Kinetic modeling of tumor regression incorporating the concept of cancer stem-like cells for patients with locally advanced lung cancer.

Q1 Mathematics

Theoretical Biology and Medical Modelling Pub Date : 2018-12-27 DOI:10.1186/s12976-018-0096-7

Hualiang Zhong, Stephen Brown, Suneetha Devpura, X Allen Li, Indrin J Chetty

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引用次数: 1

Abstract

Background: Personalized medicine for patients receiving radiation therapy remains an elusive goal due, in part, to the limits in our understanding of the underlying mechanisms governing tumor response to radiation. The purpose of this study was to develop a kinetic model, in the context of locally advanced lung cancer, connecting cancer cell subpopulations with tumor volumes measured during the course of radiation treatment for understanding treatment outcome for individual patients.

Methods: The kinetic model consists of three cell compartments: cancer stem-like cells (CSCs), non-stem tumor cells (TCs) and dead cells (DCs). A set of ordinary differential equations were developed to describe the time evolution of each compartment, and the analytic solution of these equations was iterated to be aligned with the day-to-day tumor volume changes during the course of radiation treatment. A least squares fitting method was used to estimate the parameters of the model that include the proportion of CSCs and their radio-sensitivities. This model was applied to five patients with stage III lung cancer, and tumor volumes were measured from 33 cone-beam computed tomography (CBCT) images for each of these patients. The analytical solution of these differential equations was compared with numerically simulated results.

Results: For the five patients with late stage lung cancer, the derived proportions of CSCs are 0.3 on average, the average probability of the symmetry division is 0.057 and the average surviving fractions of CSCs is 0.967, respectively. The derived parameters are comparable to the results from literature and our experiments. The preliminary results suggest that the CSC self-renewal rate is relatively small, compared to the proportion of CSCs for locally advanced lung cancers.

Conclusions: A novel mathematical model has been developed to connect the population of cancer stem-like cells with tumor volumes measured from a sequence of CBCT images. This model may help improve our understanding of tumor response to radiation therapy, and is valuable for development of new treatment regimens for patients with locally advanced lung cancer.

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结合肿瘤干细胞概念的局部晚期肺癌患者肿瘤消退动力学模型。

背景:对接受放射治疗的患者进行个体化治疗仍然是一个难以实现的目标，部分原因是我们对肿瘤对放射反应的潜在机制的理解有限。本研究的目的是在局部晚期肺癌的背景下建立一个动力学模型，将癌细胞亚群与放射治疗过程中测量的肿瘤体积联系起来，以了解个体患者的治疗结果。方法:动力学模型由3个细胞区室组成:肿瘤干细胞样细胞(CSCs)、非干细胞肿瘤细胞(TCs)和死细胞(DCs)。建立了一组常微分方程来描述每个腔室的时间演变，并迭代这些方程的解析解以与放射治疗过程中日常肿瘤体积的变化保持一致。采用最小二乘拟合方法估计模型参数，其中包括CSCs的比例及其辐射灵敏度。该模型应用于5例III期肺癌患者，并从每个患者的33张锥形束计算机断层扫描(CBCT)图像中测量肿瘤体积。将这些微分方程的解析解与数值模拟结果进行了比较。结果:5例晚期肺癌患者，CSCs的衍生比例平均为0.3，对称分裂的平均概率为0.057,CSCs的平均存活分数为0.967。所得参数与文献和实验结果基本一致。初步结果表明，与局部晚期肺癌中CSC的比例相比，CSC的自我更新率相对较小。结论:已经建立了一个新的数学模型，将癌症干细胞样细胞的数量与从一系列CBCT图像中测量的肿瘤体积联系起来。该模型可能有助于提高我们对肿瘤对放射治疗的反应的理解，并对局部晚期肺癌患者的新治疗方案的开发有价值。

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来源期刊

Theoretical Biology and Medical Modelling MATHEMATICAL & COMPUTATIONAL BIOLOGY-

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Theoretical Biology and Medical Modelling is an open access peer-reviewed journal adopting a broad definition of "biology" and focusing on theoretical ideas and models associated with developments in biology and medicine. Mathematicians, biologists and clinicians of various specialisms, philosophers and historians of science are all contributing to the emergence of novel concepts in an age of systems biology, bioinformatics and computer modelling. This is the field in which Theoretical Biology and Medical Modelling operates. We welcome submissions that are technically sound and offering either improved understanding in biology and medicine or progress in theory or method.