E Nobakht1, N Fouladi1. 1. Department of Nuclear Physics, University of Tabriz, Tabriz 51664, Iran.
Abstract
AIM: The feasibility of using 230 MeV proton cyclotrons in proton therapy centers as a spallation neutron source for Boron Neutron Capture Therapy (BNCT) was investigated. BACKGROUND: BNCT is based on the neutron irradiation of a 10B-containing compound located selectively in tumor cells. Among various types of neutron generators, the spallation neutron source is a unique way to generate high-energy and high-flux neutrons. MATERIALS AND METHODS: Neutron beam was generated by a proton accelerator via spallation reactions and then the produced neutron beam was shaped to be appropriate for BNCT. The proposed Beam Shaping Assembly (BSA) consists of different moderators, a reflector, a collimator, as well as thermal and gamma filters. In addition, the simulated Snyder head phantom was utilized to evaluate the dose distribution in tumor and normal tissue due to the irradiation by the designed beam. MCNPX2.6 Monte Carlo code was used to optimize BSA as well as evaluate dose evaluation. RESULTS: A BSA was designed. With the BSA configuration and a beam current of 104 nA, epithermal neutron flux of 3.94 × 106 [n/cm2] can be achieved, which is very low. Provided that we use the beam current of 5.75 μA, epithermal neutron flux of 2.18 × 108 [n/cm2] can be obtained and the maximum dose of 38.2 Gy-eq can be delivered to tumor tissue at 1.4 cm from the phantom surface. CONCLUSIONS: Results for 230 MeV protons show that with proposed BSA, proton beam current about 5.75 μA is required for this purpose.
AIM: The feasibility of using 230 MeV proton cyclotrons in proton therapy centers as a spallation neutron source for Boron Neutron Capture Therapy (BNCT) was investigated. BACKGROUND: BNCT is based on the neutron irradiation of a 10B-containing compound located selectively in tumor cells. Among various types of neutron generators, the spallation neutron source is a unique way to generate high-energy and high-flux neutrons. MATERIALS AND METHODS: Neutron beam was generated by a proton accelerator via spallation reactions and then the produced neutron beam was shaped to be appropriate for BNCT. The proposed Beam Shaping Assembly (BSA) consists of different moderators, a reflector, a collimator, as well as thermal and gamma filters. In addition, the simulated Snyder head phantom was utilized to evaluate the dose distribution in tumor and normal tissue due to the irradiation by the designed beam. MCNPX2.6 Monte Carlo code was used to optimize BSA as well as evaluate dose evaluation. RESULTS: A BSA was designed. With the BSA configuration and a beam current of 104 nA, epithermal neutron flux of 3.94 × 106 [n/cm2] can be achieved, which is very low. Provided that we use the beam current of 5.75 μA, epithermal neutron flux of 2.18 × 108 [n/cm2] can be obtained and the maximum dose of 38.2 Gy-eq can be delivered to tumor tissue at 1.4 cm from the phantom surface. CONCLUSIONS: Results for 230 MeV protons show that with proposed BSA, proton beam current about 5.75 μA is required for this purpose.
Authors: O E Kononov; V N Kononov; M V Bokhovko; V V Korobeynikov; A N Soloviev; A S Sysoev; I A Gulidov; W T Chu; D W Nigg Journal: Appl Radiat Isot Date: 2004-11 Impact factor: 1.513
Authors: Verónica Andrea Trivillin; Ayelén Serrano; Marcela A Garabalino; Lucas Luis Colombo; Emiliano César Pozzi; Andrea Monti Hughes; Paula M Curotto; Silvia Inés Thorp; Ruben O Farías; Sara J González; Silva Bortolussi; Saverio Altieri; Maria E Itoiz; Romina F Aromando; David W Nigg; Amanda E Schwint Journal: Int J Radiat Biol Date: 2019-02-22 Impact factor: 2.694
Authors: Peter J Binns; Kent J Riley; Yakov Ostrovsky; Wei Gao; J Raymond Albritton; W S Kiger; Otto K Harling Journal: Int J Radiat Oncol Biol Phys Date: 2007-04-01 Impact factor: 7.038