Program Information
Dynamic Blade Collimation for Image Quality Improvement and Dose Reduction in CBCT Guidance
D Parsons1*, J Robar1,2 , (1) Department of Physics and Atmospheric Science, Dalhousie University, Halifax, NS (2) Capital District Health Authority, Halifax, NS
Presentations
TH-EF-BRB-5 (Thursday, July 16, 2015) 1:00 PM - 2:50 PM Room: Ballroom B
Purpose: The focus of this work is the development of a novel blade collimation system enabling volume-of-interest (VOI) CBCT using the kV source on a TrueBeam linear accelerator (linac). Advantages of the system are assessed, particularly with regard to reduction and localization of dose, as well as improvement of image quality.
Methods: A four blade dynamic kV collimator was developed to track a VOI during a CBCT acquisition. The system is controlled using a Raspberry Pi computer placed within the linac gantry. The current prototype is capable of tracking an arbitrary volume defined by the treatment planner for subsequent CBCT guidance. During gantry rotation, the collimator tracks the VOI with adjustment of position and dimension. CBCT image quality was investigated as a function of collimator dimension, while maintaining the same dose to the VOI, for a 20 cm diameter cylindrical water phantom with a 9 mm diameter bone insert centered on isocenter. Dose distributions for various anatomical sites were modeled using a dynamic BEAMnrc library and DOSXYZnrc. The resulting VOI dose distributions were compared to full-field distributions to quantify dose reduction and localization to the target volume.
Results: Preliminary measurements show contrast increase by a factor of 1.3 and noise reduction by a factor of 1.7, for CBCT. This results in a increase in contrast-to-noise ratio by a factor of approximately 2.2. Depending upon the anatomical site, dose was reduced to 15%–80% of the full field value along the central axis plane and down to less than 1% along the axial planes.
Conclusion: The present system allows CBCT imaging of a planner-defined volume, offering both image quality improvement and reduction of imaging dose for the patient. Current work involves the development of fluence modulation for VOI CBCT.
Funding Support, Disclosures, and Conflict of Interest: This work was supported through a research partnership with Varian Medical, Incorporated.
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