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Author(s)
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Muraro, S (Pisa U. ; INFN, Pisa) ; Battistoni, G (INFN, Milan) ; Belcari, N (Pisa U. ; INFN, Pisa) ; Bisogni, M G (Pisa U. ; INFN, Pisa) ; Camarlinghi, N (Pisa U. ; INFN, Pisa) ; Cristoforetti, L (Trento Hospital, Trento) ; Guerra, A Del (Pisa U. ; INFN, Pisa) ; Ferrari, A (CERN) ; Fracchiolla, F (Trento Hospital, Trento) ; Morrocchi, M (Pisa U. ; INFN, Pisa) ; Righetto, R (Trento Hospital, Trento) ; Sala, P (INFN, Milan) ; Schwarz, M (Trento Hospital, Trento ; TIFPA-INFN, Trento) ; Sportelli, G (Pisa U. ; INFN, Pisa) ; Topi, A (U. Siena (main) ; INFN, Siena) ; Rosso, V (Pisa U. ; INFN, Pisa) |
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Abstract
| Ion beam irradiations can deliver conformal dose distributions minimizing damage to healthy tissues thanks to their characteristic dose profiles. Nevertheless, the location of the Bragg peak can be affected by different sources of range uncertainties: a critical issue is the treatment verification. During the treatment delivery, nuclear interactions between the ions and the irradiated tissues generate β+ emitters: the detection of this activity signal can be used to perform the treatment monitoring if an expected activity distribution is available for comparison. Monte Carlo (MC) codes are widely used in the particle therapy community to evaluate the radiation transport and interaction with matter. In this work, FLUKA MC code was used to simulate the experimental conditions of irradiations performed at the Proton Therapy Center in Trento (IT). Several mono-energetic pencil beams were delivered on phantoms mimicking human tissues. The activity signals were acquired with a PET system (DoPET) based on two planar heads, and designed to be installed along the beam line to acquire data also during the irradiation. Different acquisitions are analyzed and compared with the MC predictions, with a special focus on validating the PET detectors response for activity range verification. |