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Main Authors: Piao, Sirong, Ming, Ying, Zhao, Ruijie, Wang, Jiaru, Xiao, Ran, Zhao, Rui, Liao, Zicheng, Xu, Qiqi, Luo, Shaoze, Li, Bing, Li, Lin, Ma, Zhuangfei, Zheng, Fuling, Song, Wei
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.17547
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author Piao, Sirong
Ming, Ying
Zhao, Ruijie
Wang, Jiaru
Xiao, Ran
Zhao, Rui
Liao, Zicheng
Xu, Qiqi
Luo, Shaoze
Li, Bing
Li, Lin
Ma, Zhuangfei
Zheng, Fuling
Song, Wei
author_facet Piao, Sirong
Ming, Ying
Zhao, Ruijie
Wang, Jiaru
Xiao, Ran
Zhao, Rui
Liao, Zicheng
Xu, Qiqi
Luo, Shaoze
Li, Bing
Li, Lin
Ma, Zhuangfei
Zheng, Fuling
Song, Wei
contents To characterize lobar and segmental airway volume differences between systemic lupus erythematosus (SLE) patients with interstitial lung disease (ILD) and those without ILD (non-ILD) using a deep learning-based approach on non-contrast chest high-resolution CT (HRCT). Methods: A retrospective analysis was conducted on 106 SLE patients (27 SLE-ILD, 79 SLE-non-ILD) who underwent HRCT. A customized deep learning framework based on the U-Net architecture was developed to automatically segment airway structures at the lobar and segmental levels via HRCT. Volumetric measurements of lung lobes and segments derived from the segmentations were statistically compared between the two groups using two-sample t-tests (significance threshold: p < 0.05). Results: At lobar level, significant airway volume enlargement in SLE-ILD patients was observed in the right upper lobe (p=0.009) and left upper lobe (p=0.039) compared to SLE-non-ILD. At the segmental level, significant differences were found in segments including R1 (p=0.016), R3 (p<0.001), and L3 (p=0.038), with the most marked changes in the upper lung zones, while lower zones showed non-significant trends. Conclusion: Our study demonstrates that an automated deep learning-based approach can effectively quantify airway volumes on HRCT scans and reveal significant, region-specific airway dilation in patients with SLE-ILD compared to those without ILD. The pattern of involvement, predominantly affecting the upper lobes and specific segments, highlights a distinct topographic phenotype of SLE-ILD and implicates airway structural alterations as a potential biomarker for disease presence. This AI-powered quantitative imaging biomarker holds promise for enhancing the early detection and monitoring of ILD in the SLE population, ultimately contributing to more personalized patient management.
format Preprint
id arxiv_https___arxiv_org_abs_2603_17547
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Deep Learning-Based Airway Segmentation in Systemic Lupus Erythematosus Patients with Interstitial Lung Disease (SLE-ILD): A Comparative High-Resolution CT Analysis
Piao, Sirong
Ming, Ying
Zhao, Ruijie
Wang, Jiaru
Xiao, Ran
Zhao, Rui
Liao, Zicheng
Xu, Qiqi
Luo, Shaoze
Li, Bing
Li, Lin
Ma, Zhuangfei
Zheng, Fuling
Song, Wei
Image and Video Processing
Computer Vision and Pattern Recognition
To characterize lobar and segmental airway volume differences between systemic lupus erythematosus (SLE) patients with interstitial lung disease (ILD) and those without ILD (non-ILD) using a deep learning-based approach on non-contrast chest high-resolution CT (HRCT). Methods: A retrospective analysis was conducted on 106 SLE patients (27 SLE-ILD, 79 SLE-non-ILD) who underwent HRCT. A customized deep learning framework based on the U-Net architecture was developed to automatically segment airway structures at the lobar and segmental levels via HRCT. Volumetric measurements of lung lobes and segments derived from the segmentations were statistically compared between the two groups using two-sample t-tests (significance threshold: p < 0.05). Results: At lobar level, significant airway volume enlargement in SLE-ILD patients was observed in the right upper lobe (p=0.009) and left upper lobe (p=0.039) compared to SLE-non-ILD. At the segmental level, significant differences were found in segments including R1 (p=0.016), R3 (p<0.001), and L3 (p=0.038), with the most marked changes in the upper lung zones, while lower zones showed non-significant trends. Conclusion: Our study demonstrates that an automated deep learning-based approach can effectively quantify airway volumes on HRCT scans and reveal significant, region-specific airway dilation in patients with SLE-ILD compared to those without ILD. The pattern of involvement, predominantly affecting the upper lobes and specific segments, highlights a distinct topographic phenotype of SLE-ILD and implicates airway structural alterations as a potential biomarker for disease presence. This AI-powered quantitative imaging biomarker holds promise for enhancing the early detection and monitoring of ILD in the SLE population, ultimately contributing to more personalized patient management.
title Deep Learning-Based Airway Segmentation in Systemic Lupus Erythematosus Patients with Interstitial Lung Disease (SLE-ILD): A Comparative High-Resolution CT Analysis
topic Image and Video Processing
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2603.17547