Program Information
High Density Scintillating Glass Proton Imaging Detector
C Wilkinson1 , A Zieser2 , L Ruane3*, U Akgun1 , (1) Coe College, Cedar Rapids, IA, (2) University of Iowa, Iowa City, IA, (3) Hastings College, Hastings, NE,
Presentations
SU-I-GPD-SPS-2 (Sunday, July 30, 2017) 3:00 PM - 6:00 PM Room: Exhibit Hall
Purpose: Proton therapy has potential of remarkable precision in delivering doses to cancerous cells while avoiding healthy tissue. However, in order to utilize this high precision treatment, greater accuracy in patient positioning is needed. An accepted approximate uncertainty of ±3% exists in the current practice of proton therapy due to conversions between x-ray and proton stopping power. The use of protons in imaging would eliminate this source of error and lessen the radiation exposure of the patient. To this end, this study focuses on developing a novel proton-imaging detector built with high-density glass. We envision this compact system to be attached to the gantry.
Methods: The model described herein contains a compact homogeneous proton calorimeter composed of high-density glass as the active medium. The unique geometry of this detector allows for the measurement of both the position and residual energy of protons, eliminating the need for a separate set of position trackers in the system. Average position and energy of a pencil beam of 10^6 protons is used to reconstruct the image rather than by analyzing individual proton data. Simplicity and efficiency were major objectives in this model in order to present an imaging technique that is compact, cost-effective, and precise, as well as practical for a clinical setting with pencil-beam scanning proton therapy equipment.
Results: In this work, the development of novel high-density scintillating and semiconductive glass samples and the unique conceptual design of the imager are discussed; a proof-of-principle Monte Carlo simulation study is performed; preliminary two-dimensional images reconstructed from the Geant4 simulation are presented.
Conclusion: Our proof-of-concept model shows that a pencil beam and a compact calorimeter may work as a feasible proton imaging system that can be used before and during the therapy.
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