Transplant-Ready? Evaluating AI Lung Segmentation Models in Candidates with Severe Lung Disease
- URL: http://arxiv.org/abs/2509.15083v1
- Date: Thu, 18 Sep 2025 15:42:43 GMT
- Title: Transplant-Ready? Evaluating AI Lung Segmentation Models in Candidates with Severe Lung Disease
- Authors: Jisoo Lee, Michael R. Harowicz, Yuwen Chen, Hanxue Gu, Isaac S. Alderete, Lin Li, Maciej A. Mazurowski, Matthew G. Hartwig,
- Abstract summary: This study evaluates publicly available deep-learning based lung segmentation models in transplant-eligible patients.<n>Unet-R231 provided the most accurate automated lung segmentation among evaluated models.
- Score: 11.854505363942941
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: This study evaluates publicly available deep-learning based lung segmentation models in transplant-eligible patients to determine their performance across disease severity levels, pathology categories, and lung sides, and to identify limitations impacting their use in preoperative planning in lung transplantation. This retrospective study included 32 patients who underwent chest CT scans at Duke University Health System between 2017 and 2019 (total of 3,645 2D axial slices). Patients with standard axial CT scans were selected based on the presence of two or more lung pathologies of varying severity. Lung segmentation was performed using three previously developed deep learning models: Unet-R231, TotalSegmentator, MedSAM. Performance was assessed using quantitative metrics (volumetric similarity, Dice similarity coefficient, Hausdorff distance) and a qualitative measure (four-point clinical acceptability scale). Unet-R231 consistently outperformed TotalSegmentator and MedSAM in general, for different severity levels, and pathology categories (p<0.05). All models showed significant performance declines from mild to moderate-to-severe cases, particularly in volumetric similarity (p<0.05), without significant differences among lung sides or pathology types. Unet-R231 provided the most accurate automated lung segmentation among evaluated models with TotalSegmentator being a close second, though their performance declined significantly in moderate-to-severe cases, emphasizing the need for specialized model fine-tuning in severe pathology contexts.
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