Improved dose-calculation accuracy in proton treatment planning using a simplified Monte Carlo method verified with three-dimensional measurements in an anthropomorphic phantom

Treatment planning for proton tumor therapy requires a fast and accurate dose-calculation method. We have implemented a simplified Monte Carlo (SMC) method in the treatment planning system of the National Cancer Center Hospital East for the double-scattering beam delivery scheme. The SMC method take...

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Veröffentlicht in:	Physics in medicine & biology 2010-06, Vol.55 (12), p.3545-3556
Hauptverfasser:	Hotta, Kenji, Kohno, Ryosuke, Takada, Yoshihisa, Hara, Yousuke, Tansho, Ryohei, Himukai, Takeshi, Kameoka, Satoru, Matsuura, Taeko, Nishio, Teiji, Ogino, Takashi
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Sprache:	eng
Schlagworte:	Humans Monte Carlo Method Phantoms, Imaging Protons - therapeutic use Radiometry - instrumentation Radiotherapy Planning, Computer-Assisted - instrumentation
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creator	Hotta, Kenji Kohno, Ryosuke Takada, Yoshihisa Hara, Yousuke Tansho, Ryohei Himukai, Takeshi Kameoka, Satoru Matsuura, Taeko Nishio, Teiji Ogino, Takashi
description	Treatment planning for proton tumor therapy requires a fast and accurate dose-calculation method. We have implemented a simplified Monte Carlo (SMC) method in the treatment planning system of the National Cancer Center Hospital East for the double-scattering beam delivery scheme. The SMC method takes into account the scattering effect in materials more accurately than the pencil beam algorithm by tracking individual proton paths. We confirmed that the SMC method reproduced measured dose distributions in a heterogeneous slab phantom better than the pencil beam method. When applied to a complex anthropomorphic phantom, the SMC method reproduced the measured dose distribution well, satisfying an accuracy tolerance of 3 mm and 3% in the gamma index analysis. The SMC method required approximately 30 min to complete the calculation over a target volume of 500 cc, much less than the time required for the full Monte Carlo calculation. The SMC method is a candidate for a practical calculation technique with sufficient accuracy for clinical application.
doi_str_mv	10.1088/0031-9155/55/12/018
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We have implemented a simplified Monte Carlo (SMC) method in the treatment planning system of the National Cancer Center Hospital East for the double-scattering beam delivery scheme. The SMC method takes into account the scattering effect in materials more accurately than the pencil beam algorithm by tracking individual proton paths. We confirmed that the SMC method reproduced measured dose distributions in a heterogeneous slab phantom better than the pencil beam method. When applied to a complex anthropomorphic phantom, the SMC method reproduced the measured dose distribution well, satisfying an accuracy tolerance of 3 mm and 3% in the gamma index analysis. The SMC method required approximately 30 min to complete the calculation over a target volume of 500 cc, much less than the time required for the full Monte Carlo calculation. 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source	MEDLINE; IOP Publishing Journals; Institute of Physics (IOP) Journals - HEAL-Link
subjects	Humans Monte Carlo Method Phantoms, Imaging Protons - therapeutic use Radiometry - instrumentation Radiotherapy Planning, Computer-Assisted - instrumentation
title	Improved dose-calculation accuracy in proton treatment planning using a simplified Monte Carlo method verified with three-dimensional measurements in an anthropomorphic phantom
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