Dynamics of the self-assembly of complex cellular aggregates on micromolded nonadhesive hydrogels.

Anthony P Napolitano, Peter Chai, Dylan M Dean, Jeffrey R Morgan
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引用次数: 213

Abstract

The process by which cells self-assemble to form three-dimensional (3D) structures is central to morphogenesis and development of living tissues and hence is of growing interest to the field of tissue engineering. Using rapid prototyping technology we made micromolded nonadhesive hydrogels to study the dynamics of self-assembly in a low-shear environment with simple spherical geometries as well as more complex geometries such as a toroid. Aggregate size, shape, and composition were easily controlled; aggregates were easily retrieved; and the dynamics of the assembly process were readily observed by time-lapse microscopy. When two cell types, normal human fibroblasts (NHFs) and human umbilical vein endothelial cells (HUVECs), were seeded together, they self-segregated into multilayered spherical microtissues with a core of NHFs enveloped by a layer of HUVECs. Surprisingly, when a single cell suspension of NHFs was added to 7-day-old HUVEC spheroids, the HUVEC spheroid reorganized such that NHFs occupied the center and HUVECs coated the outside, demonstrating that self-assembly is not terminal and that spheroids are fluid structures that retain the ability to reassemble. We also showed that cells can self-assemble to form a complex toroid shape, and we observed several phenomena indicating that cellular contraction and tension play a significant role in the assembly process of complex shapes.

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微模非黏附水凝胶上复杂细胞聚集体自组装的动力学。
细胞自组装形成三维(3D)结构的过程是活体组织形态发生和发育的核心,因此对组织工程领域越来越感兴趣。利用快速成型技术,我们制作了微模压非粘性水凝胶,以研究低剪切环境下的自组装动力学,包括简单的球形几何形状以及更复杂的几何形状,如环面。骨料的大小、形状和组成都很容易控制;聚集体很容易检索;通过延时显微镜可以很容易地观察到装配过程的动力学。当两种细胞类型,正常人成纤维细胞(NHFs)和人脐静脉内皮细胞(HUVECs)一起播种时,它们自我分离成多层球形微组织,NHFs核心被HUVECs层包裹。令人惊讶的是,当将NHFs的单细胞悬浮液添加到7天大的HUVEC球体中时,HUVEC球体重组,NHFs占据中心,HUVEC包裹在外部,这表明自组装不是终点,球体是流体结构,保留了重新组装的能力。我们还发现细胞可以自组装形成复杂的环面形状,并且我们观察到一些现象表明细胞收缩和张力在复杂形状的组装过程中起着重要作用。
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Tissue engineering
Tissue engineering CELL & TISSUE ENGINEERING-BIOTECHNOLOGY & APPLIED MICROBIOLOGY
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