Microbeam radiation therapy for lung cancer: a review of experimental setups and biological endpoints in preclinical studies.

International journal of radiation biology Pub Date : 2025-01-01 Epub Date: 2025-03-06 DOI:10.1080/09553002.2025.2473981

Abbie Reynolds, Laure Marignol

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Abstract

Background: Microbeam radiation therapy (MRT) seeks to improve the therapeutic ratio of conventional radiation therapy though the delivery of high doses in micrometre-scale beamlets of synchrotron-generated X-rays.

Purpose: To assess the MRT experimental setups and biological endpoints used in preclinical studies investigating its therapeutic potential in lung cancer models.

Methodology: PubMed, Embase, Science Direct, and Web of Science were searched using the following keywords, 'microbeam', 'micro beam', 'synchrotron' and 'lung'. The reported physical parameters of the MRT set up and biological endpoints chosen to test efficacy were examined.

Main findings: Fourteen studies were assessed. The microbeam widths ranged from 25 µm to 630 µm, and the microbeam spacing ranged from 0 µm to 4000 µm. The peak doses ranged up to 1000 Gy and dose rates ranged from 4 Gy/s to 1.4x10⁴ Gy/s. Fibrosis was the most commonly assessed radiation-induced toxicity.

Conclusion: MRT experimental set ups and biological endpoints are heterogeneous. Standardization could strengthen future evidence supporting its use for the management of patients with lung cancer.

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肺癌的微束放射治疗：临床前研究的实验设置和生物学终点的综述。

背景：微束放射治疗（MRT）旨在提高传统放射治疗的治疗率，通过递送高剂量的微米级同步加速器产生的x射线束。目的：评估MRT实验设置和临床前研究中使用的生物学终点，研究其在肺癌模型中的治疗潜力。方法：PubMed， Embase， Science Direct和Web of Science使用以下关键词进行搜索，“微束”，“微束”，“同步加速器”和“肺”。报告的MRT设置的物理参数和选择的生物学终点来检验疗效。主要发现：14项研究被评估。微束宽度为25µm ~ 630µm，微束间距为0µm ~ 4000µm。峰值剂量可达1000戈瑞，剂量率从4戈瑞/秒到1.4 × 104戈瑞/秒不等。纤维化是最常见的辐射毒性评估。结论：MRT实验设置和生物学终点具有异质性。标准化可以加强未来支持其用于肺癌患者管理的证据。

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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International journal of radiation biology

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