Spatial simulation of autologous cell defection for cancer treatment.

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
ACS Applied Electronic Materials Pub Date : 2023-11-22 eCollection Date: 2023-01-01 DOI:10.1093/emph/eoad042
Jibeom Choi
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Abstract

Cancer cells are highly cooperative in a nepotistic way and evolutionarily dynamic. Present cancer treatments often overlook these aspects, inducing the selection of resistant cancer cells and the corresponding relapse. As an alternative method of cancer elimination, autologous cell defection (ACD) was suggested by which modified cancer cells parasitically reliant on other cancer cells are implemented to the cancer cluster. Specifically, modified cancer cells should not produce costly growth factors that promote the growth of other cancer cells while receiving the benefit of exposure to such growth factors. Analytical models and rudimentary experiments up to date provide the medical feasibility of this method. In this study, I built comprehensive spatial simulation models by embracing the effects of the multiple growth factors, the Warburg effect, mutations and immunity. The simulation results based on planar spatial structures indicate that implementation of the defective modified tumours may replace the existing cancer cluster and defective cells would later collapse by themselves. Furthermore, I built a mathematical model that compares the fitness of the cells adjacent to the hypertumour-cancer interface. I also calculated whether anticancer drugs that reduce the effects of the growth factors promote or demote the utility of ACD under diverse fitness functions. The computational examination implies that anticancer drugs may impede the therapeutic effect of ACD when there is a strong concavity in the fitness function. The analysis results could work as a general guidance for effective ACD that may expand the paradigm of cancer treatment.

用于癌症治疗的自体细胞脱落空间模拟。
癌细胞具有高度合作性和进化动态性。目前的癌症治疗方法往往忽视了这些方面,从而导致抗药性癌细胞的产生和相应的复发。作为消除癌症的另一种方法,有人提出了自体细胞叛逃(ACD),即在癌细胞群中实施寄生于其他癌细胞的改造癌细胞。具体来说,改造后的癌细胞不应产生促进其他癌细胞生长的昂贵生长因子,同时又能从接触这些生长因子中获益。迄今为止的分析模型和初步实验证明了这种方法在医学上的可行性。在这项研究中,我建立了全面的空间模拟模型,囊括了多种生长因子、沃伯格效应、突变和免疫的影响。基于平面空间结构的模拟结果表明,实施缺陷修饰的肿瘤可能会取代现有的癌群,缺陷细胞随后会自行崩溃。此外,我还建立了一个数学模型,用于比较邻近高肿瘤-癌症界面的细胞的适应性。我还计算了减少生长因子作用的抗癌药物在不同的适应度函数下是促进还是降低了ACD的效用。计算结果表明,当适应度函数出现强凹性时,抗癌药物可能会阻碍ACD的治疗效果。分析结果可以作为有效的 ACD 的一般指导,从而拓展癌症治疗的范式。
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
CiteScore
7.20
自引率
4.30%
发文量
567
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