Characterization of a MLIC Detector for QA in Scanned Proton and Carbon Ion Beams

Alessandro Vai; Alfredo Mirandola; Giuseppe Magro; Davide Maestri; Edoardo Mastella; Andrea Mairani; Silvia Molinelli; Stefania Russo; Michele Togno; Sara La Civita; Mario Ciocca

doi:10.14338/IJPT-19-00064.1

Characterization of a MLIC Detector for QA in Scanned Proton and Carbon Ion Beams

Int J Part Ther. 2019 Fall;6(2):50-59. doi: 10.14338/IJPT-19-00064.1. Epub 2019 Nov 26.

Authors

Affiliations

¹ Fondazione CNAO (Italian National Center for Oncological Hadronterapy), Pavia, Italy.
² Heidelberg Ion-Beam Therapy Center, Heidelberg, Germany.
³ R&D Department, IBA Dosimetry, Schwarzenbruck, Germany.

Abstract

Purpose: Beam energy validation is a fundamental aspect of the routine quality assurance (QA) protocol of a particle therapy facility. A multilayer ionization chamber (MLIC) detector provides the optimal tradeoff between achieving accuracy in particle range determination and saving operational time in measurements and analysis procedures. We propose the characterization of a commercial MLIC as a suitable QA tool for a clinical environment with proton and carbon-ion scanning beams.

Materials and methods: Commercial MLIC Giraffe (IBA Dosimetry, Schwarzenbruck, Germany) was primarily evaluated in terms of short-term and long-term stability, linearity with dose, and dose-rate independence. Accuracy was tested by analyzing range of integrated depth-dose curves for a set of representative energies against reference acquisitions in water for proton and carbon ion beams; in addition, 2 modulated proton spread-out Bragg peaks were also measured. Possible methods to increase the native spatial resolution of the detector were also investigated.

Results: Measurements showed a high repeatability: mean relative standard deviation was within 0.5% for all channels and both particle types. The long-term stability of the gain calibration showed discrepancies less than 1% at different times. The detector response was linear with dose (R ² > 0.99) and independent on the dose rate. Measurements of integrated depth-dose curve ranges revealed a mean deviation from reference measurements in water of 0.1 ± 0.3 mm for protons with a maximum difference of 0.4 mm and 0.2 ± 0.6 mm with maximum difference of 0.85 mm for carbon ion beams. For the 2 modulated proton spread-out Bragg peaks, measured differences in distal dose falloff were ≤0.5 mm against calculated values.

Conclusions: The detector is stable, linearly responding with dose, precise, and easy to handle for QA beam energy checks of proton and carbon ion beams.

Keywords: detector; particle radiation therapy; particle range measurements; quality assurance device.