Spatial mechanistic modeling for prediction of 3D multicellular spheroids behavior upon exposure to high intensity pulsed electric fields

IF 1 Q4 ENGINEERING, BIOMEDICAL

AIMS Bioengineering Pub Date : 2022-01-01 DOI:10.3934/bioeng.2022009

Annabelle Collin, Hadrien Bruhier, Jelena Kolosnjaj, M. Golzio, M. Rols, C. Poignard

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引用次数: 2

Abstract

The objective of this work was to investigate the growth specificities of cancer cells spheroids subjected to pulsed electric field. Multicellular HCT-116-GFP spheroids were exposed to different electric field intensities and the volume of multicellular spheroids was monitored by fluorescence and bright field microscopy. Thanks to an advanced mathematical model, based on differential equations and well-adapted estimation strategies, our modeling enables us to characterize the multicellular spheroids growth after permeabilizing pulsed electric field. In particular, we identify the percentage of cells which are destroyed and the percentage of cells which exhibit an altered growth pattern for different magnitudes of the electric field. We also quantify the growth resumption upon reversible and partially irreversible electroporation. Our preliminary results provide a first quantification of the impact of electroporation on multicellular spheroids growth, and suggest a booming growth of partially irreversible electric pulses, leading to an accelerated regrowth.

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高强度脉冲电场作用下三维多细胞球体行为预测的空间机制建模

本研究的目的是研究脉冲电场作用下癌细胞球状体的生长特异性。多细胞HCT-116-GFP球体暴露于不同电场强度下，荧光显微镜和明场显微镜监测多细胞球体的体积。借助先进的数学模型，基于微分方程和适应性良好的估计策略，我们的建模使我们能够表征渗透脉冲电场后多细胞球体的生长。特别是，我们确定了细胞被破坏的百分比和细胞在不同大小的电场下表现出改变生长模式的百分比。我们还量化了可逆和部分不可逆电穿孔的生长恢复。我们的初步结果首次量化了电穿孔对多细胞球体生长的影响，并提出了部分不可逆电脉冲的快速增长，导致加速再生。

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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AIMS Bioengineering ENGINEERING, BIOMEDICAL-

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审稿时长

4 weeks