2.5D mapping of the esophagus as imaging quality and completeness assuring extension for endoscopic computer-aided detection systems

Esmee Esselaar; Tim J.M. Jaspers; Koen Kusters; Tim Boers; Martijn R. Jong; Rixta A.H. van Eijck van Heslinga; Albert J. (Jeroen) de Groof; Jacques J.G.H.M. Bergman; Peter H.N. de With; Fons van der Sommen

doi:10.1117/12.3046636

2.5D mapping of the esophagus as imaging quality and completeness assuring extension for endoscopic computer-aided detection systems

Esmee Esselaar, Tim J.M. Jaspers (Corresponding author), Koen Kusters, Tim Boers, Martijn R. Jong, Rixta A.H. van Eijck van Heslinga, Albert J. (Jeroen) de Groof, Jacques J.G.H.M. Bergman, Peter H.N. de With, Fons van der Sommen

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

Abstract

Quality and completeness of images taken during endoscopy of the esophagus are of high importance for their use in computer-aided detection (CADe) systems. Providing a tissue map to show visited locations with sufficient image quality, and providing feedback on the completeness of the procedure could ensure standards are met for input to CADe systems. However, existing solutions are either not translatable to esophageal endoscopy procedures or impose unrealistic restrictions on endoscope movement. Our study shows the first steps in developing a tissue mapping algorithm for esophageal endoscopy, that is robust against camera rotation and movement natural to endoscopy procedures. The method combines SIFT-feature-based visual odometry and image stitching to generate a 2.5D map of the esophagus. The algorithm is tested in a virtual model environment, on 6 scenarios mimicking the movements and rotations of an endoscope during a pullback procedure. Results are evaluated based on ground-truth camera pose and distortion of the generated map. It is demonstrated that the proposed algorithm can generate accurate tissue maps but is sensitive to errors in estimated camera position and rotation.

Original language	English
Title of host publication	Medical Imaging 2025
Subtitle of host publication	Computer-Aided Diagnosis
Editors	Susan M. Astley, Axel Wismüller
Publisher	SPIE
Number of pages	9
DOIs	https://doi.org/10.1117/12.3046636
Publication status	Published - 4 Apr 2025
Event	SPIE Medical Imaging 2025 - San Diego, United States Duration: 16 Feb 2025 → 21 Feb 2025

Publication series

Name	Proceedings of SPIE
Volume	13407
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	SPIE Medical Imaging 2025
Country/Territory	United States
City	San Diego
Period	16/02/25 → 21/02/25

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Esselaar, E., Jaspers, T. J. M., Kusters, K., Boers, T., Jong, M. R., van Eijck van Heslinga, R. A. H., de Groof, A. J., Bergman, J. J. G. H. M., de With, P. H. N., & van der Sommen, F. (2025). 2.5D mapping of the esophagus as imaging quality and completeness assuring extension for endoscopic computer-aided detection systems. In S. M. Astley, & A. Wismüller (Eds.), Medical Imaging 2025: Computer-Aided Diagnosis Article 1340733 (Proceedings of SPIE; Vol. 13407). SPIE. https://doi.org/10.1117/12.3046636

@inproceedings{b1f72519650247c4ae91a14fcb748d59,

title = "2.5D mapping of the esophagus as imaging quality and completeness assuring extension for endoscopic computer-aided detection systems",

abstract = "Quality and completeness of images taken during endoscopy of the esophagus are of high importance for their use in computer-aided detection (CADe) systems. Providing a tissue map to show visited locations with sufficient image quality, and providing feedback on the completeness of the procedure could ensure standards are met for input to CADe systems. However, existing solutions are either not translatable to esophageal endoscopy procedures or impose unrealistic restrictions on endoscope movement. Our study shows the first steps in developing a tissue mapping algorithm for esophageal endoscopy, that is robust against camera rotation and movement natural to endoscopy procedures. The method combines SIFT-feature-based visual odometry and image stitching to generate a 2.5D map of the esophagus. The algorithm is tested in a virtual model environment, on 6 scenarios mimicking the movements and rotations of an endoscope during a pullback procedure. Results are evaluated based on ground-truth camera pose and distortion of the generated map. It is demonstrated that the proposed algorithm can generate accurate tissue maps but is sensitive to errors in estimated camera position and rotation.",

author = "Esmee Esselaar and Jaspers, {Tim J.M.} and Koen Kusters and Tim Boers and Jong, {Martijn R.} and {van Eijck van Heslinga}, {Rixta A.H.} and {de Groof}, {Albert J. (Jeroen)} and Bergman, {Jacques J.G.H.M.} and {de With}, {Peter H.N.} and {van der Sommen}, Fons",

year = "2025",

month = apr,

day = "4",

doi = "10.1117/12.3046636",

language = "English",

series = "Proceedings of SPIE",

publisher = "SPIE",

editor = "Astley, {Susan M.} and Axel Wism{\"u}ller",

booktitle = "Medical Imaging 2025",

address = "United States",

note = "SPIE Medical Imaging 2025 ; Conference date: 16-02-2025 Through 21-02-2025",

}

Esselaar, E, Jaspers, TJM , Kusters, K , Boers, T, Jong, MR, van Eijck van Heslinga, RAH, de Groof, AJ, Bergman, JJGHM, de With, PHN & van der Sommen, F 2025, 2.5D mapping of the esophagus as imaging quality and completeness assuring extension for endoscopic computer-aided detection systems. in SM Astley & A Wismüller (eds), Medical Imaging 2025: Computer-Aided Diagnosis., 1340733, Proceedings of SPIE, vol. 13407, SPIE, SPIE Medical Imaging 2025, San Diego, United States, 16/02/25. https://doi.org/10.1117/12.3046636

2.5D mapping of the esophagus as imaging quality and completeness assuring extension for endoscopic computer-aided detection systems. / Esselaar, Esmee; Jaspers, Tim J.M. (Corresponding author); Kusters, Koen et al.
Medical Imaging 2025: Computer-Aided Diagnosis. ed. / Susan M. Astley; Axel Wismüller. SPIE, 2025. 1340733 (Proceedings of SPIE; Vol. 13407).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

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T1 - 2.5D mapping of the esophagus as imaging quality and completeness assuring extension for endoscopic computer-aided detection systems

AU - Esselaar, Esmee

AU - Jaspers, Tim J.M.

AU - Kusters, Koen

AU - Boers, Tim

AU - Jong, Martijn R.

AU - van Eijck van Heslinga, Rixta A.H.

AU - de Groof, Albert J. (Jeroen)

AU - Bergman, Jacques J.G.H.M.

AU - de With, Peter H.N.

AU - van der Sommen, Fons

PY - 2025/4/4

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N2 - Quality and completeness of images taken during endoscopy of the esophagus are of high importance for their use in computer-aided detection (CADe) systems. Providing a tissue map to show visited locations with sufficient image quality, and providing feedback on the completeness of the procedure could ensure standards are met for input to CADe systems. However, existing solutions are either not translatable to esophageal endoscopy procedures or impose unrealistic restrictions on endoscope movement. Our study shows the first steps in developing a tissue mapping algorithm for esophageal endoscopy, that is robust against camera rotation and movement natural to endoscopy procedures. The method combines SIFT-feature-based visual odometry and image stitching to generate a 2.5D map of the esophagus. The algorithm is tested in a virtual model environment, on 6 scenarios mimicking the movements and rotations of an endoscope during a pullback procedure. Results are evaluated based on ground-truth camera pose and distortion of the generated map. It is demonstrated that the proposed algorithm can generate accurate tissue maps but is sensitive to errors in estimated camera position and rotation.

AB - Quality and completeness of images taken during endoscopy of the esophagus are of high importance for their use in computer-aided detection (CADe) systems. Providing a tissue map to show visited locations with sufficient image quality, and providing feedback on the completeness of the procedure could ensure standards are met for input to CADe systems. However, existing solutions are either not translatable to esophageal endoscopy procedures or impose unrealistic restrictions on endoscope movement. Our study shows the first steps in developing a tissue mapping algorithm for esophageal endoscopy, that is robust against camera rotation and movement natural to endoscopy procedures. The method combines SIFT-feature-based visual odometry and image stitching to generate a 2.5D map of the esophagus. The algorithm is tested in a virtual model environment, on 6 scenarios mimicking the movements and rotations of an endoscope during a pullback procedure. Results are evaluated based on ground-truth camera pose and distortion of the generated map. It is demonstrated that the proposed algorithm can generate accurate tissue maps but is sensitive to errors in estimated camera position and rotation.

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DO - 10.1117/12.3046636

M3 - Conference contribution

T3 - Proceedings of SPIE

BT - Medical Imaging 2025

A2 - Astley, Susan M.

A2 - Wismüller, Axel

PB - SPIE

T2 - SPIE Medical Imaging 2025

Y2 - 16 February 2025 through 21 February 2025

ER -

Esselaar E, Jaspers TJM , Kusters K , Boers T, Jong MR, van Eijck van Heslinga RAH et al. 2.5D mapping of the esophagus as imaging quality and completeness assuring extension for endoscopic computer-aided detection systems. In Astley SM, Wismüller A, editors, Medical Imaging 2025: Computer-Aided Diagnosis. SPIE. 2025. 1340733. (Proceedings of SPIE). doi: 10.1117/12.3046636

2.5D mapping of the esophagus as imaging quality and completeness assuring extension for endoscopic computer-aided detection systems

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