Large-scale pretrained frame generative model enables real-time low-dose DSA imaging: An AI system development and multi-center validation study

Huangxuan Zhao; Ziyang Xu; Lei Chen; Linxia Wu; Ziwei Cui; Jinqiang Ma; Tao Sun; Yu Lei; Nan Wang; Hongyao Hu; Yiqing Tan; Wei Lu; Wenzhong Yang; Kaibing Liao; Gaojun Teng; Xiaoyun Liang; Yi Li; Congcong Feng; Tong Nie; Xiaoyu Han; Dongqiao Xiang; Charles B.L.M. Majoie; Wim H. van Zwam; Aad van der Lugt; P. Matthijs van der Sluijs; Theo van Walsum; Yun Feng; Guoli Liu; Yan Huang; Wenyu Liu; Xuefeng Kan; Ruisheng Su; Weihua Zhang; Xinggang Wang; Chuansheng Zheng

doi:10.1016/j.medj.2024.07.025

Large-scale pretrained frame generative model enables real-time low-dose DSA imaging: An AI system development and multi-center validation study

Huangxuan Zhao^*, Ziyang Xu, Lei Chen, Linxia Wu, Ziwei Cui, Jinqiang Ma, Tao Sun, Yu Lei, Nan Wang, Hongyao Hu, Yiqing Tan, Wei Lu, Wenzhong Yang, Kaibing Liao, Gaojun Teng, Xiaoyun Liang, Yi Li, Congcong Feng, Tong Nie, Xiaoyu HanDongqiao Xiang, Charles B.L.M. Majoie, Wim H. van Zwam, Aad van der Lugt, P. Matthijs van der Sluijs, Theo van Walsum, Yun Feng, Guoli Liu, Yan Huang, Wenyu Liu, Xuefeng Kan^*, Ruisheng Su^*, Weihua Zhang^*, Xinggang Wang, Chuansheng Zheng

^*Corresponding author for this work

Radiology & Nuclear Medicine

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

1 Citation (Scopus)

Abstract

Background: Digital subtraction angiography (DSA) devices are commonly used in numerous interventional procedures across various parts of the body, necessitating multiple scans per procedure, which results in significant radiation exposure for both doctors and patients. Inspired by generative artificial intelligence techniques, this study proposes GenDSA, a large-scale pretrained multi-frame generative model-based real-time and low-dose DSA imaging system. Methods: GenDSA was developed to generate 1-, 2-, and 3-frame sequences following each real frame. A large-scale dataset comprising ∼3 million DSA images from 27,117 patients across 10 hospitals was constructed to pretrain, fine-tune, and validate GenDSA. Two other datasets from 25 hospitals were used for evaluation. Objective evaluations included SSIM and PSNR. Five interventional radiologists independently assessed the quality of the generated frames using the Likert scale and visual Turing test. Scoring consistency among the radiologists was measured using the Kendall coefficient of concordance (W). The Fleiss’ kappa values were used for inter-rater agreement analysis for visual Turing tests. Findings: Using only one-third of the clinical radiation dose, videos generated by GenDSA were perfectly consistent with real videos. Objective evaluations demonstrated that GenDSA's performance (PSNR = 36.83, SSIM = 0.911, generation time = 0.07 s/frame) surpassed state-of-the-art algorithms. Subjective ratings and statistical results from five doctors indicated no significant difference between real and generated videos. Furthermore, the generated videos were comparable to real videos in overall quality (4.905 vs. 4.935) and lesion assessment (4.825 vs. 4.860). Conclusions: With clear clinical and translational values, the developed GenDSA can significantly reduce radiation damage to both doctors and patients during DSA-guided procedures. Funding: This study was supported by the National Key R&D Program and the National Natural Science Foundation of China.

Original language	English
Article number	100497
Journal	Med
Volume	6
Issue number	1
Early online date	19 Aug 2024
DOIs	https://doi.org/10.1016/j.medj.2024.07.025
Publication status	Published - 10 Jan 2025

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Zhao, H., Xu, Z., Chen, L., Wu, L., Cui, Z., Ma, J., Sun, T., Lei, Y., Wang, N., Hu, H., Tan, Y., Lu, W., Yang, W., Liao, K., Teng, G., Liang, X., Li, Y., Feng, C., Nie, T., ... Zheng, C. (2025). Large-scale pretrained frame generative model enables real-time low-dose DSA imaging: An AI system development and multi-center validation study. Med, 6(1), Article 100497. https://doi.org/10.1016/j.medj.2024.07.025

@article{b1170889290349379ff65d8fb3a48b3b,

title = "Large-scale pretrained frame generative model enables real-time low-dose DSA imaging: An AI system development and multi-center validation study",

abstract = "Background: Digital subtraction angiography (DSA) devices are commonly used in numerous interventional procedures across various parts of the body, necessitating multiple scans per procedure, which results in significant radiation exposure for both doctors and patients. Inspired by generative artificial intelligence techniques, this study proposes GenDSA, a large-scale pretrained multi-frame generative model-based real-time and low-dose DSA imaging system. Methods: GenDSA was developed to generate 1-, 2-, and 3-frame sequences following each real frame. A large-scale dataset comprising ∼3 million DSA images from 27,117 patients across 10 hospitals was constructed to pretrain, fine-tune, and validate GenDSA. Two other datasets from 25 hospitals were used for evaluation. Objective evaluations included SSIM and PSNR. Five interventional radiologists independently assessed the quality of the generated frames using the Likert scale and visual Turing test. Scoring consistency among the radiologists was measured using the Kendall coefficient of concordance (W). The Fleiss{\textquoteright} kappa values were used for inter-rater agreement analysis for visual Turing tests. Findings: Using only one-third of the clinical radiation dose, videos generated by GenDSA were perfectly consistent with real videos. Objective evaluations demonstrated that GenDSA's performance (PSNR = 36.83, SSIM = 0.911, generation time = 0.07 s/frame) surpassed state-of-the-art algorithms. Subjective ratings and statistical results from five doctors indicated no significant difference between real and generated videos. Furthermore, the generated videos were comparable to real videos in overall quality (4.905 vs. 4.935) and lesion assessment (4.825 vs. 4.860). Conclusions: With clear clinical and translational values, the developed GenDSA can significantly reduce radiation damage to both doctors and patients during DSA-guided procedures. Funding: This study was supported by the National Key R&D Program and the National Natural Science Foundation of China.",

author = "Huangxuan Zhao and Ziyang Xu and Lei Chen and Linxia Wu and Ziwei Cui and Jinqiang Ma and Tao Sun and Yu Lei and Nan Wang and Hongyao Hu and Yiqing Tan and Wei Lu and Wenzhong Yang and Kaibing Liao and Gaojun Teng and Xiaoyun Liang and Yi Li and Congcong Feng and Tong Nie and Xiaoyu Han and Dongqiao Xiang and Majoie, {Charles B.L.M.} and {van Zwam}, {Wim H.} and {van der Lugt}, Aad and {van der Sluijs}, {P. Matthijs} and {van Walsum}, Theo and Yun Feng and Guoli Liu and Yan Huang and Wenyu Liu and Xuefeng Kan and Ruisheng Su and Weihua Zhang and Xinggang Wang and Chuansheng Zheng",

note = "Publisher Copyright: {\textcopyright} 2024 Elsevier Inc.",

year = "2025",

month = jan,

day = "10",

doi = "10.1016/j.medj.2024.07.025",

language = "English",

volume = "6",

journal = "Med",

issn = "2666-6359",

publisher = "Cell Press",

number = "1",

}

Zhao, H, Xu, Z, Chen, L, Wu, L, Cui, Z, Ma, J, Sun, T, Lei, Y, Wang, N, Hu, H, Tan, Y, Lu, W, Yang, W, Liao, K, Teng, G, Liang, X, Li, Y, Feng, C, Nie, T, Han, X, Xiang, D, Majoie, CBLM, van Zwam, WH, van der Lugt, A , van der Sluijs, PM , van Walsum, T, Feng, Y, Liu, G, Huang, Y, Liu, W, Kan, X, Su, R, Zhang, W, Wang, X & Zheng, C 2025, 'Large-scale pretrained frame generative model enables real-time low-dose DSA imaging: An AI system development and multi-center validation study', Med, vol. 6, no. 1, 100497. https://doi.org/10.1016/j.medj.2024.07.025

TY - JOUR

T1 - Large-scale pretrained frame generative model enables real-time low-dose DSA imaging

T2 - An AI system development and multi-center validation study

AU - Zhao, Huangxuan

AU - Xu, Ziyang

AU - Chen, Lei

AU - Wu, Linxia

AU - Cui, Ziwei

AU - Ma, Jinqiang

AU - Sun, Tao

AU - Lei, Yu

AU - Wang, Nan

AU - Hu, Hongyao

AU - Tan, Yiqing

AU - Lu, Wei

AU - Yang, Wenzhong

AU - Liao, Kaibing

AU - Teng, Gaojun

AU - Liang, Xiaoyun

AU - Li, Yi

AU - Feng, Congcong

AU - Nie, Tong

AU - Han, Xiaoyu

AU - Xiang, Dongqiao

AU - Majoie, Charles B.L.M.

AU - van Zwam, Wim H.

AU - van der Lugt, Aad

AU - van der Sluijs, P. Matthijs

AU - van Walsum, Theo

AU - Feng, Yun

AU - Liu, Guoli

AU - Huang, Yan

AU - Liu, Wenyu

AU - Kan, Xuefeng

AU - Su, Ruisheng

AU - Zhang, Weihua

AU - Wang, Xinggang

AU - Zheng, Chuansheng

PY - 2025/1/10

Y1 - 2025/1/10

N2 - Background: Digital subtraction angiography (DSA) devices are commonly used in numerous interventional procedures across various parts of the body, necessitating multiple scans per procedure, which results in significant radiation exposure for both doctors and patients. Inspired by generative artificial intelligence techniques, this study proposes GenDSA, a large-scale pretrained multi-frame generative model-based real-time and low-dose DSA imaging system. Methods: GenDSA was developed to generate 1-, 2-, and 3-frame sequences following each real frame. A large-scale dataset comprising ∼3 million DSA images from 27,117 patients across 10 hospitals was constructed to pretrain, fine-tune, and validate GenDSA. Two other datasets from 25 hospitals were used for evaluation. Objective evaluations included SSIM and PSNR. Five interventional radiologists independently assessed the quality of the generated frames using the Likert scale and visual Turing test. Scoring consistency among the radiologists was measured using the Kendall coefficient of concordance (W). The Fleiss’ kappa values were used for inter-rater agreement analysis for visual Turing tests. Findings: Using only one-third of the clinical radiation dose, videos generated by GenDSA were perfectly consistent with real videos. Objective evaluations demonstrated that GenDSA's performance (PSNR = 36.83, SSIM = 0.911, generation time = 0.07 s/frame) surpassed state-of-the-art algorithms. Subjective ratings and statistical results from five doctors indicated no significant difference between real and generated videos. Furthermore, the generated videos were comparable to real videos in overall quality (4.905 vs. 4.935) and lesion assessment (4.825 vs. 4.860). Conclusions: With clear clinical and translational values, the developed GenDSA can significantly reduce radiation damage to both doctors and patients during DSA-guided procedures. Funding: This study was supported by the National Key R&D Program and the National Natural Science Foundation of China.

AB - Background: Digital subtraction angiography (DSA) devices are commonly used in numerous interventional procedures across various parts of the body, necessitating multiple scans per procedure, which results in significant radiation exposure for both doctors and patients. Inspired by generative artificial intelligence techniques, this study proposes GenDSA, a large-scale pretrained multi-frame generative model-based real-time and low-dose DSA imaging system. Methods: GenDSA was developed to generate 1-, 2-, and 3-frame sequences following each real frame. A large-scale dataset comprising ∼3 million DSA images from 27,117 patients across 10 hospitals was constructed to pretrain, fine-tune, and validate GenDSA. Two other datasets from 25 hospitals were used for evaluation. Objective evaluations included SSIM and PSNR. Five interventional radiologists independently assessed the quality of the generated frames using the Likert scale and visual Turing test. Scoring consistency among the radiologists was measured using the Kendall coefficient of concordance (W). The Fleiss’ kappa values were used for inter-rater agreement analysis for visual Turing tests. Findings: Using only one-third of the clinical radiation dose, videos generated by GenDSA were perfectly consistent with real videos. Objective evaluations demonstrated that GenDSA's performance (PSNR = 36.83, SSIM = 0.911, generation time = 0.07 s/frame) surpassed state-of-the-art algorithms. Subjective ratings and statistical results from five doctors indicated no significant difference between real and generated videos. Furthermore, the generated videos were comparable to real videos in overall quality (4.905 vs. 4.935) and lesion assessment (4.825 vs. 4.860). Conclusions: With clear clinical and translational values, the developed GenDSA can significantly reduce radiation damage to both doctors and patients during DSA-guided procedures. Funding: This study was supported by the National Key R&D Program and the National Natural Science Foundation of China.

UR - http://www.scopus.com/inward/record.url?scp=85203408119&partnerID=8YFLogxK

U2 - 10.1016/j.medj.2024.07.025

DO - 10.1016/j.medj.2024.07.025

M3 - Article

C2 - 39163857

AN - SCOPUS:85203408119

SN - 2666-6359

VL - 6

JO - Med

JF - Med

IS - 1

M1 - 100497

ER -

Large-scale pretrained frame generative model enables real-time low-dose DSA imaging: An AI system development and multi-center validation study

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