Endobronchial Ultrasound Image Simulation for Image-Guided Bronchoscopy

Background/Objective: Accurate disease diagnosis and staging are essential for patients suspected of having lung cancer. The state-of-the-art minimally invasive tools used by physicians to perform these operations are bronchoscopy, for navigating the lung airways, and endobronchial ultrasound (EBUS)...

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Bibliographic Details
Published in:IEEE transactions on biomedical engineering 2023-01, Vol.70 (1), p.318-330
Main Authors: Zhao, Wennan, Ahmad, Danish, Toth, Jennifer, Bascom, Rebecca, Higgins, William E.
Format: Article
Language:English
Subjects:
Bronchoscopy
Bronchoscopy - methods
Computational modeling
Computed tomography
endobronchial ultrasound
Endosonography - methods
Humans
image-guided bronchoscopy systems
image-guided surgery systems
Lesions
Localization
Lung - diagnostic imaging
Lung cancer
Lung Neoplasms - diagnostic imaging
Medical imaging
Medical instruments
Probes
Simulation
Three-dimensional displays
Ultrasonic imaging
Ultrasonic testing
Ultrasonography
Ultrasound
ultrasound simulation
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Summary:Background/Objective: Accurate disease diagnosis and staging are essential for patients suspected of having lung cancer. The state-of-the-art minimally invasive tools used by physicians to perform these operations are bronchoscopy, for navigating the lung airways, and endobronchial ultrasound (EBUS), for localizing suspect extraluminal cancer lesions. While new image-guided systems enable accurate bronchoscope navigation close to a lesion, no means exists for guiding the final EBUS localization of an extraluminal lesion. We propose an EBUS simulation method to assist with EBUS localization. Methods: The method draws on a patient's chest computed-tomography (CT) scan to model the ultrasound signal propagation through the tissue media. The method, which is suitable for simulating EBUS images for both radial-probe and convex-probe EBUS devices, entails three steps: 1) image preprocessing, which generates a 2D CT equivalent of the EBUS scan plane; 2) EBUS scan-line computation, which models ultrasound transmission to map the CT plane into a preliminary simulated EBUS image; and 3) image post-processing, which increases realism by introducing simulated EBUS imaging effects and artifacts. Results: Results show that the method produces simulated EBUS images that strongly resemble images generated live by a real device and compares favorably to an existing ultrasound simulation method. It also produces images at a rate greater than real time (i.e., >53 frames/sec). We also demonstrate a successful integration of the method into an image-guided EBUS bronchoscopy system. Conclusion/Significance: The method is effective and practical for procedure planning/preview and follow-on live guidance of EBUS bronchoscopy.
ISSN:0018-9294
1558-2531
DOI:10.1109/TBME.2022.3190165