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SU‐C‐207A‐04: Accuracy of Acoustic‐Based Proton Range Verification in Water
Author(s) -
Jones KC,
Vander Stappen F,
Sehgal CM,
Avery S
Publication year - 2016
Publication title -
medical physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.473
H-Index - 180
eISSN - 2473-4209
pISSN - 0094-2405
DOI - 10.1118/1.4955579
Subject(s) - standard deviation , imaging phantom , bragg peak , hydrophone , physics , noise (video) , amplitude , proton therapy , signal to noise ratio (imaging) , proton , signal (programming language) , optics , range (aeronautics) , calibration , nuclear magnetic resonance , materials science , acoustics , statistics , mathematics , nuclear physics , computer science , composite material , quantum mechanics , artificial intelligence , image (mathematics) , programming language
Purpose: To determine the accuracy and dose required for acoustic‐based proton range verification (protoacoustics) in water. Methods: Proton pulses with 17 µs FWHM and instantaneous currents of 480 nA (5.6 × 10 7 protons/pulse, 8.9 cGy/pulse) were generated by a clinical, hospital‐based cyclotron at the University of Pennsylvania. The protoacoustic signal generated in a water phantom by the 190 MeV proton pulses was measured with a hydrophone placed at multiple known positions surrounding the dose deposition. The background random noise was measured. The protoacoustic signal was simulated to compare to the experiments. Results: The maximum protoacoustic signal amplitude at 5 cm distance was 5.2 mPa per 1 × 10 7 protons (1.6 cGy at the Bragg peak). The background random noise of the measurement was 27 mPa. Comparison between simulation and experiment indicates that the hydrophone introduced a delay of 2.4 µs. For acoustic data collected with a signal‐to‐noise ratio (SNR) of 21, deconvolution of the protoacoustic signal with the proton pulse provided the most precise time‐of‐flight range measurement (standard deviation of 2.0 mm), but a systematic error (−4.5 mm) was observed. Conclusion: Based on water phantom measurements at a clinical hospital‐based cyclotron, protoacoustics is a potential technique for measuring the proton Bragg peak range with 2.0 mm standard deviation. Simultaneous use of multiple detectors is expected to reduce the standard deviation, but calibration is required to remove systematic error. Based on the measured background noise and protoacoustic amplitude, a SNR of 5.3 is projected for a deposited dose of 2 Gy.

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