Single-pulse Gy-scale irradiation of biological cells at average dose-rates above $10^{13}$ Gy/s from a laser-wakefield accelerator

arXiv - PHYS - Plasma Physics Pub Date : 2024-09-03 DOI:arxiv-2409.01717

C. A. McAnespie, P. Chaudhary, M. J. V. Streeter, S. W. Botchway, N. Bourgeois, L. Calvin, N. Cavanagh, K. Fleck, D. Jaroszynski, B. Kettle, A. M. Lupu, S. P. D. Mangles, S. J. McMahon, J. Mill, S. R. Needham, P. P. Rajeev, K. M. Prise, G. Sarri

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Abstract

We report on the first experimental characterization of a laser-wakefield accelerator able to deliver, in a single pulse, doses in excess of 1 Gy on timescales of the order of tens of femtoseconds, reaching unprecedented average dose-rates above $10^{13}$ Gy/s. The irradiator is demonstrated to deliver doses tuneable up to 2.2 Gy in a cm$^2$ area and with a high degree of longitudinal and transverse uniformity in a single irradiation. In this regime, proof-of-principle irradiation of patient-derived glioblastoma stem-like cells and human skin fibroblast cells show indications of a differential cellular response, when compared to reference irradiations at conventional dose-rates. These include a statistically significant increase in relative biological effectiveness ($1.40\pm0.08$ at 50\% survival for both cell lines) and a significant reduction of the relative radioresistance of tumour cells. Data analysis provides preliminary indications that these effects might not be fully explained by induced oxygen depletion in the cells but may be instead linked to a higher complexity of the damages triggered by the ultra-high density of ionising tracks of femtosecond-scale radiation pulses. These results demonstrate an integrated platform for systematic radiobiological studies at unprecedented beam durations and dose-rates, a unique infrastructure for translational research in radiobiology at the femtosecond scale.

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激光辐照加速器以高于 10^{13}$ Gy/s 的平均剂量率对生物细胞进行单脉冲 Gy 级辐照

我们首次报道了激光渚射加速器的实验特性，该加速器能够在单脉冲中以数十飞秒的时间尺度输出超过 1 Gy 的剂量，达到前所未有的平均剂量率，超过 10^{13}$ Gy/s。该辐照装置可在厘米^$^2$的面积内提供高达 2.2 Gy 的剂量，并且在单次辐照中具有高度的纵向和横向均匀性。在这一系统中，对源自患者的胶质母细胞瘤干样细胞和人类皮肤成纤维细胞进行的原理性辐照显示，与常规剂量率的参考辐照相比，细胞反应有所不同。数据分析提供的初步迹象表明，这些效应可能无法完全用诱导细胞缺氧来解释，而可能与飞秒级辐射脉冲的超高密度电离轨道引发的更高复杂性损伤有关。这些结果展示了一个在前所未有的光束持续时间和剂量率条件下进行系统放射生物学研究的集成平台，这是飞秒尺度放射生物学研究的独特基础设施。

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arXiv - PHYS - Plasma Physics

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