基于单细胞数据的肿瘤进化过程中表型可塑性的数学建模和定量分析。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Yuyang Xiao, Xiufen Zou
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引用次数: 0

摘要

肿瘤是一种复杂的侵袭性疾病,对健康构成重大挑战。了解肿瘤进展的细胞机制对于开发有效的治疗方法至关重要。在本研究中,我们建立了一个新颖的数学框架来研究细胞可塑性和异质性在肿瘤进展中的作用。通过利用时序单细胞数据,我们提出了一种反应-对流-扩散模型,该模型能有效捕捉肿瘤微环境中肿瘤细胞和巨噬细胞的时空动态。通过理论分析,我们得到了脉冲波速的估计值,并分析了均匀稳态解的稳定性。值得一提的是,我们利用 AddModuleScore 函数来量化细胞的可塑性。我们方法的亮点之一是引入了脉冲波速作为定量指标,以精确测量细胞表型的转换速度,并新颖地实现了高可塑性细胞状态/低可塑性细胞状态比率作为肿瘤恶性程度的指标。此外,分叉分析揭示了肿瘤细胞群的复杂动态。我们的广泛分析表明,表型转换率的增加与恶性程度的提高有关,这归因于肿瘤探索更广阔表型空间的能力。研究还探讨了肿瘤细胞的增殖率和死亡率、表型对流速度以及表型转换阶段的中点如何影响肿瘤细胞表型转换的速度以及向腺癌的进展。这些见解和定量测量有助于指导靶向治疗策略的开发,从而调节细胞可塑性并有效控制肿瘤进展。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Mathematical modeling and quantitative analysis of phenotypic plasticity during tumor evolution based on single-cell data.

Mathematical modeling and quantitative analysis of phenotypic plasticity during tumor evolution based on single-cell data.

Tumor is a complex and aggressive type of disease that poses significant health challenges. Understanding the cellular mechanisms underlying its progression is crucial for developing effective treatments. In this study, we develop a novel mathematical framework to investigate the role of cellular plasticity and heterogeneity in tumor progression. By leveraging temporal single-cell data, we propose a reaction-convection-diffusion model that effectively captures the spatiotemporal dynamics of tumor cells and macrophages within the tumor microenvironment. Through theoretical analysis, we obtain the estimate of the pulse wave speed and analyze the stability of the homogeneous steady state solutions. Notably, we employe the AddModuleScore function to quantify cellular plasticity. One of the highlights of our approach is the introduction of pulse wave speed as a quantitative measure to precisely gauge the rate of cell phenotype transitions, as well as the novel implementation of the high-plasticity cell state/low-plasticity cell state ratio as an indicator of tumor malignancy. Furthermore, the bifurcation analysis reveals the complex dynamics of tumor cell populations. Our extensive analysis demonstrates that an increased rate of phenotype transition is associated with heightened malignancy, attributable to the tumor's ability to explore a wider phenotypic space. The study also investigates how the proliferation rate and the death rate of tumor cells, phenotypic convection velocity, and the midpoint of the phenotype transition stage affect the speed of tumor cell phenotype transitions and the progression to adenocarcinoma. These insights and quantitative measures can help guide the development of targeted therapeutic strategies to regulate cellular plasticity and control tumor progression effectively.

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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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