A mathematical model for predicting the spatiotemporal response of breast cancer cells treated with doxorubicin.

IF 4.4 4区 医学 Q2 ONCOLOGY
Cancer Biology & Therapy Pub Date : 2024-12-31 Epub Date: 2024-02-27 DOI:10.1080/15384047.2024.2321769
Hugo J M Miniere, Ernesto A B F Lima, Guillermo Lorenzo, David A Hormuth, Sophia Ty, Amy Brock, Thomas E Yankeelov
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引用次数: 0

Abstract

Tumor heterogeneity contributes significantly to chemoresistance, a leading cause of treatment failure. To better personalize therapies, it is essential to develop tools capable of identifying and predicting intra- and inter-tumor heterogeneities. Biology-inspired mathematical models are capable of attacking this problem, but tumor heterogeneity is often overlooked in in-vivo modeling studies, while phenotypic considerations capturing spatial dynamics are not typically included in in-vitro modeling studies. We present a data assimilation-prediction pipeline with a two-phenotype model that includes a spatiotemporal component to characterize and predict the evolution of in-vitro breast cancer cells and their heterogeneous response to chemotherapy. Our model assumes that the cells can be divided into two subpopulations: surviving cells unaffected by the treatment, and irreversibly damaged cells undergoing treatment-induced death. MCF7 breast cancer cells were previously cultivated in wells for up to 1000 hours, treated with various concentrations of doxorubicin and imaged with time-resolved microscopy to record spatiotemporally-resolved cell count data. Images were used to generate cell density maps. Treatment response predictions were initialized by a training set and updated by weekly measurements. Our mathematical model successfully calibrated the spatiotemporal cell growth dynamics, achieving median [range] concordance correlation coefficients of > .99 [.88, >.99] and .73 [.58, .85] across the whole well and individual pixels, respectively. Our proposed data assimilation-prediction approach achieved values of .97 [.44, >.99] and .69 [.35, .79] for the whole well and individual pixels, respectively. Thus, our model can capture and predict the spatiotemporal dynamics of MCF7 cells treated with doxorubicin in an in-vitro setting.

预测接受多柔比星治疗的乳腺癌细胞时空反应的数学模型。
肿瘤异质性在很大程度上导致了化疗抗药性,而化疗抗药性是治疗失败的主要原因。为了更好地实现个性化治疗,必须开发出能够识别和预测肿瘤内和肿瘤间异质性的工具。受生物学启发的数学模型能够解决这一问题,但体内建模研究往往忽略了肿瘤异质性,而体外建模研究通常不包括捕捉空间动态的表型因素。我们介绍了一种数据同化-预测管道,该管道采用包含时空成分的双表型模型,用于描述和预测体外乳腺癌细胞的演变及其对化疗的异质性反应。我们的模型假定细胞可分为两个亚群:未受治疗影响的存活细胞和因治疗而死亡的不可逆损伤细胞。MCF7 乳腺癌细胞先前在培养孔中培养长达 1000 小时,用不同浓度的多柔比星处理,并用时间分辨显微镜成像,记录时空分辨细胞计数数据。图像用于生成细胞密度图。治疗反应预测由训练集初始化,并通过每周的测量进行更新。我们的数学模型成功校准了时空细胞生长动态,在整井和单个像素上的中位数[范围]一致性相关系数分别大于.99[.88, >.99]和.73[.58, .85]。我们提出的数据同化-预测方法在全井和单个像素上的相关系数分别达到了 .97 [.44, >.99] 和 .69 [.35, .79]。因此,我们的模型可以捕捉和预测体外环境中接受多柔比星治疗的 MCF7 细胞的时空动态。
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
Cancer Biology & Therapy
Cancer Biology & Therapy 医学-肿瘤学
CiteScore
7.00
自引率
0.00%
发文量
60
审稿时长
2.3 months
期刊介绍: Cancer, the second leading cause of death, is a heterogenous group of over 100 diseases. Cancer is characterized by disordered and deregulated cellular and stromal proliferation accompanied by reduced cell death with the ability to survive under stresses of nutrient and growth factor deprivation, hypoxia, and loss of cell-to-cell contacts. At the molecular level, cancer is a genetic disease that develops due to the accumulation of mutations over time in somatic cells. The phenotype includes genomic instability and chromosomal aneuploidy that allows for acceleration of genetic change. Malignant transformation and tumor progression of any cell requires immortalization, loss of checkpoint control, deregulation of growth, and survival. A tremendous amount has been learned about the numerous cellular and molecular genetic changes and the host-tumor interactions that accompany tumor development and progression. It is the goal of the field of Molecular Oncology to use this knowledge to understand cancer pathogenesis and drug action, as well as to develop more effective diagnostic and therapeutic strategies for cancer. This includes preventative strategies as well as approaches to treat metastases. With the availability of the human genome sequence and genomic and proteomic approaches, a wealth of tools and resources are generating even more information. The challenge will be to make biological sense out of the information, to develop appropriate models and hypotheses and to translate information for the clinicians and the benefit of their patients. Cancer Biology & Therapy aims to publish original research on the molecular basis of cancer, including articles with translational relevance to diagnosis or therapy. We will include timely reviews covering the broad scope of the journal. The journal will also publish op-ed pieces and meeting reports of interest. The goal is to foster communication and rapid exchange of information through timely publication of important results using traditional as well as electronic formats. The journal and the outstanding Editorial Board will strive to maintain the highest standards for excellence in all activities to generate a valuable resource.
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