Development of pre-seeded tissue-engineered vascular grafts in vitro

M. Khanova, L. Antonova
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Abstract

Current vascular surgery employs reconstruction of occluded blood vessels using autologous grafts. As a considerable proportion of patients lack healthy autologous vessels to be used as the grafts, the development of tissue-engineered, small-diameter vascular grafts has significant clinical relevance. Biodegradable vascular grafts, which have a defined degradation rate upon the implantation, provide an opportunity for the controlled vascular regeneration. Such polymer framework acts as a guiding matrix for organising the patient's newly formed tissues to ensure consistent and complete vessel remodeling. The crucial aspect of tissue-engineered vascular graft regeneration is endothelialisation, as non-endothelialised blood vessels suffer from the thrombosis if having < 5 mm diameter because of low blood flow. This review describes two approaches to stimulate endothelialization. The first is the biofunctionalization of the luminal surface with the bioactive peptides with the following in situ implantation. Using the body as a bioreactor, this approach relies on the selective recruitment of endothelial cells. The second approach includes in vitro pre-seeding of a luminal surface with an endothelial cell monolayer. The development of such pre-seeded vascular grafts requires the choice of an appropriate polymer for the manufacture of a 3D matrix, isolation of endothelial cell culture, and tuning of mechanical stimuli to control the cell specification during the pre-seeding. In addition to the pre-seeding of endothelial cells on the luminal surface, it is necessary to adapt them to the flow to prevent shedding or incorrect orientation. Cell adhesion can be enhanced by the attachment of extracellular matrix proteins to the luminal surface or by mimicking natural blood flow conditions. Sustained mechanical stimuli facilitate the adaptation of endothelial cells to the flow and contribute to the maturation of endothelial progenitor cells.
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体外预播种组织工程血管移植的研究进展
目前的血管外科手术采用自体移植物重建闭塞的血管。由于相当比例的患者缺乏健康的自体血管作为移植物,因此开发组织工程化、小直径血管移植物具有重要的临床意义。生物可降解血管移植物在植入时具有一定的降解率,为可控的血管再生提供了机会。这种聚合物框架作为引导基质组织患者新形成的组织,以确保一致和完整的血管重塑。组织工程血管移植再生的关键方面是内皮化,因为如果非内皮化血管的直径小于5mm,则由于血流量低而导致血栓形成。本文综述了两种刺激内皮化的方法。第一种是利用生物活性肽对管腔表面进行生物功能化,然后进行原位植入。利用身体作为生物反应器,这种方法依赖于内皮细胞的选择性募集。第二种方法包括体外预播种具有内皮细胞单层的管腔表面。这种预播种血管移植物的发展需要选择合适的聚合物来制造3D基质,分离内皮细胞培养,以及调整机械刺激来控制预播种期间的细胞规格。除了在管腔表面预先播种内皮细胞外,还需要使其适应血流以防止脱落或不正确的定向。细胞粘附可以通过细胞外基质蛋白附着在管腔表面或通过模拟自然血流条件来增强。持续的机械刺激促进内皮细胞对血流的适应,促进内皮祖细胞的成熟。
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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