芹菜衍生的肝小叶模拟支架用于组织工程移植

Smart medicine Pub Date : 2022-12-16 eCollection Date: 2022-12-01 DOI:10.1002/SMMD.20220002
Jinglin Wang, Xueqian Qin, Bin Kong, Haozhen Ren
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引用次数: 0

摘要

脱细胞支架在肝脏组织工程中的价值已得到证实。该领域面临的挑战主要集中在如何有效消除支架的生物排斥反应以及寻找合适的肝细胞来源。在此,我们从肝小叶的天然微结构中获得灵感,提出了一种新型脱细胞芹菜衍生支架,用人诱导多能干细胞衍生肝细胞(hiPSC-Heps)培养生物工程肝组织构建。由于脱细胞芹菜衍生支架具有天然的中空通道、相互连接的多孔结构和优异的理化特性,因此所构建的生物工程肝组织能够在体外培养中保持 hiPSC-Heps 的活力和肝功能。基于这种生物工程肝组织,我们证明了其良好的生物相容性,并且将其植入裸鼠体内时,白蛋白(ALB)和周期性酸-希夫染色(PAS)的表达量显著提高。这些显著特性赋予了 hiPSC-Heps 集成脱细胞芹菜支架系统在肝脏移植和其他再生医学领域的广阔前景。
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Celery-derived scaffolds with liver lobule-mimicking structures for tissue engineering transplantation.

Decellularized scaffolds have a demonstrated value in liver tissue engineering. Challenges in this area are focused on effectively eliminating the biological rejection of scaffolds and finding a suitable liver cell source. Here, inspired by the natural microstructure of hepatic lobules, we present a novel decellularized celery-derived scaffold cultured with human-induced pluripotent stem cell-derived hepatocytes (hiPSC-Heps) bioengineering liver tissue construction. Because of the natural hollow channels, interconnected porous structures, and excellent physicochemical characterization of the decellularized celery-derived scaffold, the resultant bioengineering liver tissue can maintain the hiPSC-Heps viability and the hepatic functions in the in vitro cultures. Based on this bioengineering liver tissue, we have demonstrated its good biocompatibility and the significantly higher expressions of albumin (ALB) and periodic acid-schiff stain (PAS) when it was implanted in nude mice. These remarkable properties endow the hiPSC-Heps integrated decellularized celery scaffolds system with promising prospects in the field of liver transplantation and other regeneration medicine.

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