Biophysical modeling of low‐energy ion irradiations with NanOx

IF 3.2 2区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Medical physics Pub Date : 2024-09-17 DOI:10.1002/mp.17407

Mario Alcocer‐Ávila, Victor Levrague, Rachel Delorme, Étienne Testa, Michaël Beuve

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引用次数: 0

Abstract

BackgroundTargeted radiotherapies with low‐energy ions show interesting possibilities for the selective irradiation of tumor cells, a strategy particularly appropriate for the treatment of disseminated cancer. Two promising examples are boron neutron capture therapy (BNCT) and targeted radionuclide therapy with ‐particle emitters (TAT). The successful clinical translation of these radiotherapies requires the implementation of accurate radiation dosimetry approaches able to take into account the impact on treatments of the biological effectiveness of ions and the heterogeneity in the therapeutic agent distribution inside the tumor cells. To this end, biophysical models can be applied to translate the interactions of radiations with matter into biological endpoints, such as cell survival.PurposeThe NanOx model was initially developed for predicting the cell survival fractions resulting from irradiations with the high‐energy ion beams encountered in hadrontherapy. We present in this work a new implementation of the model that extends its application to irradiations with low‐energy ions, as the ones found in TAT and BNCT.MethodsThe NanOx model was adapted to consider the energy loss of primary ions within the sensitive volume (i.e., the cell nucleus). Additional assumptions were introduced to simplify the practical implementation of the model and reduce computation time. In particular, for low‐energy ions the narrow‐track approximation allowed to neglect the energy deposited by secondary electrons outside the sensitive volume, increasing significantly the performance of simulations. Calculations were performed to compare the original hadrontherapy implementation of the NanOx model with the present one in terms of the inactivation cross sections of human salivary gland cells as a function of the kinetic energy of incident ‐particles.ResultsThe predictions of the previous and current versions of NanOx agreed for incident energies higher than 1 MeV/n. For lower energies, the new NanOx implementation predicted a decrease in the inactivation cross sections that depended on the length of the sensitive volume.ConclusionsWe reported in this work an extension of the NanOx biophysical model to consider irradiations with low‐energy ions, such as the ones found in TAT and BNCT. The excellent agreement observed at intermediate and high energies between the original hadrontherapy implementation and the present one showed that NanOx offers a consistent, self‐integrated framework for describing the biological effects induced by ion irradiations. Future work will focus on the application of the latest version of NanOx to cases closer to the clinical setting.

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用纳米氧化物进行低能量离子照射的生物物理建模

背景使用低能离子的靶向放射治疗为选择性照射肿瘤细胞提供了有趣的可能性，这种策略尤其适用于治疗扩散性癌症。硼中子俘获疗法（BNCT）和使用-粒子发射体的放射性核素靶向疗法（TAT）就是两个很有前景的例子。要将这些放射疗法成功应用于临床，就必须采用精确的辐射剂量测量方法，并能考虑到离子的生物有效性和治疗剂在肿瘤细胞内分布的异质性对治疗的影响。为此，可以应用生物物理模型将辐射与物质的相互作用转化为生物终点，如细胞存活率。目的NanOx 模型最初是为预测在放射治疗中遇到的高能离子束照射所产生的细胞存活率而开发的。我们在这项工作中介绍了该模型的新实施方案，将其应用范围扩展到低能量离子的辐照，如 TAT 和 BNCT 中的低能量离子。为了简化模型的实际应用并减少计算时间，还引入了其他假设。特别是对于低能离子，窄轨道近似可以忽略敏感体积外的次级电子沉积的能量，从而大大提高了模拟的性能。在计算人类唾液腺细胞的失活截面与入射粒子动能的函数关系时，比较了最初的 NanOx 模型和现在的 NanOx 模型。对于较低的能量，新的 NanOx 实现预测的失活截面会减小，这取决于敏感体积的长度。结论我们在这项工作中报告了对 NanOx 生物物理模型的扩展，以考虑低能量离子的辐照，例如在 TAT 和 BNCT 中发现的低能量离子。在中高能量下观察到的原始哈德罗疗法实施方案与目前的实施方案之间的极佳一致性表明，NanOx 为描述离子照射引起的生物效应提供了一个一致的、自成一体的框架。未来的工作重点是将最新版本的 NanOx 应用于更接近临床的病例。

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

Medical physics 医学-核医学

CiteScore

6.80

自引率

15.80%

发文量

660

审稿时长

1.7 months

期刊介绍： Medical Physics publishes original, high impact physics, imaging science, and engineering research that advances patient diagnosis and therapy through contributions in 1) Basic science developments with high potential for clinical translation 2) Clinical applications of cutting edge engineering and physics innovations 3) Broadly applicable and innovative clinical physics developments Medical Physics is a journal of global scope and reach. By publishing in Medical Physics your research will reach an international, multidisciplinary audience including practicing medical physicists as well as physics- and engineering based translational scientists. We work closely with authors of promising articles to improve their quality.