An efficient dosimetry method with a Faraday cup for small animal, small-field proton irradiation under conventional and ultra-high dose rates

TL;DR

This paper presents a fast, cost-effective dosimetry method using a Faraday cup for small animal and potentially clinical small-field proton irradiation, effective at both conventional and ultra-high dose rates.

Contribution

The study introduces a novel calibration and monitoring technique with a Faraday cup that works across different dose rates and small field sizes in proton therapy.

Findings

Faraday cup readings accurately monitor dose and dose rate in small-field proton irradiation.

The method is independent of dose rate and applicable to small animal and clinical settings.

It offers a time-efficient, cost-effective solution for dose verification in proton therapy.

Abstract

Introduction: We developed and evaluated a method for dose calibration and monitoring under conventional and ultra-high dose rates for small animal experiments with small-field proton beams using a Faraday cup. Methods: We determined a relationship between dose and optical density (OD) of EBT-XD Gafchromic film using scanned 10x10 cm2 proton pencil beams delivered at clinical dose rates; the dose was measured with an Advanced Markus chamber. On a small animal proton irradiation platform, double-scattered pencil beams with 5 or 8 mm diameter brass collimation at conventional and ultra-high dose rates were delivered to the EBT-XD films. The proton fluence charges were collected by a Faraday cup placed downstream from the film. The average of the irradiated film ODs was related to the Faraday cup charges. A conversion from the Faraday cup charge to the average dose of the small-field proton beam was then obtained. Results: The relationship between the small-field average profile dose and Faraday cup charge was established for 10 and 15 Gy mice FLASH experiments. The film OD was found to be independent of dose rate. At small-animal treatments, the Faraday cup readings were conveniently used to QA and monitor the delivered dose and dose rates to the mice under conventional and ultra-high dose rates. Conclusion: The dose calibration and monitoring method with Faraday cup for small animal proton FLASH experiments is time-efficient and cost-effective and can be used for irradiations of various small field sizes. The same approach can also be adopted for clinical proton dosimetry for small-field irradiations.