PURPOSE: To measure the acoustic signal generated by a pulsed proton spill from a hospital-based clinical cyclotron. METHODS: An electronic function generator modulated the IBA C230 isochronous cyclotron to create a pulsed proton beam. The acoustic emissions generated by the proton beam were measured in water using a hydrophone. The acoustic measurements were repeated with increasing proton current and increasing distance between detector and beam. RESULTS: The cyclotron generated proton spills with rise times of 18 μs and a maximum measured instantaneous proton current of 790 nA. Acoustic emissions generated by the proton energy deposition were measured to be on the order of mPa. The origin of the acoustic wave was identified as the proton beam based on the correlation between acoustic emission arrival time and distance between the hydrophone and proton beam. The acoustic frequency spectrum peaked at 10 kHz, and the acoustic pressure amplitude increased monotonically with increasing proton current. CONCLUSIONS: The authors report the first observation of acoustic emissions generated by a proton beam from a hospital-based clinical cyclotron. When modulated by an electronic function generator, the cyclotron is capable of creating proton spills with fast rise times (18 μs) and high instantaneous currents (790 nA). Measurements of the proton-generated acoustic emissions in a clinical setting may provide a method for in vivo proton range verification and patient monitoring.
PURPOSE: To measure the acoustic signal generated by a pulsed proton spill from a hospital-based clinical cyclotron. METHODS: An electronic function generator modulated the IBA C230 isochronous cyclotron to create a pulsed proton beam. The acoustic emissions generated by the proton beam were measured in water using a hydrophone. The acoustic measurements were repeated with increasing proton current and increasing distance between detector and beam. RESULTS: The cyclotron generated proton spills with rise times of 18 μs and a maximum measured instantaneous proton current of 790 nA. Acoustic emissions generated by the proton energy deposition were measured to be on the order of mPa. The origin of the acoustic wave was identified as the proton beam based on the correlation between acoustic emission arrival time and distance between the hydrophone and proton beam. The acoustic frequency spectrum peaked at 10 kHz, and the acoustic pressure amplitude increased monotonically with increasing proton current. CONCLUSIONS: The authors report the first observation of acoustic emissions generated by a proton beam from a hospital-based clinical cyclotron. When modulated by an electronic function generator, the cyclotron is capable of creating proton spills with fast rise times (18 μs) and high instantaneous currents (790 nA). Measurements of the proton-generated acoustic emissions in a clinical setting may provide a method for in vivo proton range verification and patient monitoring.
Authors: Kevin C Jones; Wei Nie; James C H Chu; Julius V Turian; Alireza Kassaee; Chandra M Sehgal; Stephen Avery Journal: Phys Med Biol Date: 2018-01-11 Impact factor: 3.609
Authors: Wei Nie; Kevin C Jones; Scott Petro; Alireza Kassaee; Chandra M Sehgal; Stephen Avery Journal: Phys Med Biol Date: 2018-01-17 Impact factor: 3.609
Authors: Jerimy C Polf; Paul Maggi; Rajesh Panthi; Stephen Peterson; Dennis Mackin; Sam Beddar Journal: IEEE Trans Radiat Plasma Med Sci Date: 2021-02-05
Authors: Stephan Kellnberger; Walter Assmann; Sebastian Lehrack; Sabine Reinhardt; Peter Thirolf; Daniel Queirós; George Sergiadis; Günther Dollinger; Katia Parodi; Vasilis Ntziachristos Journal: Sci Rep Date: 2016-07-07 Impact factor: 4.379
Authors: Sina Mossahebi; Pouya Sabouri; Haijian Chen; Michelle Mundis; Matthew O'Neil; Paul Maggi; Jerimy C Polf Journal: Int J Part Ther Date: 2020-11-23