Biological dosimetric impact of dose-delivery time for hypoxic tumour with modified microdosimetric kinetic model

IF 1.2 Q4 ONCOLOGY

Reports of Practical Oncology and Radiotherapy Pub Date : 2023-08-28 DOI:10.5603/rpor.96868

Daisuke Kawahara, Yasushi Nagata

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引用次数: 0

Abstract

Background: An improved microdosimetric kinetic model (MKM) can address radiobiological effects with prolonged delivery times. However, these do not consider the effects of oxygen. The current study aimed to evaluate the biological dosimetric effects associated with the dose delivery time in hypoxic tumours with improved MKM for photon radiation therapy. Materials and methods: Cell survival was measured under anoxic, hypoxic, and oxic conditions using the Monte Carlo code PHITS. The effect of the dose rate of 0.5–24 Gy/min for the biological dose (Dbio) was estimated using the microdosimetric kinetic model. The dose per fraction and pressure of O2 (pO2) in the tumour varied from 2 to 20 Gy and from 0.01 to 5.0% pO 2 , respectively. Results: The ratio of the Dbio at 1.0–24 Gy/min to that at 0.5 Gy/min (RDR) was higher at higher doses. The maximum RDR was 1.09 at 1.0 Gy/min, 1.12 at 12 Gy/min, and 1.13 at 24 Gy/min. The ratio of the Dbio at 0.01–2.0% of pO2 to that at 5.0% of pO 2 (Roxy) was within 0.1 for 2–20 Gy of physical dose. The maximum Roxy was 0.42 at 0.01% pO2, 0.76 at 0.4% pO2, 0.89 at 1% pO 2 , and 0.96 at 2% pO2. Conclusion: Our proposed model can estimate the cell killing and biological dose under hypoxia in a clinical and realistic patient. A shorter dose-delivery time with a higher oxygen distribution increased the radiobiological effect. It was more effective at higher doses per fraction than at lower doses.

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用改进的微剂量动力学模型研究给药时间对缺氧肿瘤的生物剂量学影响

背景:一种改进的微剂量动力学模型(MKM)可以解决延长递送时间的放射生物学效应。然而，这些都没有考虑到氧气的影响。本研究旨在评估缺氧肿瘤改良MKM光子放射治疗中与剂量传递时间相关的生物剂量学效应。材料和方法:使用蒙特卡洛代码PHITS在缺氧、缺氧和缺氧条件下测量细胞存活率。利用微剂量动力学模型估计了0.5 ~ 24 Gy/min剂量率对生物剂量(Dbio)的影响。肿瘤中每分数O2 (pO2)的剂量和压力分别为2 ~ 20gy和0.01 ~ 5.0% pO2。结果:1.0 ~ 24 Gy/min的Dbio与0.5 Gy/min的Dbio之比(RDR)随剂量增大而增大。1.0 Gy/min时最大RDR为1.09,12 Gy/min时为1.12,24 Gy/min时为1.13。物理剂量为2 ~ 20 Gy时，0.01 ~ 2.0% pO2与5.0% pO2 (Roxy)的Dbio比值在0.1以内。0.01% pO2、0.4% pO2、1% pO2和2% pO2的最大Roxy分别为0.42、0.76、0.89和0.96。结论:该模型能较好地估计临床和现实患者在缺氧条件下的细胞杀伤和生物剂量。较短的给药时间和较高的氧分布增加了放射生物学效应。高剂量时比低剂量时更有效。

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

Reports of Practical Oncology and Radiotherapy Multiple-

CiteScore

2.80

自引率

8.30%

发文量

115

审稿时长

16 weeks

期刊介绍： Reports of Practical Oncology and Radiotherapy is an interdisciplinary bimonthly journal, publishing original contributions in clinical oncology and radiotherapy, as well as in radiotherapy physics, techniques and radiotherapy equipment. Reports of Practical Oncology and Radiotherapy is a journal of the Polish Society of Radiation Oncology, the Czech Society of Radiation Oncology, the Hungarian Society for Radiation Oncology, the Slovenian Society for Radiotherapy and Oncology, the Polish Study Group of Head and Neck Cancer, the Guild of Bulgarian Radiotherapists and the Greater Poland Cancer Centre, affiliated with the Spanish Society of Radiotherapy and Oncology, the Italian Association of Radiotherapy and the Portuguese Society of Radiotherapy - Oncology.