Semi-analytical model for output factor calculations in proton beam therapy with consideration for the collimator aperture edge

In the development of an external radiotherapy treatment planning system, the output factor (OPF) is an important value for the monitor unit calculations. We developed a proton OPF calculation model with consideration for the collimator aperture edge to account for the dependence of the OPF on the c...

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Bibliographic Details
Published in:Physics in medicine & biology 2015-08, Vol.60 (15), p.5833-5852
Main Authors: Kase, Yuki, Yamashita, Haruo, Sakama, Makoto, Mizota, Manabu, Maeda, Yoshikazu, Tameshige, Yuji, Murayama, Shigeyuki
Format: Article
Language:English
Subjects:
Algorithms
Calibration
collimator scattering
Computer Simulation
field size effect
Humans
Models, Biological
Models, Theoretical
monitor unit
Monte Carlo Method
output factor
proton beam therapy
Proton Therapy
Radiometry - methods
Radiotherapy Dosage
Radiotherapy Planning, Computer-Assisted - methods
Relative Biological Effectiveness
Scattering, Radiation
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Summary:In the development of an external radiotherapy treatment planning system, the output factor (OPF) is an important value for the monitor unit calculations. We developed a proton OPF calculation model with consideration for the collimator aperture edge to account for the dependence of the OPF on the collimator aperture and distance in proton beam therapy. Five parameters in the model were obtained by fitting with OPFs measured by a pinpoint chamber with the circular radiation fields of various field radii and collimator distances. The OPF model calculation using the fitted model parameters could explain the measurement results to within 1.6% error in typical proton treatment beams with 6- and 12 cm SOBP widths through a range shifter and a circular aperture more than 10.6 mm in radius. The calibration depth dependences of the model parameters were approximated by linear or quadratic functions. The semi-analytical OPF model calculation was tested with various MLC aperture shapes that included circles of various sizes as well as a rectangle, parallelogram, and L-shape for an intermediate proton treatment beam condition. The pre-calculated OPFs agreed well with the measured values, to within 2.7% error up to 620 mm in the collimator distance, though the maximum difference was 5.1% in the case of the largest collimator distance of 740 mm. The OPF calculation model would allow more accurate monitor unit calculations for therapeutic proton beams within the expected range of collimator conditions in clinical use.
ISSN:0031-9155
1361-6560
DOI:10.1088/0031-9155/60/15/5833