A visual probe positioning tool for 4D ultrasound-guided radiotherapy

Ultrasound (US) guidance is a rapidly growing area in image-guided radiotherapy. For motion compensation, the therapy target needs to be visualized with the US probe to continuously determine its position and adapt for shifts. While US has obvious benefits such as real-time capability and proven saf...

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Bibliographic Details
Main Authors: Ipsen, Svenja, Bruder, Ralf, Kuhlemann, Ivo, Jauer, Philipp, Motisi, Laura, Cremers, Florian, Ernst, Floris, Schweikard, Achim
Format: Conference Proceeding
Language:English
Subjects:
Calibration
Computed tomography
Data visualization
Probes
Real-time systems
Visualization
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Summary:Ultrasound (US) guidance is a rapidly growing area in image-guided radiotherapy. For motion compensation, the therapy target needs to be visualized with the US probe to continuously determine its position and adapt for shifts. While US has obvious benefits such as real-time capability and proven safety, one of the main drawbacks to date is its user dependency - high quality results require long years of clinical experience. To provide positioning assistance for the setup of US equipment by non-experts, we developed a visual guidance tool combining real-time US volume and CT visualization in a geometrically calibrated setup. By using a 4D US station with real-time data access and an optical tracking system, we achieved a calibration accuracy of 1.2 mm and a mean 2D contour distance of 1.7 mm between organ boundaries identified in US and CT. With this low calibration error as well as the good visual alignment of the structures, the developed probe positioning tool could be a valuable aid for ultrasound-guided radiotherapy and other interventions by guiding the user to a suitable acoustic window while potentially improving setup reproducibility.
ISSN:1558-4615
2694-0604
DOI:10.1109/EMBC.2018.8512390