Cell spheroid viscoelasticity is deformation-dependent

Ruben C. Boot, Anouk van der Net, Christos Gogou, Pranav Mehta, Dimphna H. Meijer, Gijsje H. Koenderink, Pouyan E. Boukany
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Abstract

Tissue surface tension influences cell sorting and tissue fusion. Earlier mechanical studies suggest that multicellular spheroids actively reinforce their surface tension with applied force. Here we study this open question through high-throughput microfluidic micropipette aspiration measurements on cell spheroids to identify the role of force duration and cell contractility. We find that larger spheroid deformations lead to faster cellular retraction once the pressure is released, regardless of the applied force and cellular contractility. These new insights demonstrate that spheroid viscoelasticity is deformation-dependent and challenge whether surface tension truly reinforces.
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细胞球体的粘弹性取决于形变
组织表面张力影响细胞分选和组织融合。早期的力学研究表明,多细胞球体在外力作用下会主动增强其表面张力。在这里,我们通过对细胞球体进行高通量微流体微吸管吸液测量来研究这一未决问题,以确定作用力持续时间和细胞收缩力的作用。我们发现,无论作用力和细胞收缩力如何,一旦压力释放,较大的球体变形会导致细胞更快地回缩。这些新发现证明了球体的粘弹性与形变有关,并对表面张力是否真正起到加固作用提出了挑战。
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