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Autores principales: Zhang, Francis Xiatian, Mackute, Emile, Kasaei, Mohammadreza, Dhaliwal, Kevin, Thomson, Robert, Khadem, Mohsen
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2509.11885
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author Zhang, Francis Xiatian
Mackute, Emile
Kasaei, Mohammadreza
Dhaliwal, Kevin
Thomson, Robert
Khadem, Mohsen
author_facet Zhang, Francis Xiatian
Mackute, Emile
Kasaei, Mohammadreza
Dhaliwal, Kevin
Thomson, Robert
Khadem, Mohsen
contents Monocular depth estimation in bronchoscopy can significantly improve real-time navigation accuracy and enhance the safety of interventions in complex, branching airways. Recent advances in depth foundation models have shown promise for endoscopic scenarios, yet these models often lack anatomical awareness in bronchoscopy, overfitting to local textures rather than capturing the global airway structure, particularly under ambiguous depth cues and poor lighting. To address this, we propose Brea-Depth, a novel framework that integrates airway-specific geometric priors into foundation model adaptation for bronchoscopic depth estimation. Our method introduces a depth-aware CycleGAN, refining the translation between real bronchoscopic images and airway geometries from anatomical data, effectively bridging the domain gap. In addition, we introduce an airway structure awareness loss to enforce depth consistency within the airway lumen while preserving smooth transitions and structural integrity. By incorporating anatomical priors, Brea-Depth enhances model generalization and yields more robust, accurate 3D airway reconstructions. To assess anatomical realism, we introduce Airway Depth Structure Evaluation, a new metric for structural consistency. We validate BREA-Depth on a collected ex vivo human lung dataset and an open bronchoscopic dataset, where it outperforms existing methods in anatomical depth preservation.
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spellingShingle BREA-Depth: Bronchoscopy Realistic Airway-geometric Depth Estimation
Zhang, Francis Xiatian
Mackute, Emile
Kasaei, Mohammadreza
Dhaliwal, Kevin
Thomson, Robert
Khadem, Mohsen
Computer Vision and Pattern Recognition
Monocular depth estimation in bronchoscopy can significantly improve real-time navigation accuracy and enhance the safety of interventions in complex, branching airways. Recent advances in depth foundation models have shown promise for endoscopic scenarios, yet these models often lack anatomical awareness in bronchoscopy, overfitting to local textures rather than capturing the global airway structure, particularly under ambiguous depth cues and poor lighting. To address this, we propose Brea-Depth, a novel framework that integrates airway-specific geometric priors into foundation model adaptation for bronchoscopic depth estimation. Our method introduces a depth-aware CycleGAN, refining the translation between real bronchoscopic images and airway geometries from anatomical data, effectively bridging the domain gap. In addition, we introduce an airway structure awareness loss to enforce depth consistency within the airway lumen while preserving smooth transitions and structural integrity. By incorporating anatomical priors, Brea-Depth enhances model generalization and yields more robust, accurate 3D airway reconstructions. To assess anatomical realism, we introduce Airway Depth Structure Evaluation, a new metric for structural consistency. We validate BREA-Depth on a collected ex vivo human lung dataset and an open bronchoscopic dataset, where it outperforms existing methods in anatomical depth preservation.
title BREA-Depth: Bronchoscopy Realistic Airway-geometric Depth Estimation
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2509.11885