Generative Adversarial Network-Based Image Conversion Among Different Computed Tomography Protocols and Vendors: Effects on Accuracy and Variability in Quantifying Regional Disease Patterns of Interstitial Lung DiseaseGenerative Adversarial Network-Based Image Conversion Among Different Computed Tomography Protocols and Vendors: Effects on Accuracy and Variability in Quantifying Regional Disease Patterns of Interstitial Lung Disease
- Other Titles
- Generative Adversarial Network-Based Image Conversion Among Different Computed Tomography Protocols and Vendors: Effects on Accuracy and Variability in Quantifying Regional Disease Patterns of Interstitial Lung Disease
- Authors
- Hwang, Hye Jeon; Kim, Hyunjong; Seo, Joon Beom; Ye, Jong Chul; Oh, Gyutaek; Lee, Sang Min; Jang, Ryoungwoo; Yun, Jihye; Kim, Namkug; Park, Hee Jun; Lee, Ho Yun; Yoon, Soon Ho; Shin, Kyung Eun; Lee, Jae Wook; Kwon, Woocheol; Sun, Joo Sung; You, Seulgi; Chung, Myung Hee; Gil, Bo Mi; Lim, Jae-Kwang; Lee, Youkyung; Hong, Su Jin; Choi, Yo Won
- Issue Date
- Aug-2023
- Publisher
- 대한영상의학회
- Keywords
- Interstitial lung disease; Computed tomography; Quantification; Artificial intelligence
- Citation
- Korean Journal of Radiology, v.24, no.8, pp 807 - 820
- Pages
- 14
- Indexed
- SCIE
SCOPUS
KCI
- Journal Title
- Korean Journal of Radiology
- Volume
- 24
- Number
- 8
- Start Page
- 807
- End Page
- 820
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/196546
- DOI
- 10.3348/kjr.2023.0088
- ISSN
- 1229-6929
2005-8330
- Abstract
- OBJECTIVE: To assess whether computed tomography (CT) conversion across different scan parameters and manufacturers using a routable generative adversarial network (RouteGAN) can improve the accuracy and variability in quantifying interstitial lung disease (ILD) using a deep learning-based automated software.
MATERIALS AND METHODS: This study included patients with ILD who underwent thin-section CT. Unmatched CT images obtained using scanners from four manufacturers (vendors A-D), standard- or low-radiation doses, and sharp or medium kernels were classified into groups 1-7 according to acquisition conditions. CT images in groups 2-7 were converted into the target CT style (Group 1: vendor A, standard dose, and sharp kernel) using a RouteGAN. ILD was quantified on original and converted CT images using a deep learning-based software (Aview, Coreline Soft). The accuracy of quantification was analyzed using the dice similarity coefficient (DSC) and pixel-wise overlap accuracy metrics against manual quantification by a radiologist. Five radiologists evaluated quantification accuracy using a 10-point visual scoring system.
RESULTS: Three hundred and fifty CT slices from 150 patients (mean age: 67.6 ± 10.7 years; 56 females) were included. The overlap accuracies for quantifying total abnormalities in groups 2-7 improved after CT conversion (original vs. converted: 0.63 vs. 0.68 for DSC, 0.66 vs. 0.70 for pixel-wise recall, and 0.68 vs. 0.73 for pixel-wise precision; P < 0.002 for all). The DSCs of fibrosis score, honeycombing, and reticulation significantly increased after CT conversion (0.32 vs. 0.64, 0.19 vs. 0.47, and 0.23 vs. 0.54, P < 0.002 for all), whereas those of ground-glass opacity, consolidation, and emphysema did not change significantly or decreased slightly. The radiologists' scores were significantly higher (P < 0.001) and less variable on converted CT.
CONCLUSION: CT conversion using a RouteGAN can improve the accuracy and variability of CT images obtained using different scan parameters and manufacturers in deep learning-based quantification of ILD.
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