Deep learning-driven pulmonary artery and vein segmentation reveals demography-associated vasculature anatomical differences

Yuetan Chu; Gongning Luo; Longxi Zhou; Shaodong Cao; Guolin Ma; Xianglin Meng; Juexiao Zhou; Changchun Yang; Dexuan Xie; Dan Mu; Ricardo Henao; Gianluca Setti; Xigang Xiao; Lianming Wu; Zhaowen Qiu; Xin Gao

doi:10.1038/s41467-025-56505-6

Deep learning-driven pulmonary artery and vein segmentation reveals demography-associated vasculature anatomical differences

Yuetan Chu
, Gongning Luo^*
, Longxi Zhou
, Shaodong Cao
, Guolin Ma
, Xianglin Meng
, Juexiao Zhou
, Changchun Yang
, Dexuan Xie
, Dan Mu
, Ricardo Henao
, Gianluca Setti^*
, Xigang Xiao^*
, Lianming Wu^*
, Zhaowen Qiu^*
, Xin Gao^*

^*Corresponding author for this work

King Abdullah University of Science and Technology
Harbin Medical University
China-Japan Friendship Hospital
The First Affiliated Hospital of Harbin Medical University
Affiliated Nanjing Drum Tower Hospital of Nanjing University Medical School
Shanghai Jiao Tong University
Northeast Forestry University

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

10 Scopus citations

Abstract

Pulmonary artery-vein segmentation is critical for disease diagnosis and surgical planning. Traditional methods rely on Computed Tomography Pulmonary Angiography (CTPA), which requires contrast agents with potential health risks. Non-contrast CT, a safer and more widely available approach, however, has long been considered impossible for this task. Here we propose High-abundant Pulmonary Artery-vein Segmentation (HiPaS), enabling accurate segmentation across both non-contrast CT and CTPA at multiple resolutions. HiPaS integrates spatial normalization with an iterative segmentation strategy, leveraging lower-level vessel segmentations as priors for higher-level segmentations. Trained on a multi-center dataset comprising 1073 CT volumes with manual annotations, HiPaS achieves superior performance (dice score: 91.8%, sensitivity: 98.0%) and demonstrates non-inferiority on non-contrast CT compared to CTPA. Furthermore, HiPaS enables large-scale analysis of 11,784 participants, revealing associations between vessel abundance and sex, age, and diseases, under lung-volume control. HiPaS represents a promising, non-invasive approach for clinical diagnostics and anatomical research.

Original language	English
Article number	2262
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-56505-6
State	Published - Dec 2025
Externally published	Yes

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

SDG 3 Good Health and Well-being

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Chu, Y., Luo, G., Zhou, L., Cao, S., Ma, G., Meng, X., Zhou, J., Yang, C., Xie, D., Mu, D., Henao, R., Setti, G., Xiao, X., Wu, L., Qiu, Z., & Gao, X. (2025). Deep learning-driven pulmonary artery and vein segmentation reveals demography-associated vasculature anatomical differences. Nature Communications, 16(1), Article 2262. https://doi.org/10.1038/s41467-025-56505-6

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title = "Deep learning-driven pulmonary artery and vein segmentation reveals demography-associated vasculature anatomical differences",

abstract = "Pulmonary artery-vein segmentation is critical for disease diagnosis and surgical planning. Traditional methods rely on Computed Tomography Pulmonary Angiography (CTPA), which requires contrast agents with potential health risks. Non-contrast CT, a safer and more widely available approach, however, has long been considered impossible for this task. Here we propose High-abundant Pulmonary Artery-vein Segmentation (HiPaS), enabling accurate segmentation across both non-contrast CT and CTPA at multiple resolutions. HiPaS integrates spatial normalization with an iterative segmentation strategy, leveraging lower-level vessel segmentations as priors for higher-level segmentations. Trained on a multi-center dataset comprising 1073 CT volumes with manual annotations, HiPaS achieves superior performance (dice score: 91.8\%, sensitivity: 98.0\%) and demonstrates non-inferiority on non-contrast CT compared to CTPA. Furthermore, HiPaS enables large-scale analysis of 11,784 participants, revealing associations between vessel abundance and sex, age, and diseases, under lung-volume control. HiPaS represents a promising, non-invasive approach for clinical diagnostics and anatomical research.",

author = "Yuetan Chu and Gongning Luo and Longxi Zhou and Shaodong Cao and Guolin Ma and Xianglin Meng and Juexiao Zhou and Changchun Yang and Dexuan Xie and Dan Mu and Ricardo Henao and Gianluca Setti and Xigang Xiao and Lianming Wu and Zhaowen Qiu and Xin Gao",

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doi = "10.1038/s41467-025-56505-6",

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AU - Chu, Yuetan

AU - Luo, Gongning

AU - Zhou, Longxi

AU - Cao, Shaodong

AU - Ma, Guolin

AU - Meng, Xianglin

AU - Zhou, Juexiao

AU - Yang, Changchun

AU - Xie, Dexuan

AU - Mu, Dan

AU - Henao, Ricardo

AU - Setti, Gianluca

AU - Xiao, Xigang

AU - Wu, Lianming

AU - Qiu, Zhaowen

AU - Gao, Xin

PY - 2025/12

Y1 - 2025/12

N2 - Pulmonary artery-vein segmentation is critical for disease diagnosis and surgical planning. Traditional methods rely on Computed Tomography Pulmonary Angiography (CTPA), which requires contrast agents with potential health risks. Non-contrast CT, a safer and more widely available approach, however, has long been considered impossible for this task. Here we propose High-abundant Pulmonary Artery-vein Segmentation (HiPaS), enabling accurate segmentation across both non-contrast CT and CTPA at multiple resolutions. HiPaS integrates spatial normalization with an iterative segmentation strategy, leveraging lower-level vessel segmentations as priors for higher-level segmentations. Trained on a multi-center dataset comprising 1073 CT volumes with manual annotations, HiPaS achieves superior performance (dice score: 91.8%, sensitivity: 98.0%) and demonstrates non-inferiority on non-contrast CT compared to CTPA. Furthermore, HiPaS enables large-scale analysis of 11,784 participants, revealing associations between vessel abundance and sex, age, and diseases, under lung-volume control. HiPaS represents a promising, non-invasive approach for clinical diagnostics and anatomical research.

AB - Pulmonary artery-vein segmentation is critical for disease diagnosis and surgical planning. Traditional methods rely on Computed Tomography Pulmonary Angiography (CTPA), which requires contrast agents with potential health risks. Non-contrast CT, a safer and more widely available approach, however, has long been considered impossible for this task. Here we propose High-abundant Pulmonary Artery-vein Segmentation (HiPaS), enabling accurate segmentation across both non-contrast CT and CTPA at multiple resolutions. HiPaS integrates spatial normalization with an iterative segmentation strategy, leveraging lower-level vessel segmentations as priors for higher-level segmentations. Trained on a multi-center dataset comprising 1073 CT volumes with manual annotations, HiPaS achieves superior performance (dice score: 91.8%, sensitivity: 98.0%) and demonstrates non-inferiority on non-contrast CT compared to CTPA. Furthermore, HiPaS enables large-scale analysis of 11,784 participants, revealing associations between vessel abundance and sex, age, and diseases, under lung-volume control. HiPaS represents a promising, non-invasive approach for clinical diagnostics and anatomical research.

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DO - 10.1038/s41467-025-56505-6

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VL - 16

JO - Nature Communications

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Deep learning-driven pulmonary artery and vein segmentation reveals demography-associated vasculature anatomical differences

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