血管瘤硅学模型的形态稳定性

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Erik Blom, Stefan Engblom
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引用次数: 0

摘要

癌症系统生物学中的计算建模方法多种多样,提供了一系列模型和框架,每种模型和框架都有其自身的权衡和优势。理想情况下,模型应有助于完善假设、改进实验程序,从长远来看,甚至可应用于个性化医疗。最大的挑战之一是如何在模型的现实性和细节与实验数据之间取得平衡,以最终产生有用的数据驱动模型。我们开发了一个透明、高度简约的生长无血管肿瘤第一原理硅学模型,为这一探索做出了贡献。我们首先在一个基于随机细胞的框架内制定了生理考虑因素和具体模型。接下来,我们利用偏微分方程建立了一个相应的均场模型,并对其进行了数学分析。尽管两个模型之间存在一些明显的差异,但通过这种方法,我们能够成功地详细说明所有参数对随机模型生长过程的稳定性和最终肿瘤命运的影响。这不仅有助于推导出特定情况下的贝叶斯先验,还能为了解肿瘤生长和进展的内在机制提供重要启示。虽然由此产生的模型框架相对简单透明,但它仍能重现各种已知的突发行为。我们发现了一种由营养饥饿引起的新型模型不稳定性,我们还讨论了有关可能的模型添加及其影响的更多见解。由于该框架具有灵活性,因此只要有相关数据,就可以随时添加这些内容。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Morphological Stability for in silico Models of Avascular Tumors.

Morphological Stability for in silico Models of Avascular Tumors.

The landscape of computational modeling in cancer systems biology is diverse, offering a spectrum of models and frameworks, each with its own trade-offs and advantages. Ideally, models are meant to be useful in refining hypotheses, to sharpen experimental procedures and, in the longer run, even for applications in personalized medicine. One of the greatest challenges is to balance model realism and detail with experimental data to eventually produce useful data-driven models. We contribute to this quest by developing a transparent, highly parsimonious, first principle in silico model of a growing avascular tumor. We initially formulate the physiological considerations and the specific model within a stochastic cell-based framework. We next formulate a corresponding mean-field model using partial differential equations which is amenable to mathematical analysis. Despite a few notable differences between the two models, we are in this way able to successfully detail the impact of all parameters in the stability of the growth process and on the eventual tumor fate of the stochastic model. This facilitates the deduction of Bayesian priors for a given situation, but also provides important insights into the underlying mechanism of tumor growth and progression. Although the resulting model framework is relatively simple and transparent, it can still reproduce the full range of known emergent behavior. We identify a novel model instability arising from nutrient starvation and we also discuss additional insight concerning possible model additions and the effects of those. Thanks to the framework's flexibility, such additions can be readily included whenever the relevant data become available.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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