Vascular Tissue Engineering Using Scaffold-Free Prevascular Endothelial-Fibroblast Constructs.

Q2 Biochemistry, Genetics and Molecular Biology
BioResearch Open Access Pub Date : 2019-01-08 eCollection Date: 2019-01-01 DOI:10.1089/biores.2018.0039
Sanket Pattanaik, Chase Arbra, Heather Bainbridge, Sarah Grace Dennis, Stephen A Fann, Michael J Yost
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引用次数: 12

Abstract

Vascularization remains a substantial limitation to the viability of engineered tissue. By comparing in vivo vascularization dynamics of a self-assembled prevascular endothelial-fibroblast model to avascular grafts, we explore the vascularization rate limitations in implants at early time intervals, during which tissue hypoxia begins to affect cell viability. Scaffold-free prevascular endothelial-fibroblast constructs (SPECs) may serve as a modular and reshapable vascular bed in replacement tissues. SPECs, fibroblast-only spheroids (FOS), and silicone implants were implanted in 54 Sprague Dawley rats and harvested at 6, 12, and 24 h (n = 5 per time point and implant type). We hypothesized that the primary endothelial networks of the SPECs allow earlier anastomosis and increased vessel formation in the interior of the implant compared to FOS and silicone implants within a 24 h window. All constructs were encapsulated by an endothelial lining at 6 h postimplantation and SPEC internal cords inosculated with the host vascular network by this time point. SPECs had a significantly higher microvascular area fraction and branch/junction density of penetrating cords at 6-12 h compared with other constructs. In addition, SPECs demonstrated perivascular cell recruitment, lumen formation, and network remodeling consistent with vessel maturation at 12-24 h; however, these implants were poorly perfused within our observation window, suggesting poor lumen patency. FOS vascular characteristics (microvessel area and penetrating cord density) increased within the 12-24 h period to represent those of the SPEC implants, suggesting a 12 h latency in host response to avascular grafts compared to prevascular grafts. Knowledge of this temporal advantage in in vitro prevascular network self-assembly as well as an understanding of the current limitations of SPEC engraftment builds on our theoretical temporal model of tissue graft vascularization and suggests a crucial time window, during which technological improvements and vascular therapy can improve engineered tissue survival.

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利用无支架血管内皮成纤维细胞构建血管组织工程。
血管化仍然是工程组织生存能力的一个重大限制。通过比较自组装血管前内皮-成纤维细胞模型与无血管移植物的体内血管化动力学,我们探索了在组织缺氧开始影响细胞活力的早期时间间隔内移植物血管化率的限制。无支架血管前内皮成纤维细胞结构(SPECs)可以作为替代组织的模块化和可重塑的血管床。将SPECs、仅成纤维细胞球体(FOS)和硅胶植入54只Sprague Dawley大鼠,并在6、12和24小时收获(每个时间点和植入物类型n = 5)。我们假设,与FOS和硅胶植入物相比,SPECs的初级内皮网络可以在24小时内更早地吻合并增加植入物内部的血管形成。所有构建体在植入后6小时被内皮衬里包裹,SPEC内索在这个时间点与宿主血管网络绝缘。在6-12 h时,SPECs的微血管面积分数和穿透索的分支/连接密度显著高于其他结构。此外,SPECs显示血管周围细胞募集、管腔形成和网络重塑与血管成熟在12-24小时一致;然而,这些植入物在我们的观察窗口内灌注不良,表明管腔通畅不良。FOS血管特征(微血管面积和穿透性脊髓密度)在12-24小时内增加,与SPEC植入物相比,表明宿主对无血管移植物的反应延迟了12小时。对体外血管前网络自组装的这种时间优势的了解,以及对目前SPEC植入的局限性的理解,建立在我们的组织移植血管化理论时间模型之上,并提出了一个关键的时间窗口,在此期间,技术改进和血管治疗可以提高工程组织的存活率。
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
BioResearch Open Access
BioResearch Open Access Biochemistry, Genetics and Molecular Biology-Biochemistry, Genetics and Molecular Biology (all)
自引率
0.00%
发文量
1
期刊介绍: BioResearch Open Access is a high-quality open access journal providing peer-reviewed research on a broad range of scientific topics, including molecular and cellular biology, tissue engineering, regenerative medicine, stem cells, gene therapy, systems biology, genetics, virology, and neuroscience. The Journal publishes basic science and translational research in the form of original research articles, comprehensive review articles, mini-reviews, rapid communications, brief reports, technology reports, hypothesis articles, perspectives, and letters to the editor.
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