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Main Authors: Khan, Wasif, Rees, John, See, Kyle B., Kato, Simon, Huang, Ziqian, Lazarte, Amy, Douglas, Kyle, Lou, Xiangyang, Peng, Teng J., Rajderkar, Dhanashree, Sanelli, Pina, Singh, Amita, Tuna, Ibrahim, Wilson, Christina A., Fang, Ruogu
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.22673
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author Khan, Wasif
Rees, John
See, Kyle B.
Kato, Simon
Huang, Ziqian
Lazarte, Amy
Douglas, Kyle
Lou, Xiangyang
Peng, Teng J.
Rajderkar, Dhanashree
Sanelli, Pina
Singh, Amita
Tuna, Ibrahim
Wilson, Christina A.
Fang, Ruogu
author_facet Khan, Wasif
Rees, John
See, Kyle B.
Kato, Simon
Huang, Ziqian
Lazarte, Amy
Douglas, Kyle
Lou, Xiangyang
Peng, Teng J.
Rajderkar, Dhanashree
Sanelli, Pina
Singh, Amita
Tuna, Ibrahim
Wilson, Christina A.
Fang, Ruogu
contents Perfusion imaging is extensively utilized to assess hemodynamic status and tissue perfusion in various organs. Computed tomography perfusion (CTP) imaging plays a key role in the early assessment and planning of stroke treatment. While CTP provides essential perfusion parameters to identify abnormal blood flow in the brain, the use of contrast agents in CTP can lead to allergic reactions and adverse side effects, along with costing USD 4.9 billion worldwide in 2022. To address these challenges, we propose a novel deep learning framework called Multitask Automated Generation of Intermodal CT perfusion maps (MAGIC). This framework combines generative artificial intelligence and physiological information to map non-contrast computed tomography (CT) imaging to multiple contrast-free CTP imaging maps. We demonstrate enhanced image fidelity by incorporating physiological characteristics into the loss terms. Our network was trained and validated using CT image data from patients referred for stroke at UF Health and demonstrated robustness to abnormalities in brain perfusion activity. A double-blinded study was conducted involving seven experienced neuroradiologists and vascular neurologists. This study validated MAGIC's visual quality and diagnostic accuracy showing favorable performance compared to clinical perfusion imaging with intravenous contrast injection. Overall, MAGIC holds great promise in revolutionizing healthcare by offering contrast-free, cost-effective, and rapid perfusion imaging.
format Preprint
id arxiv_https___arxiv_org_abs_2505_22673
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Physiology-Informed Generative Multi-Task Network for Contrast-Free CT Perfusion
Khan, Wasif
Rees, John
See, Kyle B.
Kato, Simon
Huang, Ziqian
Lazarte, Amy
Douglas, Kyle
Lou, Xiangyang
Peng, Teng J.
Rajderkar, Dhanashree
Sanelli, Pina
Singh, Amita
Tuna, Ibrahim
Wilson, Christina A.
Fang, Ruogu
Tissues and Organs
Artificial Intelligence
Computer Vision and Pattern Recognition
Perfusion imaging is extensively utilized to assess hemodynamic status and tissue perfusion in various organs. Computed tomography perfusion (CTP) imaging plays a key role in the early assessment and planning of stroke treatment. While CTP provides essential perfusion parameters to identify abnormal blood flow in the brain, the use of contrast agents in CTP can lead to allergic reactions and adverse side effects, along with costing USD 4.9 billion worldwide in 2022. To address these challenges, we propose a novel deep learning framework called Multitask Automated Generation of Intermodal CT perfusion maps (MAGIC). This framework combines generative artificial intelligence and physiological information to map non-contrast computed tomography (CT) imaging to multiple contrast-free CTP imaging maps. We demonstrate enhanced image fidelity by incorporating physiological characteristics into the loss terms. Our network was trained and validated using CT image data from patients referred for stroke at UF Health and demonstrated robustness to abnormalities in brain perfusion activity. A double-blinded study was conducted involving seven experienced neuroradiologists and vascular neurologists. This study validated MAGIC's visual quality and diagnostic accuracy showing favorable performance compared to clinical perfusion imaging with intravenous contrast injection. Overall, MAGIC holds great promise in revolutionizing healthcare by offering contrast-free, cost-effective, and rapid perfusion imaging.
title Physiology-Informed Generative Multi-Task Network for Contrast-Free CT Perfusion
topic Tissues and Organs
Artificial Intelligence
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2505.22673