Rapid and reversible adaptation of a clinical linear accelerator for electron FLASH radiotherapy

IF 2.7 3区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Physica Medica-European Journal of Medical Physics Pub Date : 2025-06-23 DOI:10.1016/j.ejmp.2025.105032

Frank Schneider , Cornelius J. Bauer , Ida D. Göbel , Clarence King , Maria Francesca Spadea , Joao Seco , Frank A. Giordano , Jens Fleckenstein

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引用次数: 0

Abstract

Purpose

The aim of this work was to establish a procedure that allows the conversion of a standard clinical LINAC into a “FLASH” LINAC capable of delivering ultra-high dose rates above 40 Gy/s, with minimal, fully reversible modifications to the device. A dosimetric characterization of the resulting treatment beam is presented.

Methods

A LINAC was modified to emit a 10 MeV electron FLASH beam. Modifications included the integration of a pulse control unit which consisted out of a scintillation detector and a transistor circuit. Beam parameters were optimized to maximize dose output. Beam characterization measurements were performed with different detectors in water: ionization chamber, diamond detector, radiographic films and scintillation detector. The resulting doses per pulse (DPP) and dose rates at different source-surface-distances (SSD) as well as the output reproducibility were determined. The beam was characterized with depth dose curves and lateral profiles.

Results

Conversion of a LINAC to FLASH mode was feasible in less than 30 min. Output was between DPP_SSD=56cm = 1.69 ± 0.02 Gy and DPP_SSD=100cm = 0.53 ± 0.01 Gy or dose rates between 676 ± 8 Gy/s and 213 ± 4 Gy/s. Reproducibility of DPP was better than 0.8 %. FLASH depth dose curves showed a higher range (R80 = 39.8 mm vs. 34.6 mm) and lateral beam profiles had a reduced flatness (from 5.5 % to 12.7 %) at SSD = 56 cm.

Conclusion

We present a fully reversible conversion method requiring minimal modifications to a LINAC to produce electron FLASH beams. The achieved DPP and mean dose rates demonstrated high reproducibility, meeting criteria for FLASH applications, and markedly simplifying access to this technology for broader implementation.

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快速和可逆适应临床直线加速器的电子闪光放疗

这项工作的目的是建立一个程序，允许将标准的临床LINAC转换为能够提供超过40 Gy/s的超高剂量率的“FLASH”LINAC，对设备进行最小的，完全可逆的修改。提出了所产生的处理光束的剂量学特性。方法对LINAC进行修饰，使其能发射出10mev的电子闪光束。修改包括集成脉冲控制单元，该单元由闪烁探测器和晶体管电路组成。优化光束参数以最大剂量输出。在水中用离子化室、金刚石探测器、射线底片和闪烁探测器进行了光束表征测量。测定了不同源-表面距离下的单脉冲剂量（DPP）和剂量率以及输出的可重复性。用深度、剂量曲线和横向分布曲线对光束进行了表征。结果LINAC可在30 min内转换为FLASH模式，输出在DPPSSD=56cm = 1.69±0.02 Gy和DPPSSD=100cm = 0.53±0.01 Gy之间，剂量率在676±8 Gy/s和213±4 Gy/s之间。DPP的重现性优于0.8%。FLASH深度剂量曲线显示出更高的范围（R80 = 39.8 mm vs. 34.6 mm），并且在SSD = 56 cm时，侧束剖面的平坦度降低（从5.5%降至12.7%）。结论我们提出了一种完全可逆的转换方法，只需对直线加速器进行最小的修改即可产生电子闪光束。获得的DPP和平均剂量率显示出高重复性，符合FLASH应用标准，并显着简化了该技术的更广泛实施。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Physica Medica-European Journal of Medical Physics 生物-生物物理

CiteScore

6.80

自引率

14.70%

发文量

493

审稿时长

78 days

期刊介绍： Physica Medica, European Journal of Medical Physics, publishing with Elsevier from 2007, provides an international forum for research and reviews on the following main topics: Medical Imaging Radiation Therapy Radiation Protection Measuring Systems and Signal Processing Education and training in Medical Physics Professional issues in Medical Physics.