Optimization of irradiation interval for fractionated stereotactic radiosurgery by a cellular automata model with reoxygenation effects

Physics in Medicine & Biology 65 巻 8 号 085008- 頁 2020-04-20 発行
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タイトル ( eng )
Optimization of irradiation interval for fractionated stereotactic radiosurgery by a cellular automata model with reoxygenation effects
作成者
Wu Lin
Watanabe Yoichi
収録物名
Physics in Medicine & Biology
65
8
開始ページ 085008
抄録
The current study aims to determine the optimal irradiation interval of fractionated stereotactic radiosurgery (SRS) by using an improved cellular automata (CA) model. The tumor growth process was simulated by considering the amount of oxygen and the density of blood vessels, which supplied oxygen and nutrient required for cell growth. Cancer cells died by the mitotic death process due to radiation, which was quantified by the LQ-model, or the apoptosis due to the lack of nutrients. The radiation caused increased permeation of plasma protein through the blood vessel or the breakdown of the vasculature. Consequently, these changes lead to a change in radiation sensitivity of cancer cells and tumor growth rate after irradiation. The optimal model parameters were determined with experimental data of the rat tumor volume. The tumor control probability (TCP) was defined as the ratio of the number of histories in which all cancer cells died after the irradiation to the total number of the histories per simulation. The optimal irradiation interval was defined as the irradiation interval that TCP was the maximum. For one fractionation treatment, the ratio of hypoxic cells to the total number of cancer cells kept decreasing until day 16th after irradiation; whereas the number of surviving cancer cells begun increasing immediately after irradiation. This intricate relationship between the hypoxia (or reoxygenation) and the number of cancer cells lead to an optimal irradiation interval for the second irradiation. The optimal irradiation interval for two-fraction SRS was six days. The optimum intervals for the first-second irradiations and the second-third irradiations were five and two days, respectively, for three fraction SRS. For 4 and 5-fraction treatments, the optimum first-interval was five days, which was similar to three fraction treatment. The remaining intervals should be one day. We showed that the improved CA model could be used to optimize the irradiation interval by explicitly including the reoxygenation after irradiation in the model.
著者キーワード
automata model
radiation effect
hypoxia
SRS
内容記述
The part of the work was previously published as an electronic poster at the annual meeting of the American Association of Physicists in Medicine, San Antonio, Texas, USA, July 13-18, 2019.
言語
英語
資源タイプ 学術雑誌論文
出版者
Institute of Physics and Engineering in Medicine
IOP Publishing
発行日 2020-04-20
権利情報
This is an author-created, un-copyedited version of an article accepted for publication/published in Physics in Medicine & Biology. IOP Publishing Ltd is not responsible for any errors or omissions in this version of the manuscript or any version derived from it. The Version of Record is available online at https://doi.org/10.1088/1361-6560/ab7974.
This is not the published version. Please cite only the published version. この論文は出版社版ではありません。引用の際には出版社版をご確認、ご利用ください。
出版タイプ Author’s Original(十分な品質であるとして、著者から正式な査読に提出される版)
アクセス権 オープンアクセス
収録物識別子
[ISSN] 0031-9155
[ISSN] 1361-6560
[DOI] 10.1088/1361-6560/ab7974
[PMID] 32092715
[DOI] https://doi.org/10.1088/1361-6560/ab7974
備考 Post-print version/PDF may be used in an institutional repository after an embargo period of 12 months.