Maintenance of hepatic sinusoidal endothelial cell phenotype in vitro using organ-specific extracellular matrix scaffolds.

Tiffany L Sellaro, Anjani K Ravindra, Donna Beer Stolz, Stephen F Badylak
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引用次数: 217

Abstract

Sinusoidal endothelial cells (SECs) are notoriously difficult to culture in vitro. SECs represent a highly specialized endothelial cell (EC) population, and traditional methods of SEC isolation from the liver initiate a process of SEC dedifferentiation. Acellular extracellular matrix (ECM) scaffolds were investigated in a physiologically relevant in vitro culture model for their ability to maintain SEC phenotype. The cell culture model used SECs only or a coculture of SECs with hepatocytes on ECM substrates derived from the liver (L-ECM), bladder (UBM-ECM), or small intestine submucosa (SIS-ECM). The effect of the ECM substrate upon SEC dedifferentiation was evaluated using scanning electron microscopy (SEM) and confocal microscopy. When SECs alone were cultured on uncoated glass slides, collagen I, UBM-ECM, or SIS-ECM, SECs showed signs of dedifferentiation after 1 day. In contrast, SECs alone cultured on L-ECM maintained their differentiated phenotype for at least 3 days, indicated by the presence of many fenestrations on SEC surface, expression of anti-rat hepatic sinusoidal endothelial cells mouse IgG MoAb (SE-1), and lack of expression of CD31. When SECs were cocultured with hepatocytes on any of the ECM scaffolds, the SECs maintained a near-normal fenestrated phenotype for at least 1 day. However, SEM revealed that the shape, size, frequency, and organization of the fenestrations varied greatly depending on ECM source. At all time points, SECs cocultured with hepatocytes on L-ECM maintained the greatest degree of differentiation. The present study demonstrated that the acellular ECM scaffold derived from the liver maintained SEC differentiation in culture longer than any of the tested substrate materials. The replacement of complex tissues and 3-dimensional organs may require specialized scaffolds to support multiple, functional cell phenotypes.

使用器官特异性细胞外基质支架在体外维持肝窦内皮细胞表型。
众所周知,窦状内皮细胞(SECs)很难在体外培养。SEC是一种高度特化的内皮细胞(EC)群体,从肝脏中分离SEC的传统方法启动了SEC去分化的过程。在生理相关的体外培养模型中研究了脱细胞细胞外基质(ECM)支架维持SEC表型的能力。细胞培养模型仅使用SECs或将SECs与肝细胞在来自肝脏(L-ECM)、膀胱(UBM-ECM)或小肠粘膜下层(SIS-ECM)的ECM基质上共培养。利用扫描电镜(SEM)和共聚焦显微镜评估ECM底物对SEC去分化的影响。当SECs单独在未涂布的玻片、I型胶原、UBM-ECM或SIS-ECM上培养时,1天后SECs出现去分化迹象。相比之下,在L-ECM上单独培养的SECs至少维持了3天的分化表型,这表明SEC表面存在许多开孔,表达抗大鼠肝窦内皮细胞小鼠IgG MoAb (SE-1),缺乏CD31的表达。当SECs与肝细胞在任何ECM支架上共培养时,SECs保持接近正常的开窗表型至少1天。然而,扫描电镜显示,孔洞的形状、大小、频率和组织随ECM源的不同而变化很大。在所有时间点,在L-ECM上与肝细胞共培养的sec保持最大程度的分化。本研究表明,来源于肝脏的脱细胞ECM支架在培养过程中保持SEC分化的时间比任何一种测试的底物材料都要长。复杂组织和三维器官的替换可能需要专门的支架来支持多种功能细胞表型。
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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来源期刊
Tissue engineering
Tissue engineering CELL & TISSUE ENGINEERING-BIOTECHNOLOGY & APPLIED MICROBIOLOGY
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