The Dependence of Compensation Dose on Systematic and Random Interruption Treatment Time in Radiation Therapy

Onco Pub Date : 2022-09-05 DOI:10.3390/onco2030015
R. Abolfath, M. Khalili, A. Senejani, Balachandran Kodery, R. Ivker
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Abstract

Introduction: In this work, we develop a multi-scale model to calculate corrections to the prescription dose to predict compensation required for the DNA repair mechanism and the repopulation of the cancer cells due to the occurrence of patient scheduling variabilities and the treatment time-gap in fractionation scheme. Methods: A system of multi-scale, time-dependent birth-death Master equations is used to describe stochastic evolution of double-strand breaks (DSBs) formed on DNAs and post-irradiation intra and inter chromosomes end-joining processes in cells, including repair and mis-repair mechanisms in microscopic scale, with an extension appropriate for calculation of tumor control probability (TCP) in macroscopic scale. Variabilities in fractionation time due to systematic shifts in patient’s scheduling and randomness in inter-fractionation treatment time are modeled. For an illustration of the methodology, we focus on prostate cancer. Results: We derive analytical corrections to linear-quadratic radiobiological indices α and β as a function of variabilities in treatment time and shifts in patient’s scheduling. We illustrate the dependence of the absolute value of the compensated dose on radio-biological sensitivity, α/β, DNA repair half-time, T1/2, tumor cells repopulation rate, and the time-gaps among treatment fractions due to inter-patient variabilities. At a given tumor size, delays between fractions totaling 24 h over the entire course of treatment, in a typical prostate cancer fractionation scheme, e.g., 81 Gy, 1.8 Gy per fraction and 45 treatment days, require up to 10% compensation dose if the sublethal DNA repair half-time, T1/2, spans over 10 h. We show that the contribution of the fast DNA repair mechanisms to the total dose is negligible. Instead, any compensation to the total dose stems from the tumor cell repopulation that may go up to a significant fraction of the original dose for a time gap of up to one week. Conclusions: We recommend implementation of time irregularities in treatment scheduling in the clinic settings to be taken into account. To achieve a clinical endpoint, corrections to the prescription dose must be assessed, in particular, if modern external beam therapy techniques such as IMRT/VMAT are used for the treatment of cancer.
放射治疗中补偿剂量与系统和随机中断治疗时间的关系
简介:在这项工作中,我们开发了一个多尺度模型来计算处方剂量的校正,以预测由于分级方案中患者调度变量和治疗时间间隔的发生,癌症细胞的DNA修复机制和重新繁殖所需的补偿。方法:使用多尺度、时间依赖的出生-死亡主方程系统来描述DNA上形成的双链断裂(DSBs)的随机进化以及细胞中辐照后染色体内和染色体间末端连接过程,包括微观尺度的修复和错误修复机制,其扩展适用于在宏观尺度上计算肿瘤控制概率(TCP)。由于患者日程安排的系统性变化和分级间治疗时间的随机性,分级时间的可变性被建模。为了说明方法,我们将重点放在前列腺癌症上。结果:我们推导了线性二次放射生物学指数α和β的分析校正,作为治疗时间变化和患者日程安排变化的函数。我们说明了补偿剂量的绝对值对放射生物学敏感性、α/β、DNA修复半时间、T1/2、肿瘤细胞再增殖率以及由于患者间差异导致的治疗组分之间的时间间隔的依赖性。在给定的肿瘤大小下,在典型的前列腺癌症分级方案中,在整个治疗过程中总共24小时的级分之间的延迟,例如,81 Gy,每个级分1.8 Gy和45个治疗日,如果亚致死DNA修复半时T1/2跨越10小时,则需要高达10%的补偿剂量。我们表明,快速DNA修复机制对总剂量的贡献可以忽略不计。相反,对总剂量的任何补偿都源于肿瘤细胞的重新增殖,在长达一周的时间间隔内,肿瘤细胞的数量可能会增加到原始剂量的很大一部分。结论:我们建议在临床环境中考虑治疗计划中的时间不规则性。为了达到临床终点,必须评估处方剂量的校正,特别是如果使用IMRT/VMAT等现代外部射束治疗技术治疗癌症。
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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