SU‐E‐T‐47: Application of the Repair‐Misrepair‐Fixation RBE Model to Describe the Results of High Resolution Proton Irradiation Cell Survival Experiments

Abstract

Purpose:To develop a system to rapidly and accurately calculate RBE with the repair‐misrepair‐fixation (RMF) model for proton therapy data sets and to evaluate its effectiveness in modeling RBE for cell survival experiments performed with the H460 cell line for a range of proton LET.Methods:A system for using the Monte Carlo Damage Simulation (MCDS) software with high performance computing was developed. Input for the MCDS software for a range of proton energies in increments of 0.1 MeV was generated and simulated. The output data were then used to determine doseaveraged quantities for the RMF model based on equivalently binned proton energy spectra. The method was applied to calculate RBE at 50% survival for experimental cell survival data. Experimental data were obtained using a system which allowed for the accumulation of cell survival data at known values of dose‐averaged proton LETs at a range of doses. RBE was calculated based directly on a Cs‐137 reference experiment and, additionally, according to fitted values of the θ and κ terms of the RMF model.Results:Dose‐averaged RMF model quantities were calculated using the HPC system. Compared to experimental RBE determined using a Cs‐137 irradiation as a reference, the RBE from the model differed by at most 49%. RBE based on the fitted values of θ and κ differed by at most 18% for the highest LET.Conclusion:A system for rapidly generating data necessary to calculate RBE with the RMF model has been developed. For the H460 cell line, the RMF model could not reproduce the experimentally determined RBE based solely on the photon reference data. Fitting of the θ and κ terms of the RMF model indicates that their values increase for proton LET exceeding approximately 10 keV/µm.NIH Program Project Grant P01CA021239