Litcius/Paper detail

Ultra-high dose rate dosimetry for pre-clinical experiments with mm-small proton fields

Michele Togno, Konrad P. Nesteruk, Robert Schäfer, S. Psoroulas, D. Meer, Martin Großmann, Jeppe Brage Christensen, E.G. Yukihara, Antony Lomax, Damien C. Weber, Sairos Safai

2022Physica Medica29 citationsDOIOpen Access PDF

Abstract

PURPOSE: To characterize an experimental setup for ultra-high dose rate (UHDR) proton irradiations, and to address the challenges of dosimetry in millimetre-small pencil proton beams. METHODS: At the PSI Gantry 1, high-energy transmission pencil beams can be delivered to biological samples and detectors up to a maximum local dose rate of ∼9000 Gy/s. In the presented setup, a Faraday cup is used to measure the delivered number of protons up to ultra-high dose rates. The response of transmission ion-chambers, as well as of different field detectors, was characterized over a wide range of dose rates using the Faraday cup as reference. RESULTS: :C optically stimulated luminescence detectors and a PTW microDiamond were used to validate the predicted dose. Transmission ionization chambers showed significant volume ion-recombination (>30 % in the tested conditions) which can be parametrized as a function of the maximum proton current density. Over the considered range, EBT3 films, inorganic scintillator-based screens and the PTW microDiamond were demonstrated to be dose rate independent within ±3 %, ±1.8 % and ±1 %, respectively. CONCLUSIONS: Faraday cups are versatile dosimetry instruments that can be used for dose estimation, field detector characterization and on-line dose verification for pre-clinical experiments in UHDR proton pencil beams. Among the tested detectors, the commercial PTW microDiamond was found to be a suitable option to measure real time the dosimetric properties of narrow pencil proton beams for dose rates up to 2.2 kGy/s.

Topics & Concepts

DosimetryFaraday cupProton therapyPencil (optics)Ionization chamberProtonDose profileDetectorPencil-beam scanningMaterials scienceScintillatorOpticsIonizationNuclear medicineIonPhysicsNuclear physicsBeam (structure)Ion beamMedicineQuantum mechanicsRadiation Therapy and DosimetryAdvanced Radiotherapy TechniquesRadiation Effects in Electronics