The morphology of cell spheroids in simple shear flow

arXiv - QuanBio - Cell Behavior Pub Date : 2024-04-11 DOI:arxiv-2404.07528

Rosalia Ferraro, Jasmin Di Franco, Sergio Caserta, Stefano Guido

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Abstract

Cell spheroids are a widely used model to investigate cell-cell and cell-matrix interactions in a 3D microenvironment in vitro. Most research on cell spheroids has been focused on their response to various stimuli under static conditions. Recently, the effect of flow on cell spheroids has been investigated in the context of tumor invasion in interstitial space. In particular, microfluidic perfusion of cell spheroids embedded in a collagen matrix has been shown to modulate cell-cell adhesion and to represent a possible mechanism promoting tumor invasion by interstitial flow. However, studies on the effects of well-defined flow fields on cell spheroids are lacking in the literature. Here, we apply simple shear flow to cell spheroids in a parallel plate apparatus while observing their morphology by optical microscopy. By using image analysis techniques, we show that cell spheroids rotate under flow as rigid particles. As time goes on, cells from the outer layer detach from the sheared cell spheroids and are carried away by the flow. Hence, the size of cell spheroids declines with time at a rate increasing with the external shear stress, which can be used to estimate cell-cell adhesion. The technique proposed in this work allows one to correlate flow-induced effects with microscopy imaging of cell spheroids in a well-established shear flow field, thus providing a method to obtain quantitative results which are relevant in the general field of mechanobiology.

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简单剪切流中的球形细胞形态

细胞球是一种广泛使用的模型，用于研究体外三维微环境中细胞-细胞和细胞-基质之间的相互作用。大多数关于细胞球的研究都集中在它们对各种刺激和静态条件的反应上。最近，在肿瘤侵入间质空间的背景下，人们研究了流动对细胞球的影响。特别是，对嵌入胶原基质的细胞球体进行微流体灌注已被证明能调节细胞与细胞之间的粘附力，是间质流动促进肿瘤侵袭的可能机制。然而，文献中缺乏关于定义明确的流场对细胞球体影响的研究。在这里，我们在平行板装置中对细胞球体施加简单的剪切流，同时用光学显微镜观察它们的形态。通过图像分析技术，我们发现细胞球体在流动过程中会像刚性颗粒一样旋转。随着时间的推移，外层细胞会从剪切的细胞球体上脱离并被流动带走。因此，细胞球体的大小会随着时间的推移而减小，减小的速度随着外部剪切应力的增大而增大，这可以用来估计细胞与细胞之间的粘附力。这项工作中提出的技术可以将流动诱导效应与细胞球体在成熟的剪切流场中的显微成像联系起来，从而提供了一种获得定量结果的方法，这些定量结果与一般的机械生物学领域相关。

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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arXiv - QuanBio - Cell Behavior

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