Estimating treatment sensitivity in synthetic and in vitro tumors using a random differential equation model.

IF 3.5 2区生物学 Q1 MATHEMATICAL & COMPUTATIONAL BIOLOGY

NPJ Systems Biology and Applications Pub Date : 2025-05-23 DOI:10.1038/s41540-025-00530-0

Natalie Meacham, Erica M Rutter

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Abstract

Resistance to treatment, which comes from the heterogeneity of cell types within tumors, is a leading cause of poor treatment outcomes in cancer patients. Previous mathematical work modeling cancer over time has neither emphasized the relationship between cell heterogeneity and treatment resistance nor depicted heterogeneity with sufficient nuance. To respond to the need to depict a wide range of resistance levels, we develop a random differential equation model of tumor growth. Random differential equations are differential equations in which the parameters are random variables. In the inverse problem, we aim to recover the sensitivity to treatment as a probability mass function. This allows us to observe what proportions of cells exist at different sensitivity levels. After validating the method with synthetic data, we apply it to monoclonal and mixture cell population data of isogenic Ba/F3 murine cell lines to uncover each tumor's levels of sensitivity to treatment as a probability mass function.

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用随机微分方程模型估计合成肿瘤和体外肿瘤的治疗敏感性。

由于肿瘤内细胞类型的异质性，对治疗的耐药性是癌症患者治疗效果不佳的主要原因。以前的数学工作既没有强调细胞异质性和治疗耐药性之间的关系，也没有充分细致地描述异质性。为了响应描绘大范围抵抗水平的需要，我们开发了肿瘤生长的随机微分方程模型。随机微分方程是参数为随机变量的微分方程。在反问题中，我们的目标是恢复对处理的敏感性作为一个概率质量函数。这使我们能够观察不同灵敏度水平下存在的细胞比例。在用合成数据验证该方法后，我们将其应用于等基因Ba/F3小鼠细胞系的单克隆和混合细胞群数据，以揭示每种肿瘤对治疗的敏感性水平作为概率质量函数。

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

NPJ Systems Biology and Applications Mathematics-Applied Mathematics

CiteScore

5.80

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： npj Systems Biology and Applications is an online Open Access journal dedicated to publishing the premier research that takes a systems-oriented approach. The journal aims to provide a forum for the presentation of articles that help define this nascent field, as well as those that apply the advances to wider fields. We encourage studies that integrate, or aid the integration of, data, analyses and insight from molecules to organisms and broader systems. Important areas of interest include not only fundamental biological systems and drug discovery, but also applications to health, medical practice and implementation, big data, biotechnology, food science, human behaviour, broader biological systems and industrial applications of systems biology. We encourage all approaches, including network biology, application of control theory to biological systems, computational modelling and analysis, comprehensive and/or high-content measurements, theoretical, analytical and computational studies of system-level properties of biological systems and computational/software/data platforms enabling such studies.