Reactive-Advective-Diffusive Models for the Growth of Gliomas Treated with Radiotherapy

Semina Ciencias Exatas e Tecnologicas Pub Date : 2023-06-22 DOI:10.5433/1679-0375.2023.v44.47321

Bruno da Silva Machado, G. B. Alvarez, Diomar Cesar Lobão

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Abstract

Gliomas are malignant brain tumors responsible for 50% of primary human brain cancer cases. They have a combination of rapid growth and invasiveness, and high fatality rates with a median survival time of one year. Mathematical models that describe its growth have helped to improve treatment. In this paper, a combined model formed by terms of two other models known in the literature is analyzed. The combined model is a Reactive-Advective-Diffusive partial differential equation, which is solved by combining the finite difference method, the Crank-Nicolson method and the upwind method. Logistic growth is used for cell proliferation ensuring a saturation threshold for glioma growth, which is crucial to properly estimate patient survival time. The well-known linear-quadratic radiobiological model is used to describe cell death due to radiotherapy treatment. Two initial conditions are compared in the simulations, indicating the need for further studies to have a model as close as possible to reality. Simulation results are shown for four scenarios: no radiotherapy, application of a single dose, and two dose fractionation schemes.

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放射治疗脑胶质瘤生长的反应性正向扩散模型

胶质瘤是恶性脑肿瘤，占人类原发性脑癌病例的50%。它们具有快速生长和侵袭性，死亡率高，中位生存时间为一年。描述其生长的数学模型有助于改善治疗。本文分析了由文献中已知的另外两种模型组成的组合模型。结合有限差分法、Crank-Nicolson法和迎风法对该组合模型进行求解，得到了一个反应-递进-扩散偏微分方程。逻辑生长用于细胞增殖，确保胶质瘤生长的饱和阈值，这对于正确估计患者的生存时间至关重要。众所周知的线性二次放射生物学模型用于描述放射治疗引起的细胞死亡。在模拟中比较了两种初始条件，表明需要进一步研究以使模型尽可能接近现实。模拟结果显示了四种情况:不放疗，应用单一剂量，和两个剂量分离方案。

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

Semina Ciencias Exatas e Tecnologicas

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审稿时长

12 weeks