Affiliation:
1. Helmholtz‐Zentrum Dresden‐Rossendorf Institute of Radiooncology‐OncoRay Dresden Germany
2. Centre for Medical Radiation Physics University of Wollongong Wollongong New South Wales Australia
3. Illawarra Cancer Care Centre Wollongong New South Wales Australia
4. OncoRay ‐ National Center for Radiation Research in Oncology Faculty of Medicine and University Hospital Carl Gustav Carus at the Technische Universität Dresden Helmholtz‐Zentrum Dresden‐Rossendorf Dresden Germany
5. Ion Beam Applications SA Louvain‐la‐Neuve Belgium
6. Department of Radiotherapy and Radiation Oncology Faculty of Medicine and University Hospital Carl Gustav Carus at the Technische Universität Dresden Dresden Germany
Abstract
AbstractBackgroundMR‐integrated proton therapy is under development. It consists of the unique challenge of integrating a proton pencil beam scanning (PBS) beam line nozzle with an magnetic resonance imaging (MRI) scanner. The magnetic interaction between these two components is deemed high risk as the MR images can be degraded if there is cross‐talk during beam delivery and image acquisition.PurposeTo create and benchmark a self‐consistent proton PBS nozzle model for empowering the next stages of MR‐integrated proton therapy development, namely exploring and de‐risking complete integrated prototype system designs including magnetic shielding of the PBS nozzle.Materials and MethodsMagnetic field (COMSOL ) and radiation transport (Geant4) models of a proton PBS nozzle located at OncoRay (Dresden, Germany) were developed according to the manufacturers specifications. Geant4 simulations of the PBS process were performed by using magnetic field data generated by the COMSOL simulations. In total 315 spots were simulated which consisted of a scan pattern with 5 cm spot spacings and for proton energies of 70, 100, 150, 200, and 220 MeV. Analysis of the simulated deflection at the beam isocenter plane was performed to determine the self‐consistency of the model. The magnetic fringe field from a sub selection of 24 of the 315 spot simulations were directly compared with high precision magnetometer measurements. These focused on the maximum scanning setting of 20 cm beam deflection as generated from the second scanning magnet in the PBS for a proton beam energy of 220 MeV. Locations along the beam line central axis (CAX) were measured at beam isocenter and downstream of 22, 47, 72, 97, and 122 cm. Horizontal off‐axis positions were measured at 22 cm downstream of isocenter ( 50, 100, and 150 cm from CAX).ResultsThe proton PBS simulations had good spatial agreement to the theoretical values in all 315 spots examined at the beam line isocenter plane (0–2.9 mm differences or within 1.5 % of the local spot deflection amount). Careful analysis of the experimental measurements were able to isolate the changes in magnetic fields due solely to the scanning magnet contribution, and showed 1.9 1.2 –9.4 1.2 changes over the range of measurement locations. Direct comparison with the equivalent simulations matched within the measurement apparatus and setup uncertainty in all but one measurement point.ConclusionsFor the first time a robust, accurate and self‐consistent model of a proton PBS nozzle assembly has been created and successfully benchmarked for the purposes of advancing MR‐integrated proton therapy research. The model will enable confidence in further simulation based work on fully integrated designs including MRI scanners and PBS nozzle magnetic shielding in order to de‐risk and realize the full potential of MR‐integrated proton therapy.