Human endothelial cells form an endothelium in freestanding collagen hollow filaments fabricated by direct extrusion printing

Q3 Biochemistry, Genetics and Molecular Biology Biomaterials and biosystems Pub Date : 2022-12-01 DOI:10.1016/j.bbiosy.2022.100067

Ina Prade , Michaela Schröpfer , Caroline Seidel , Claudia Krumbiegel , Tina Hille , Frank Sonntag , Stephen Behrens , Florian Schmieder , Birgit Voigt , Michael Meyer

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Abstract

Fiber-shaped materials have great potential for tissue engineering applications as they provide structural support and spatial patterns within a three-dimensional construct. Here we demonstrate the fabrication of mechanically stable, meter-long collagen hollow filaments by a direct extrusion printing process. The fibres are permeable for oxygen and proteins and allow cultivation of primary human endothelial cells (ECs) at the inner surface under perfused conditions. The cells show typical characteristics of a well-organized EC lining including VE-cadherin expression, cellular response to flow and ECM production. The results demonstrate that the collagen tubes are capable of creating robust soft tissue filaments. The mechanical properties and the biofunctionality of these collagen hollow filaments facilitate the engineering of prevascularised tissue engineering constructs.

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人内皮细胞在直接挤压打印制备的独立胶原中空纤维中形成内皮

纤维状材料在组织工程应用中具有巨大的潜力，因为它们在三维结构中提供结构支撑和空间模式。在这里，我们展示了机械稳定的制造，米长的胶原蛋白中空丝通过直接挤压印刷工艺。纤维对氧气和蛋白质具有渗透性，允许在灌注条件下在内表面培养原代人内皮细胞(ECs)。细胞表现出组织良好的EC衬里的典型特征，包括VE-cadherin表达，细胞对流动的反应和ECM的产生。结果表明，胶原蛋白管能够产生坚固的软组织纤维。这些胶原蛋白中空纤维的力学特性和生物功能为血管化组织工程结构的工程设计提供了便利。

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