Initial testing of a pixelated silicon detector prototype in proton therapy

As technology continues to develop, external beam radiation therapy is being employed, with increased conformity, to treat smaller targets. As this occurs, the dosimetry methods and tools employed to quantify these fields for treatment also have to evolve to provide increased spatial resolution. The...

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Published in:Journal of applied clinical medical physics 2017-09, Vol.18 (5), p.315-324
Main Authors: Wroe, Andrew J., McAuley, Grant, Teran, Anthony V., Wong, Jeannie, Petasecca, Marco, Lerch, Michael, Slater, James M., Rozenfeld, Anatoly B.
Format: Article
Language:English
Subjects:
Arrays
Diodes
Dosimetry
Equipment Design
Monte Carlo Method
proton therapy
Proton Therapy - instrumentation
Radiation Measurements
Radiation therapy
Radiometry - instrumentation
radiosurgery
Radiosurgery - instrumentation
Radiosurgery - methods
Real time
Scanners
Sensors
Silicon
silicon diode radiation detectors
small‐field dosimetry
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cited_by cdi_FETCH-LOGICAL-c4760-39e4e15e11e3505916a20d3d9fdd3ce0fa59cf03c5f075aeb4763b903a8785a53
cites cdi_FETCH-LOGICAL-c4760-39e4e15e11e3505916a20d3d9fdd3ce0fa59cf03c5f075aeb4763b903a8785a53
container_end_page 324
container_issue 5
container_start_page 315
container_title Journal of applied clinical medical physics
container_volume 18
creator Wroe, Andrew J.
McAuley, Grant
Teran, Anthony V.
Wong, Jeannie
Petasecca, Marco
Lerch, Michael
Slater, James M.
Rozenfeld, Anatoly B.
description As technology continues to develop, external beam radiation therapy is being employed, with increased conformity, to treat smaller targets. As this occurs, the dosimetry methods and tools employed to quantify these fields for treatment also have to evolve to provide increased spatial resolution. The team at the University of Wollongong has developed a pixelated silicon detector prototype known as the dose magnifying glass (DMG) for real‐time small‐field metrology. This device has been tested in photon fields and IMRT. The purpose of this work was to conduct the initial performance tests with proton radiation, using beam energies and modulations typically associated with proton radiosurgery. Depth dose and lateral beam profiles were measured and compared with those collected using a PTW parallel‐plate ionization chamber, a PTW proton‐specific dosimetry diode, EBT3 Gafchromic film, and Monte Carlo simulations. Measurements of the depth dose profile yielded good agreement when compared with Monte Carlo, diode and ionization chamber. Bragg peak location was measured accurately by the DMG by scanning along the depth dose profile, and the relative response of the DMG at the center of modulation was within 2.5% of that for the PTW dosimetry diode for all energy and modulation combinations tested. Real‐time beam profile measurements of a 5 mm 127 MeV proton beam also yielded FWHM and FW90 within ±1 channel (0.1 mm) of the Monte Carlo and EBT3 film data across all depths tested. The DMG tested here proved to be a useful device at measuring depth dose profiles in proton therapy with a stable response across the entire proton spread‐out Bragg peak. In addition, the linear array of small sensitive volumes allowed for accurate point and high spatial resolution one‐dimensional profile measurements of small radiation fields in real time to be completed with minimal impact from partial volume averaging.
doi_str_mv 10.1002/acm2.12120
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source Wiley-Blackwell Open Access Collection; Publicly Available Content Database; PubMed Central
subjects Arrays
Diodes
Dosimetry
Equipment Design
Monte Carlo Method
proton therapy
Proton Therapy - instrumentation
Radiation Measurements
Radiation therapy
Radiometry - instrumentation
radiosurgery
Radiosurgery - instrumentation
Radiosurgery - methods
Real time
Scanners
Sensors
Silicon
silicon diode radiation detectors
small‐field dosimetry
title Initial testing of a pixelated silicon detector prototype in proton therapy
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