Transit dosimetry in IMRT with an a-Si EPID in direct detection configuration

Sabet, Mahsheed; Rowshanfarzad, Pejman; Vial, Philip; Menk, Frederick W.; Greer, Peter B.

Title: Transit dosimetry in IMRT with an a-Si EPID in direct detection configuration
Creator: Sabet, Mahsheed; Rowshanfarzad, Pejman; Vial, Philip; Menk, Frederick W.; Greer, Peter B.
Relation: NHMRC.569211 http://purl.org/au-research/grants/nhmrc/569211
Relation: Physics in Medicine and Biology Vol. 57, Issue 15, p. N295-N306
Publisher Link: http://dx.doi.org/10.1088/0031-9155/57/15/N295
Publisher: Institute of Physics Publishing
Resource Type: journal article
Date: 2012
Description: In this study an amorphous silicon electronic portal imaging device (a-Si EPID) converted to direct detection configuration was investigated as a transit dosimeter for intensity modulated radiation therapy (IMRT). After calibration to dose and correction for a background offset signal, the EPID-measured absolute IMRT transit doses for 29 fields were compared to a MatriXX two-dimensional array of ionization chambers (as reference) using Gamma evaluation (3%, 3 mm). The MatriXX was first evaluated as reference for transit dosimetry. The accuracy of EPID measurements was also investigated by comparison of point dose measurements by an ionization chamber on the central axis with slab and anthropomorphic phantoms in a range of simple to complex fields. The uncertainty in ionization chamber measurements in IMRT fields was also investigated by its displacement from the central axis and comparison with the central axis measurements. Comparison of the absolute doses measured by the EPID and MatriXX with slab phantoms in IMRT fields showed that on average 96.4% and 97.5% of points had a Gamma index <1 in head and neck and prostate fields, respectively. For absolute dose comparisons with anthropomorphic phantoms, the values changed to an average of 93.6%, 93.7% and 94.4% of points with Gamma index <1 in head and neck, brain and prostate fields, respectively. Point doses measured by the EPID and ionization chamber were within 3% difference for all conditions. The deviations introduced in the response of the ionization chamber in IMRT fields were <1%. The direct EPID performance for transit dosimetry showed that it has the potential to perform accurate, efficient and comprehensive in vivo dosimetry for IMRT.
Subject: amorphous silicon electronic portal imaging device; gamma; anthropomorphic phantoms; intensity modulated radiation therapy
Identifier: http://hdl.handle.net/1959.13/1340654
Identifier: uon:28541
Identifier: ISSN:0031-9155
Language: eng
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