Quantitative real-time measurements of dose and dose rate in UHDR proton pencil beams via scintillation imaging system

TL;DR

This study demonstrates that ultra-fast scintillation imaging can accurately measure complex dose and dose rate maps in ultra-high dose rate proton beams, offering high spatial and temporal resolution for beam characterization.

Contribution

The paper introduces a novel ultra-fast scintillation imaging system for real-time, high-resolution dosimetry in UHDR proton beams, validated against standard detectors and simulations.

Findings

Camera response is highly linear with dose and current.

High spatial and temporal resolution measurements match standard detectors.

The system effectively characterizes complex dose rate distributions.

Abstract

Purpose: Ultra-fast scintillation imaging has been shown to provide a unique tool for spatio-temporal dosimetry of conventional cyclotron and synchrocyclotron pencil beam scanning (PBS) deliveries, indicating the potential use for characterization of ultra-UHDR PBS proton beams. The goal of this work is to introduce this novel concept and demonstrate its capabilities in recording complex dose rate maps at FLASH-capable proton beam currents, as compared to log-based dose rate calculation, internally developed UHDR beam simulation, and a fast point detector (EDGE diode). Methods: The light response of a scintillator sheet located at isocenter and irradiated by pencil beam scanning proton fields (40-210 nA, 250 MeV) was imaged by an ultra-fast iCMOS camera at 4.5-12 kHz sampling frequency. Image intensity was calibrated to dose with film and the recorded spatio-temporal data was compared to a PPC05 ion chamber, log-based reconstruction, and EDGE diode. Calculation of full-field mean and PBS dose rate maps were used to highlight the importance of high resolution, full-field information in UHDR studies. Results: Camera response was linear with dose (R2 = 0.997) and current (R2 = 0.98) in the range from 2-22 Gy and 40-210 nA, respectively, when compared to ion chamber readings. Planned and delivered spot positions agreed within 0.2+/-0.1 mm and total irradiation time agreed within 0.2+/-0.2 ms when compared with the log files, indicating the high concurrent spatial and temporal resolution. For all deliveries, the PBS dose rate measured at the diode location agreed between the imaging and the diode within 3+/-2% and with the simulation within 5+/-3%. Conclusion: The high linearity and various spatiotemporal metric reporting capabilities confirm the continued use of this camera system for UHDR beam characterization, especially for spatially resolved dose rate information.