Hydrostatic pressure under hypoxia facilitates fabrication of tissue-engineered vascular grafts derived from human vascular smooth muscle cells in vitro

IF 9.4 1区医学 Q1 ENGINEERING, BIOMEDICAL

Acta Biomaterialia Pub Date : 2023-10-02 DOI:10.1016/j.actbio.2023.09.041

Tomoyuki Kojima , Takashi Nakamura , Junichi Saito , Yuko Hidaka , Taisuke Akimoto , Hana Inoue , Christian Nanga Chick , Toyonobu Usuki , Makoto Kaneko , Etsuko Miyagi , Yoshihiro Ishikawa , Utako Yokoyama

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引用次数: 0

Abstract

Biologically compatible vascular grafts are urgently required. The scaffoldless multi-layered vascular wall is considered to offer theoretical advantages, such as facilitating cells to form cell-cell and cell-matrix junctions and natural extracellular matrix networks. Simple methods are desired for fabricating physiological scaffoldless tissue-engineered vascular grafts. Here, we showed that periodic hydrostatic pressurization under hypoxia (HP/HYP) facilitated the fabrication of multi-layered tunica media entirely from human vascular smooth muscle cells. Compared with normoxic atmospheric pressure, HP/HYP increased expression of N-myc downstream-regulated 1 (NDRG1) and the collagen-cross-linking enzyme lysyl oxidase in human umbilical artery smooth muscle cells. HP/HYP increased N-cadherin-mediated cell-cell adhesion via NDRG1, cell-matrix interaction (i.e., clustering of integrin α5β1 and fibronectin), and collagen fibrils. We then fabricated vascular grafts using HP/HYP during repeated cell seeding and obtained 10-layered smooth muscle grafts with tensile rupture strength of 0.218–0.396 MPa within 5 weeks. Implanted grafts into the rat aorta were endothelialized after 1 week and patent after 5 months, at which time most implanted cells had been replaced by recipient-derived cells. These results suggest that HP/HYP enables fabrication of scaffoldless human vascular mimetics that have a spatial arrangement of cells and matrices, providing potential clinical applications for cardiovascular diseases.

Statement of significance

Tissue-engineered vascular grafts (TEVGs) are theoretically more biocompatible than prosthetic materials in terms of mechanical properties and recipient cell-mediated tissue reconstruction. Although some promising results have been shown, TEVG fabrication processes are complex, and the ideal method is still desired. We focused on the environment in which the vessels develop in utero and found that mechanical loading combined with hypoxia facilitated formation of cell-cell and cell-matrix junctions and natural extracellular matrix networks in vitro, which resulted in the fabrication of multi-layered tunica media entirely from human umbilical artery smooth muscle cells. These scaffoldless TEVGs, produced using a simple process, were implantable and have potential clinical applications for cardiovascular diseases.

Abstract Image

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缺氧条件下的静水压有助于体外从人血管平滑肌细胞中制备组织工程血管移植物。

迫切需要具有生物相容性的血管移植物。无支架的多层血管壁被认为提供了理论优势，例如促进细胞形成细胞-细胞和细胞-基质连接以及天然的细胞外基质网络。需要简单的方法来制造生理无支架组织工程血管移植物。在这里，我们发现缺氧条件下的周期性静水压（HP/HIP）促进了完全由人类血管平滑肌细胞制造多层膜介质。与常压相比，HP/HIP增加了人脐动脉平滑肌细胞中N-myc下游调节1（NDRG1）和胶原交联酶赖氨酰氧化酶的表达。HP/HIP通过NDRG1、细胞-基质相互作用（即整合素α5β1和纤连蛋白的聚集）和胶原原纤维增加了N-钙粘蛋白介导的细胞-细胞粘附。然后，我们在重复细胞接种过程中使用HP/HIP制造血管移植物，并在5周内获得拉伸断裂强度为0.218至0.396MPa的10层平滑肌移植物。植入大鼠主动脉的移植物在1周后内皮化，5个月后专利，此时大多数植入的细胞已被受体衍生的细胞取代。这些结果表明，HP/HIP能够制造具有细胞和基质空间排列的无支架人血管模拟物，为心血管疾病提供潜在的临床应用。意义陈述：就机械性能和受体细胞介导的组织重建而言，组织工程血管移植物（TEVGs）理论上比假体材料更具生物相容性。尽管已经显示出一些有希望的结果，但TEVG的制造过程是复杂的，并且仍然需要理想的方法。我们重点研究了子宫内血管发育的环境，发现机械负荷与缺氧相结合促进了体外细胞-细胞和细胞-基质连接以及天然细胞外基质网络的形成，这导致了完全由人脐动脉平滑肌细胞制备多层膜介质。这些使用简单工艺生产的无支架TEVG是可植入的，对心血管疾病有潜在的临床应用。

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

Acta Biomaterialia 工程技术-材料科学：生物材料

CiteScore

16.80

自引率

3.10%

发文量

776

审稿时长

30 days

期刊介绍： Acta Biomaterialia is a monthly peer-reviewed scientific journal published by Elsevier. The journal was established in January 2005. The editor-in-chief is W.R. Wagner (University of Pittsburgh). The journal covers research in biomaterials science, including the interrelationship of biomaterial structure and function from macroscale to nanoscale. Topical coverage includes biomedical and biocompatible materials.