Diamond-based Detection Systems for Accurate Pulsed X-rays Diagnostics in Radiotherapy

TL;DR

This paper presents a diamond-based dosimeter system with compact electronics for real-time, accurate pulsed X-ray diagnostics in radiotherapy, demonstrating high stability and precise dose measurements at high doses and various energies.

Contribution

It introduces a novel, compact diamond dosimeter with integrated electronics capable of real-time, high-precision pulsed X-ray detection in radiotherapy settings.

Findings

Accurate dose measurements at 6 MV and 18 MV LINACs.

Real-time monitoring with 20 us sampling period.

High stability even at 100 Gy absorbed dose.

Abstract

The widespread diffusion of precision radiotherapy techniques, geared toward the release of larger dose gradients in shorter time frames, is leading to new challenges in dosimetry. Accurate dose measurements are essential to check for beam anomalies and inaccuracies to ensure treatment efficacy and patient safety during radiotherapy. This work describes the main features of a diamond dosimeter coupled to an extremely compact front-end electronics. The detection system was tested under the X-ray pulses generated by a medical LINAC for both the 6 MV and the 18 MV accelerating voltages. Located in the LINAC's bunker, it eliminates the need for a long cable connection between the detector and the electronics, detrimental for the system response speed. Signal acquisition was performed synchronously with the impinging X-ray pulses with a sampling period as low as 20 us, allowing for a real-time beam monitoring. The dosimeter demonstrated a very good stability despite the high value of the absorbed dose during the performed experiments (about 100 Gy). The measured dose-per-pulse values of 278 uGy and 556 uGy at 6 MV and 18 MV, respectively, are in excellent agreement with the nominal values expected for the LINAC apparatus used for the tests. In addition to single-pulse measurements, fundamental for dynamic radiotherapy, the proposed system also allows for the calculation of both the total collected charge and the photocurrent generated by the detector. In this regards, despite the compactness, it demonstrates its effectiveness as a tool for source diagnostics in terms of both beam intensity and emission timing.