Engineered liver-like tissue on a capillarized matrix for applied research.

Kirstin Linke, Johanna Schanz, Jan Hansmann, Thorsten Walles, Herwig Brunner, Heike Mertsching
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引用次数: 82

Abstract

Liver tissue that is functional and viable for several weeks in vitro represents an auspicious test system for basic and applied research. In this study, a coculture system for hepatocytes (HCs) and microvascular endothelial cells (mECs) was generated applying tissue-engineering techniques, establishing the basis for a new bioartificial liver in vitro model. Porcine mECs were seeded on a decellularized porcine jejunal segment with preserved vascular structures. Porcine HCs were seeded onto this vascularized scaffold, and the resulting coculture was maintained for 3 weeks in vitro. Tissue morphology and differentiation was monitored using histology and immunohistochemistry. Tissue metabolism was monitored using daily assessment of urea and lactate production. HC monolayer cultures served as controls. The 2-stage seeding procedure resulted in a 3-dimensional coculture system harboring HC cell clusters in multiple cell layers lining the generated mEC-seeded capillary structures. It was viable for 3 weeks, and HCs maintained their morphology and differentiation. Biochemical testing revealed stable metabolic activity of the tissue culture. In contrast, HCs cultured in monolayer showed morphological dedifferentiation and an unfavorable metabolic state. Our mEC-HC coculture represents a new approach toward a functional bioartificial liver-like tissue applicable as a test system for basic and applied research.

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毛细管化基质上的工程肝样组织的应用研究。
肝组织在体外具有功能并可存活数周,为基础研究和应用研究提供了良好的试验系统。本研究应用组织工程技术构建肝细胞(hc)与微血管内皮细胞(mECs)共培养体系,为新型体外生物人工肝模型奠定基础。将猪mec植入保存血管结构的去细胞猪空肠段。将猪肝细胞植入血管化支架,体外共培养3周。用组织学和免疫组织化学方法监测组织形态和分化。通过每日尿素和乳酸产量的评估来监测组织代谢。HC单层培养物作为对照。两个阶段的播种过程产生了一个三维共培养系统,在多层细胞层中包含HC细胞团,内衬生成的ec种子毛细血管结构。细胞存活3周,细胞形态和分化保持不变。生化试验表明组织培养物具有稳定的代谢活性。相比之下,单层培养的hcc表现为形态去分化和不利的代谢状态。我们的mEC-HC共培养代表了一种功能生物人工肝样组织的新方法,可作为基础和应用研究的测试系统。
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Tissue engineering
Tissue engineering CELL & TISSUE ENGINEERING-BIOTECHNOLOGY & APPLIED MICROBIOLOGY
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