Update Code: 20240513 PubMed Central ID: PMC8515667

Klicken Sie ein Format an und speichern Sie dann die Daten oder geben Sie eine Empfänger-Adresse ein und lassen Sie sich per Email zusenden.

BibTeX Citavi, JabRef, u.a.
(Literaturverwaltung)

PDF kein Volltext!
(Merkzettel, Notizen)

RIS Endnote, Citavi u.a.
(Literaturverwaltung)

MODS
(XML zur Weiterverarbeitung)

oder

Wählen Sie das für Sie passende Zitationsformat und kopieren Sie es dann in die Zwischenablage, lassen es sich per Mail zusenden oder speichern es als PDF-Datei.

Gewünschter Zitations-Stil:

oder

Bitte prüfen Sie, ob die Zitation formal korrekt ist, bevor Sie sie in einer Arbeit verwenden. Benutzen Sie gegebenenfalls den "Exportieren"-Dialog, wenn Sie ein Literaturverwaltungsprogramm verwenden und die Zitat-Angaben selbst formatieren wollen.

Generating synthetic CT from low-dose cone-beam CT by using generative adversarial networks for adaptive radiotherapy.