SU‐E‐T‐502: In Search of the Optimum Ion for Radiotherapy

Purpose: To investigate the physical and biological properties and the clinical potential of several different ions through computer simulations. Methods: Using the Geant4 Monte Carlo toolkit, we calculated spatial dose and LET distributions in a water phantom for monoenergetic beams for four candidate ions with the same range (28 cm in water): 207 MeV/u protons, 244 MeV/u 3 He ions, 206 MeV/u 4 He ions, and 400 MeV/u 12 C ions. An ideal broad beam of 6 cm in diameter was used in the simulations. The scoring voxel volume was set to 1 cubic millimeter. We also recorded the dose contributions from several major nuclear fragments. Furthermore, data for a 5‐cm RBE‐weighted dose SOBP for 12 C ions with a range of 30 cm were analyzed. Results: Simulation results showed advantages and disadvantages of each ion. For instance, a 12 C ion beam produces the sharpest and narrowest Bragg peak, and the smallest penumbra, but it has the highest entrance to peak dose ratio, and highest and longest nuclear fragmentation tail. Furthermore, the lateral dose halo effect of 12 C is substantially greater than other ions. For the same range in water, 3 He and 4 He ions show very similar features. They have smaller lateral penumbrae than protons, and much smaller fragmentation tails compared with 12 C ions. Although protons have the largest lateral penumbra and widest Bragg peak, they do not have an observable fragmentation tail. For a pristine beam of 400 MeV/u 12 C ions, the fragmentation tail dose is 15% of the peak dose. In the case of 5‐cm SOBP with 30‐cm range of 12 C ions, the fragmentation tail dose can be as high as 30% of the maximum dose. Conclusion: Each type of ion has special advantages and disadvantages. Further research is needed to consider additional factors such as energy dependence, cost effectiveness and RBE. NCI grant P01CA021239