Fabrication of 3D structured human cell networks using capillary cell suspensions from aqueous two-phase systems†

IF 6 2区材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Materials Chemistry Frontiers Pub Date : 2025-05-13 DOI:10.1039/D5QM00196J

Amro K. F. Dyab and Vesselin N. Paunov

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Abstract

Three-dimensional (3D) cell culture and cell spheroid models have recently emerged as more realistic experimental platforms in life sciences, bridging the gap between two-dimensional (2D) cell cultures and animal models. However, the formation of necrotic cores in cell spheroids presents a challenge for their wider use in drug testing. Here, we report a novel method of using an aqueous two-phase system (ATPS)-based capillary suspension to generate 3D structured cell networks which opens new possibilities for the assembly of tissues from adherent cells. We demonstrate the fabrication of 3D cell networks with different microstructures and morphologies from capillary cell suspensions. These were formed by the addition of a small volume fraction of dextran solution in culture media (DEX) as a secondary aqueous liquid phase to a concentrated cell suspension into a polyethylene glycol solution in culture media (PEG) as a primary immiscible aqueous phase. The formation of water-in-water (DEX-in-PEG) capillary bridges among the cells is responsible for transforming of the cell suspension into an innovative tissue-like biomaterial where the cells are connected in spanning networks. The wettability of adherent cells by the involved phases and their interfacial tension were investigated and correlated to the microstructures formed. Enhanced rheological properties were obtained at 2 vol% of DEX phase, where the maximal yield stress of the capillary cell suspension was achieved. Capillary cell suspensions with DEX phase volume percentage higher than 2 vol% changed their structure from cell networks to spheroidal cell aggregates, yielding cell spheroids. Cell viability was not impacted by long-term incubation in a DEX/PEG capillary suspension environment. We envisage how the present approach can pave the way for innovative and cost-effective preparation of cell structures for potential application in 3D cell culture and scaffold-free tissue engineering.

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利用毛细管细胞悬浮液从水两相系统制造的三维结构人体细胞网络†

三维（3D）细胞培养和细胞球体模型最近成为生命科学中更现实的实验平台，弥合了二维（2D）细胞培养和动物模型之间的差距。然而，细胞球体中坏死核的形成对其在药物测试中的广泛应用提出了挑战。在这里，我们报告了一种使用基于水两相系统（ATPS）的毛细管悬浮液来生成3D结构细胞网络的新方法，这为贴壁细胞组装组织开辟了新的可能性。我们演示了用毛细管细胞悬浮液制造具有不同微结构和形态的3D细胞网络。这些是通过在培养基（DEX）中加入小体积分数的葡聚糖溶液作为次级水相，将浓缩细胞悬浮液加入到培养基（PEG）中的聚乙二醇溶液中作为初级不混相形成的。细胞间形成的水包水（DEX-in-PEG）毛细血管桥负责将细胞悬浮液转化为创新的组织样生物材料，其中细胞以跨越网络连接。研究了相关相对贴壁细胞的润湿性及其界面张力与所形成的微观结构的关系。在DEX相含量为2 vol%时，毛细管细胞悬浮液的屈服应力达到最大，流变性能得到增强。DEX相体积百分比大于2 vol%的毛细管细胞悬浮液，其结构由网状细胞转变为球状细胞聚集体，形成球状细胞。在DEX/PEG毛细管悬浮液中长期孵育不影响细胞活力。我们设想目前的方法如何为创新和经济有效地制备细胞结构铺平道路，以潜在地应用于3D细胞培养和无支架组织工程。

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来源期刊

Materials Chemistry Frontiers Materials Science-Materials Chemistry

CiteScore

12.00

自引率

2.90%

发文量

313

期刊介绍： Materials Chemistry Frontiers focuses on the synthesis and chemistry of exciting new materials, and the development of improved fabrication techniques. Characterisation and fundamental studies that are of broad appeal are also welcome. This is the ideal home for studies of a significant nature that further the development of organic, inorganic, composite and nano-materials.