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Realization of Dose Verification Tool for IMRT Plan Based On DPM

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Jinfeng CAI1,2 Hui LIN1 Ruifen CAO1,2 Yumei DAI1Xi PEI1Jun ZHANG3 , Liqin HU1,3, FDS Team 1. Institute of Nuclear Energy Safety Technology, Chinese Academy of Sciences, Hefei, Anhui, 230031, China 2.School of Electronic Science & Application Physics, Hefei University of Technology,Hefei,Anhui,230009,China; 3. University of Science and Technology of China, Hefei, Anhui, 230027, China

Presentations

SU-E-T-278 Sunday 3:00PM - 6:00PM Room: Exhibit Hall

Purpose:To build a Monte Carlo dose verification tool for IMRT Plan by implementing a irradiation source model into DPM code.Extend the ability of DPM to calculate any incident angles and irregular-inhomogeneous fields.
Methods:With the virtual source and the energy spectrum which unfolded from the accelerator measurement data,combined with optimized intensity maps to calculate the dose distribution of the irradiation irregular-inhomogeneous field. The irradiation source model of accelerator was substituted by a grid-based surface source. The contour and the intensity distribution of the surface source were optimized by ARTS (Accurate/Advanced Radiotherapy System)optimization module based on the tumor configuration. The weight of the emitter was decided by the grid intensity.The direction of the emitter was decided by the combination of the virtual source and the emitter emitting position.The photon energy spectrum unfolded from the accelerator measurement data was adjusted by compensating the contaminated electron source.For verification, measured data and realistic clinical IMRT plan were compared with DPM dose calculation.
Results:The regular field was verified by comparing with the measured data.It was illustrated that the differences were acceptable (<2% inside the field, 2-3mm in the penumbra).The dose calculation of irregular field by DPM simulation was also compared with that of FSPB (Finite Size Pencil Beam)and the passing rate of gamma analysis was 95.1% for peripheral lung cancer.The regular field and the irregular rotational field were all within the range of permitting error.The computing time of regular fields were less than 2h, and the test of peripheral lung cancer was 160min.Through parallel processing,the adapted DPM could complete the calculation of IMRT plan within half an hour.
Conclusion:The adapted parallelized DPM code with irradiation source model is faster than classic Monte Carlo codes.Its computational accuracy and speed satisfy the clinical requirement,and it is expectable to be a Monte Carlo dose verification tool for IMRT Plan.

Funding Support, Disclosures, and Conflict of Interest: Strategic Priority Research Program of the China Academy of Science(XDA03040000); National Natural Science Foundation of China (81101132)


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