Performance of two commercial electron beam algorithms over regions close to the lung–mediastinum interface, against Monte Carlo simulation and point dosimetry in virtual and anthropomorphic phantoms

Abstract Electron radiotherapy is applied to treat the chest wall close to the mediastinum. The performance of the GGPB and eMC algorithms implemented in the Varian Eclipse™ treatment planning system (TPS) was studied in this region for 9 and 16 MeV beams, against Monte Carlo (MC) simulations, point...

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Bibliographic Details
Published in:Physica medica 2014-03, Vol.30 (2), p.147-154
Main Authors: Ojala, J, Hyödynmaa, S, Barańczyk, R, Góra, E, Waligórski, M.P.R
Format: Article
Language:English
Subjects:
Algorithms
Dose calculation
Electron beam radiotherapy
Electrons - therapeutic use
Humans
Lung - radiation effects
Mediastinum - radiation effects
Monte Carlo
Monte Carlo Method
Phantoms, Imaging
Radiology
Radiometry
Radiotherapy Dosage
Radiotherapy Planning, Computer-Assisted - methods
TLD
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Summary:Abstract Electron radiotherapy is applied to treat the chest wall close to the mediastinum. The performance of the GGPB and eMC algorithms implemented in the Varian Eclipse™ treatment planning system (TPS) was studied in this region for 9 and 16 MeV beams, against Monte Carlo (MC) simulations, point dosimetry in a water phantom and dose distributions calculated in virtual phantoms. For the 16 MeV beam, the accuracy of these algorithms was also compared over the lung-mediastinum interface region of an anthropomorphic phantom, against MC calculations and thermoluminescence dosimetry (TLD). In the phantom with a lung–equivalent slab the results were generally congruent, the eMC results for the 9 MeV beam slightly overestimating the lung dose, and the GGPB results for the 16 MeV beam underestimating the lung dose. Over the lung–mediastinum interface, for 9 and 16 MeV beams, the GGPB code underestimated the lung dose and overestimated the dose in water close to the lung, compared to the congruent eMC and MC results. In the anthropomorphic phantom, results of TLD measurements and MC and eMC calculations agreed, while the GGPB code underestimated the lung dose. Good agreement between TLD measurements and MC calculations attests to the accuracy of “full” MC simulations as a reference for benchmarking TPS codes. Application of the GGPB code in chest wall radiotherapy may result in significant underestimation of the lung dose and overestimation of dose to the mediastinum, affecting plan optimization over volumes close to the lung–mediastinum interface, such as the lung or heart.
ISSN:1120-1797
1724-191X
DOI:10.1016/j.ejmp.2013.04.004