作为癌症模型的囚徒困境。

Convergent science physical oncology Pub Date : 2016-09-01 Epub Date: 2016-07-04 DOI:10.1088/2057-1739/2/3/035002
Jeffrey West, Zaki Hasnain, Jeremy Mason, Paul K Newton
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引用次数: 0

摘要

肿瘤的发展是一个进化过程,在这一过程中,具有不同生长能力的异质细胞群为获得增殖优势而争夺资源。要重现这样一个发展中的复杂生态系统的某些突发特征,需要哪些最基本的成分?在我们检测到肿瘤之前,它在做什么?我们概述了一个由随机莫兰过程驱动的数学模型,在这个模型中,癌细胞和健康细胞为争夺群体中的优势地位而竞争。根据 "囚徒困境 "进化博弈,健康细胞是合作者,而癌细胞是叛逃者,两者各自分配报酬。通过点突变动态、遗传和控制出生率和死亡率的适应度景观,自然选择作用于细胞群,模拟出 "类癌 "特征,如异质性驱动的冈pertz肿瘤生长、将治疗剂量密度与癌细胞存活概率(对数)线性关联的对数致死定律,以及将肿瘤消退率与肿瘤生长率线性关联的诺顿-西蒙假说。我们强调了这些模型的实用性、清晰度和强大功能,尽管(也正因为)它们很简单,而且有内置假设。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The prisoner's dilemma as a cancer model.

The prisoner's dilemma as a cancer model.

The prisoner's dilemma as a cancer model.

The prisoner's dilemma as a cancer model.

Tumor development is an evolutionary process in which a heterogeneous population of cells with different growth capabilities compete for resources in order to gain a proliferative advantage. What are the minimal ingredients needed to recreate some of the emergent features of such a developing complex ecosystem? What is a tumor doing before we can detect it? We outline a mathematical model, driven by a stochastic Moran process, in which cancer cells and healthy cells compete for dominance in the population. Each are assigned payoffs according to a Prisoner's Dilemma evolutionary game where the healthy cells are the cooperators and the cancer cells are the defectors. With point mutational dynamics, heredity, and a fitness landscape controlling birth and death rates, natural selection acts on the cell population and simulated 'cancer-like' features emerge, such as Gompertzian tumor growth driven by heterogeneity, the log-kill law which (linearly) relates therapeutic dose density to the (log) probability of cancer cell survival, and the Norton-Simon hypothesis which (linearly) relates tumor regression rates to tumor growth rates. We highlight the utility, clarity, and power that such models provide, despite (and because of) their simplicity and built-in assumptions.

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