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广义随机微剂量模型:主要公式。

Generalized stochastic microdosimetric model: The main formulation.

机构信息

Department of Computer Science, University of Verona, Verona, Italy and TIFPA-INFN, Trento, Italy.

Department of Physics, University of Trento, Trento, Italy and TIFPA-INFN, Trento, Italy.

出版信息

Phys Rev E. 2021 Jan;103(1-1):012412. doi: 10.1103/PhysRevE.103.012412.

DOI:10.1103/PhysRevE.103.012412
PMID:33601636
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7975068/
Abstract

The present work introduces a rigorous stochastic model, called the generalized stochastic microdosimetric model (GSM^{2}), to describe biological damage induced by ionizing radiation. Starting from the microdosimetric spectra of energy deposition in tissue, we derive a master equation describing the time evolution of the probability density function of lethal and potentially lethal DNA damage induced by a given radiation to a cell nucleus. The resulting probability distribution is not required to satisfy any a priori conditions. After the initial assumption of instantaneous irradiation, we generalized the master equation to consider damage induced by a continuous dose delivery. In addition, spatial features and damage movement inside the nucleus have been taken into account. In doing so, we provide a general mathematical setting to fully describe the spatiotemporal damage formation and evolution in a cell nucleus. Finally, we provide numerical solutions of the master equation exploiting Monte Carlo simulations to validate the accuracy of GSM^{2}. Development of GSM^{2} can lead to improved modeling of radiation damage to both tumor and normal tissues, and thereby impact treatment regimens for better tumor control and reduced normal tissue toxicities.

摘要

本工作引入了一个严格的随机模型,称为广义随机微剂量模型(GSM^2),以描述电离辐射引起的生物损伤。从组织中能量沉积的微剂量谱出发,我们推导出一个描述由给定辐射引起的细胞内致死和潜在致死 DNA 损伤的概率密度函数随时间演化的主方程。得到的概率分布不需要满足任何先验条件。在最初假设瞬时辐照之后,我们将主方程推广到考虑连续剂量传递引起的损伤。此外,还考虑了核内的空间特征和损伤运动。通过这样做,我们提供了一个通用的数学框架来完全描述细胞核内的时空损伤形成和演化。最后,我们利用蒙特卡罗模拟求解主方程的数值解,以验证 GSM^2 的准确性。GSM^2 的发展可以导致对肿瘤和正常组织的辐射损伤进行更好的建模,从而影响治疗方案,以更好地控制肿瘤和降低正常组织毒性。

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