Mini-GRID therapy delivers optimised spatially fractionated radiation therapy using a flattening free filter accelerator.

IF 5.4 Q1 MEDICINE, RESEARCH & EXPERIMENTAL Communications medicine Pub Date : 2025-04-05 DOI:10.1038/s43856-025-00809-7

M Isabel Acuña, Charlotte Lamirault, Thibaut Larcher, Elise Brisebard, Tim Schneider, Marjorie Juchaux, Ramon Iglesias-Rey, Sabela Fernández-Rodicio, Pablo Aguiar, Noemi Gómez-Lado, Immaculada Martínez-Rovira, Roberto González-Vegas, Ibraheem Yousef, Antonio Gomez-Caamano, Miguel Pombar, Victor Luna, Manuel Sanchez, Yolanda Prezado

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Abstract

Background: Radioresistant tumours remain a challenge for conventional radiation therapy (RT), and often, only palliative treatment can be offered. Recently developed techniques, such as spatially fractionated radiation therapy (SFRT) could potentially improve treatment. However, current clinical SFRT implementations do not allow the full potential to be exploited. We further optimize SFRT, developing mini-GRID, which uses a flattening free filter accelerator.

Methods: The increase in normal tissue tolerances provided by mini-GRID compared to conventional RT and GRID therapy was validated in a rat model of brain irradiation in a longitudinal imaging study, behavioural tests and by histopathological evaluation.

Results: The implementation optimizes mini-GRID therapy, with beam widths around 2 mm². The peak-to-valley dose ratios and peak dose rates are around 4 and 7 Gy/min, respectively. Mini-GRID RT allows the use of high peak doses: 42 Gy in one fraction, a factor more than twice higher than the peak doses generally employed in conventional GRID therapy (20 Gy peak dose). This enables the use of more aggressive and potentially curative treatments. Infrared microspectroscopy analysis suggests different early biochemical changes in both modalities, with conventional RT leading to stronger modifications in the secondary protein structure, and higher oxidative damage than mini-GRID RT.

Conclusions: The possibility to treat both large and small tumours, and to perform safe and potentially curative dose escalations in previously untreatable cases, makes mini-GRID a promising approach to expand the clinical use of SFRT.

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Mini-GRID治疗提供优化的空间分割放射治疗，使用平坦的自由过滤器加速器。

背景：放射耐药肿瘤仍然是传统放射治疗（RT）的一个挑战，通常只能提供姑息性治疗。最近开发的技术，如空间分割放射治疗（SFRT）可能会改善治疗。然而，目前的临床SFRT实施并没有充分发挥其潜力。我们进一步优化了SFRT，开发了mini-GRID，它使用了一个无平坦滤波加速器。方法：通过纵向成像研究、行为测试和组织病理学评估，在大鼠脑辐照模型中证实，与传统RT和GRID治疗相比，mini-GRID提供的正常组织耐受性增加。结果：该方法优化了mini-GRID治疗，束宽约为2 mm2。峰谷剂量比和峰剂量率分别约为4 Gy/min和7 Gy/min。Mini-GRID RT允许使用高峰值剂量：在一个部分中使用42 Gy，比传统GRID治疗中通常使用的峰值剂量（20 Gy峰值剂量）高出两倍多。这使得使用更积极和可能治愈的治疗成为可能。红外微光谱分析表明，两种方式的早期生化变化不同，常规RT导致二级蛋白结构发生更强的改变，氧化损伤比mini-GRID RT更高。结论：mini-GRID可以治疗大小肿瘤，并且在以前无法治疗的病例中进行安全且潜在的治愈剂量升级，这使得mini-GRID成为扩大SFRT临床应用的有希望的方法。

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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Communications medicine

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