Toward Modality- and Sampling-Universal Learning Strategies for Accelerating Cardiovascular Imaging: Summary of the CMRxRecon2024 Challenge

Fanwen Wang; Zi Wang; Yan Li; Jun Lyu; Chen Qin; Shuo Wang; Kunyuan Guo; Mengting Sun; Mingkai Huang; Haoyu Zhang; Michael Tanzer; Qirong Li; Xinran Chen; Jiahao Huang; Yinzhe Wu; Haosen Zhang; Kian Anvari Hamedani; Yuntong Lyu; Longyu Sun; Qing Li; Tianxing He; Lizhen Lan; Qiong Yao; Ziqiang Xu; Bingyu Xin; Dimitris N. Metaxas; Narges Razizadeh; Shahabedin Nabavi; George Yiasemis; Jonas Teuwen; Zhenxi Zhang; Sha Wang; Chi Zhang; Daniel B. Ennis; Zhihao Xue; Chenxi Hu; Ruru Xu; Ilkay Oksuz; Donghang Lyu; Yanxin Huang; Xinrui Guo; Ruqian Hao; Jaykumar H. Patel; Guanke Cai; Binghua Chen; Yajing Zhang; Sha Hua; Zhensen Chen; Qi Dou; Xiahai Zhuang; Qian Tao; Wenjia Bai; Jing Qin; He Wang; Claudia Prieto; Michael Markl; Alistair Young; Hao Li; Xihong Hu; Lianming Wu; Xiaobo Qu; Guang Yang; Chengyan Wang

doi:10.1109/TMI.2025.3641610

Toward Modality- and Sampling-Universal Learning Strategies for Accelerating Cardiovascular Imaging: Summary of the CMRxRecon2024 Challenge

Fanwen Wang
, Zi Wang
, Yan Li
, Jun Lyu
, Chen Qin
, Shuo Wang
, Kunyuan Guo
, Mengting Sun
, Mingkai Huang
, Haoyu Zhang
, Michael Tanzer
, Qirong Li
, Xinran Chen
, Jiahao Huang
, Yinzhe Wu
, Haosen Zhang
, Kian Anvari Hamedani
, Yuntong Lyu
, Longyu Sun
, Qing Li

Tianxing He, Lizhen Lan, Qiong Yao, Ziqiang Xu, Bingyu Xin, Dimitris N. Metaxas, Narges Razizadeh, Shahabedin Nabavi, George Yiasemis, Jonas Teuwen, Zhenxi Zhang, Sha Wang, Chi Zhang, Daniel B. Ennis, Zhihao Xue, Chenxi Hu, Ruru Xu, Ilkay Oksuz, Donghang Lyu, Yanxin Huang, Xinrui Guo, Ruqian Hao, Jaykumar H. Patel, Guanke Cai, Binghua Chen, Yajing Zhang, Sha Hua, Zhensen Chen, Qi Dou, Xiahai Zhuang, Qian Tao, Wenjia Bai, Jing Qin, He Wang, Claudia Prieto, Michael Markl, Alistair Young, Hao Li, Xihong Hu^*, Lianming Wu^*, Xiaobo Qu^*, Guang Yang^*, Chengyan Wang^*

^*Corresponding author for this work

Department of Computer Engineering

Fudan University
Imperial College London
Royal Brompton and Harefield NHS Foundation Trust
Shanghai Jiao Tong University
Yantai University
Xiamen University
Shahid Beheshti University
Shanghai Fuying Medical Technology Company Ltd.
Rutgers - The State University of New Jersey, New Brunswick
Netherlands Cancer Institute
Canon Medical Systems (China) Company Ltd.
Stanford University
Istanbul Technical University
Leiden University
University of Electronic Science and Technology of China
Huazhong University of Science and Technology
Sunnybrook Research
University of Toronto
GE Healthcare
Chinese University of Hong Kong
Delft University of Technology
Hong Kong Polytechnic University
King's College London
Pontificia Universidad Católica de Chile
Northwestern University

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

1 Citation (Scopus)

Abstract

Cardiovascular health is vital to human well-being, and cardiac magnetic resonance (CMR) imaging is considered the clinical reference standard for diagnosing cardiovascular disease. However, its adoption is hindered by long scan times, complex contrasts, and inconsistent quality. While deep learning methods perform well on specific CMR imaging sequences, they often fail to generalize across modalities and sampling schemes. The lack of benchmarks for high-quality, fast CMR image reconstruction further limits technology comparison and adoption. The CMRxRecon2024 challenge, attracting over 200 teams from 18 countries, addressed these issues with two tasks: generalization to unseen modalities and robustness to diverse undersampling patterns. We introduced the largest public multi-modality CMR raw dataset, an open benchmarking platform, and shared code. Analysis of the best-performing solutions revealed that prompt-based adaptation and enhanced physics-driven consistency enabled strong cross-scenario performance. These findings establish principles for generalizable reconstruction models and advance clinically translatable AI in cardiovascular imaging.

Original language	English
Pages (from-to)	1872-1887
Number of pages	16
Journal	IEEE Transactions on Medical Imaging
Volume	45
Issue number	5
DOIs	https://doi.org/10.1109/TMI.2025.3641610
Publication status	Published - 1 May 2026

Bibliographical note

Publisher Copyright:
© 1982-2012 IEEE.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

Cardiovascular imaging
image reconstruction
magnetic resonance imaging
prompt learning
universal models

Access to Document

10.1109/TMI.2025.3641610

Cite this

Wang, F., Wang, Z., Li, Y., Lyu, J., Qin, C., Wang, S., Guo, K., Sun, M., Huang, M., Zhang, H., Tanzer, M., Li, Q., Chen, X., Huang, J., Wu, Y., Zhang, H., Anvari Hamedani, K., Lyu, Y., Sun, L., ... Wang, C. (2026). Toward Modality- and Sampling-Universal Learning Strategies for Accelerating Cardiovascular Imaging: Summary of the CMRxRecon2024 Challenge. IEEE Transactions on Medical Imaging, 45(5), 1872-1887. https://doi.org/10.1109/TMI.2025.3641610

@article{5d042d8ad6c645e197b005cd6a85cadd,

title = "Toward Modality- and Sampling-Universal Learning Strategies for Accelerating Cardiovascular Imaging: Summary of the CMRxRecon2024 Challenge",

abstract = "Cardiovascular health is vital to human well-being, and cardiac magnetic resonance (CMR) imaging is considered the clinical reference standard for diagnosing cardiovascular disease. However, its adoption is hindered by long scan times, complex contrasts, and inconsistent quality. While deep learning methods perform well on specific CMR imaging sequences, they often fail to generalize across modalities and sampling schemes. The lack of benchmarks for high-quality, fast CMR image reconstruction further limits technology comparison and adoption. The CMRxRecon2024 challenge, attracting over 200 teams from 18 countries, addressed these issues with two tasks: generalization to unseen modalities and robustness to diverse undersampling patterns. We introduced the largest public multi-modality CMR raw dataset, an open benchmarking platform, and shared code. Analysis of the best-performing solutions revealed that prompt-based adaptation and enhanced physics-driven consistency enabled strong cross-scenario performance. These findings establish principles for generalizable reconstruction models and advance clinically translatable AI in cardiovascular imaging.",

keywords = "Cardiovascular imaging, image reconstruction, magnetic resonance imaging, prompt learning, universal models",

author = "Fanwen Wang and Zi Wang and Yan Li and Jun Lyu and Chen Qin and Shuo Wang and Kunyuan Guo and Mengting Sun and Mingkai Huang and Haoyu Zhang and Michael Tanzer and Qirong Li and Xinran Chen and Jiahao Huang and Yinzhe Wu and Haosen Zhang and \{Anvari Hamedani\}, Kian and Yuntong Lyu and Longyu Sun and Qing Li and Tianxing He and Lizhen Lan and Qiong Yao and Ziqiang Xu and Bingyu Xin and Metaxas, \{Dimitris N.\} and Narges Razizadeh and Shahabedin Nabavi and George Yiasemis and Jonas Teuwen and Zhenxi Zhang and Sha Wang and Chi Zhang and Ennis, \{Daniel B.\} and Zhihao Xue and Chenxi Hu and Ruru Xu and Ilkay Oksuz and Donghang Lyu and Yanxin Huang and Xinrui Guo and Ruqian Hao and Patel, \{Jaykumar H.\} and Guanke Cai and Binghua Chen and Yajing Zhang and Sha Hua and Zhensen Chen and Qi Dou and Xiahai Zhuang and Qian Tao and Wenjia Bai and Jing Qin and He Wang and Claudia Prieto and Michael Markl and Alistair Young and Hao Li and Xihong Hu and Lianming Wu and Xiaobo Qu and Guang Yang and Chengyan Wang",

note = "Publisher Copyright: {\textcopyright} 1982-2012 IEEE.",

year = "2026",

month = may,

day = "1",

doi = "10.1109/TMI.2025.3641610",

language = "English",

volume = "45",

pages = "1872--1887",

journal = "IEEE Transactions on Medical Imaging",

issn = "0278-0062",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

number = "5",

}

Wang, F, Wang, Z, Li, Y, Lyu, J, Qin, C, Wang, S, Guo, K, Sun, M, Huang, M, Zhang, H, Tanzer, M, Li, Q, Chen, X, Huang, J, Wu, Y, Zhang, H, Anvari Hamedani, K, Lyu, Y, Sun, L, Li, Q, He, T, Lan, L, Yao, Q, Xu, Z, Xin, B, Metaxas, DN, Razizadeh, N, Nabavi, S, Yiasemis, G, Teuwen, J, Zhang, Z, Wang, S, Zhang, C, Ennis, DB, Xue, Z, Hu, C, Xu, R, Oksuz, I, Lyu, D, Huang, Y, Guo, X, Hao, R, Patel, JH, Cai, G, Chen, B, Zhang, Y, Hua, S, Chen, Z, Dou, Q, Zhuang, X, Tao, Q, Bai, W, Qin, J, Wang, H, Prieto, C, Markl, M, Young, A, Li, H, Hu, X, Wu, L, Qu, X, Yang, G & Wang, C 2026, 'Toward Modality- and Sampling-Universal Learning Strategies for Accelerating Cardiovascular Imaging: Summary of the CMRxRecon2024 Challenge', IEEE Transactions on Medical Imaging, vol. 45, no. 5, pp. 1872-1887. https://doi.org/10.1109/TMI.2025.3641610

TY - JOUR

T1 - Toward Modality- and Sampling-Universal Learning Strategies for Accelerating Cardiovascular Imaging

T2 - Summary of the CMRxRecon2024 Challenge

AU - Wang, Fanwen

AU - Wang, Zi

AU - Li, Yan

AU - Lyu, Jun

AU - Qin, Chen

AU - Wang, Shuo

AU - Guo, Kunyuan

AU - Sun, Mengting

AU - Huang, Mingkai

AU - Zhang, Haoyu

AU - Tanzer, Michael

AU - Li, Qirong

AU - Chen, Xinran

AU - Huang, Jiahao

AU - Wu, Yinzhe

AU - Zhang, Haosen

AU - Anvari Hamedani, Kian

AU - Lyu, Yuntong

AU - Sun, Longyu

AU - Li, Qing

AU - He, Tianxing

AU - Lan, Lizhen

AU - Yao, Qiong

AU - Xu, Ziqiang

AU - Xin, Bingyu

AU - Metaxas, Dimitris N.

AU - Razizadeh, Narges

AU - Nabavi, Shahabedin

AU - Yiasemis, George

AU - Teuwen, Jonas

AU - Zhang, Zhenxi

AU - Wang, Sha

AU - Zhang, Chi

AU - Ennis, Daniel B.

AU - Xue, Zhihao

AU - Hu, Chenxi

AU - Xu, Ruru

AU - Oksuz, Ilkay

AU - Lyu, Donghang

AU - Huang, Yanxin

AU - Guo, Xinrui

AU - Hao, Ruqian

AU - Patel, Jaykumar H.

AU - Cai, Guanke

AU - Chen, Binghua

AU - Zhang, Yajing

AU - Hua, Sha

AU - Chen, Zhensen

AU - Dou, Qi

AU - Zhuang, Xiahai

AU - Tao, Qian

AU - Bai, Wenjia

AU - Qin, Jing

AU - Wang, He

AU - Prieto, Claudia

AU - Markl, Michael

AU - Young, Alistair

AU - Li, Hao

AU - Hu, Xihong

AU - Wu, Lianming

AU - Qu, Xiaobo

AU - Yang, Guang

AU - Wang, Chengyan

PY - 2026/5/1

Y1 - 2026/5/1

N2 - Cardiovascular health is vital to human well-being, and cardiac magnetic resonance (CMR) imaging is considered the clinical reference standard for diagnosing cardiovascular disease. However, its adoption is hindered by long scan times, complex contrasts, and inconsistent quality. While deep learning methods perform well on specific CMR imaging sequences, they often fail to generalize across modalities and sampling schemes. The lack of benchmarks for high-quality, fast CMR image reconstruction further limits technology comparison and adoption. The CMRxRecon2024 challenge, attracting over 200 teams from 18 countries, addressed these issues with two tasks: generalization to unseen modalities and robustness to diverse undersampling patterns. We introduced the largest public multi-modality CMR raw dataset, an open benchmarking platform, and shared code. Analysis of the best-performing solutions revealed that prompt-based adaptation and enhanced physics-driven consistency enabled strong cross-scenario performance. These findings establish principles for generalizable reconstruction models and advance clinically translatable AI in cardiovascular imaging.

AB - Cardiovascular health is vital to human well-being, and cardiac magnetic resonance (CMR) imaging is considered the clinical reference standard for diagnosing cardiovascular disease. However, its adoption is hindered by long scan times, complex contrasts, and inconsistent quality. While deep learning methods perform well on specific CMR imaging sequences, they often fail to generalize across modalities and sampling schemes. The lack of benchmarks for high-quality, fast CMR image reconstruction further limits technology comparison and adoption. The CMRxRecon2024 challenge, attracting over 200 teams from 18 countries, addressed these issues with two tasks: generalization to unseen modalities and robustness to diverse undersampling patterns. We introduced the largest public multi-modality CMR raw dataset, an open benchmarking platform, and shared code. Analysis of the best-performing solutions revealed that prompt-based adaptation and enhanced physics-driven consistency enabled strong cross-scenario performance. These findings establish principles for generalizable reconstruction models and advance clinically translatable AI in cardiovascular imaging.

KW - Cardiovascular imaging

KW - image reconstruction

KW - magnetic resonance imaging

KW - prompt learning

KW - universal models

UR - https://www.scopus.com/pages/publications/105024606748

U2 - 10.1109/TMI.2025.3641610

DO - 10.1109/TMI.2025.3641610

M3 - Article

C2 - 41359736

AN - SCOPUS:105024606748

SN - 0278-0062

VL - 45

SP - 1872

EP - 1887

JO - IEEE Transactions on Medical Imaging

JF - IEEE Transactions on Medical Imaging

IS - 5

ER -

Toward Modality- and Sampling-Universal Learning Strategies for Accelerating Cardiovascular Imaging: Summary of the CMRxRecon2024 Challenge

Abstract

Bibliographical note

UN SDGs

Keywords

Access to Document

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