Biofabrication of multiscale bone extracellular matrix scaffolds for bone tissue engineering.

IF 3.2 3区医学 Q3 CELL & TISSUE ENGINEERING

European cells & materials Pub Date : 2019-10-11 DOI:10.22203/eCM.v038a12

Daniel J. Kelly, Fiona E. Freeman, David C. Browe, P. Díaz-Payno, J. Nulty, S. V. Euw, Warren L. Grayson

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引用次数: 37

Abstract

Interconnected porosity is critical to the design of regenerative scaffolds, as it permits cell migration, vascularisation and diffusion of nutrients and regulatory molecules inside the scaffold. 3D printing is a promising strategy to achieve this as it allows the control over scaffold pore size, porosity and interconnectivity. Thus, the aim of the present study was to integrate distinct biofabrication strategies to develop a multiscale porous scaffold that was not only mechanically functional at the time of implantation, but also facilitated rapid vascularisation and provided stem cells with appropriate cues to enable their differentiation into osteoblasts. To achieve this, polycaprolactone (PCL) was functionalised with decellularised bone extracellular matrix (ECM), to produce osteoinductive filaments for 3D printing. The addition of bone ECM to the PCL not only increased the mechanical properties of the resulting scaffold, but also increased cellular attachment and enhanced osteogenesis of mesenchymal stem cells (MSCs). In vivo, scaffold pore size determined the level of vascularisation, with a larger filament spacing supporting faster vessel in-growth and more new bone formation. By freeze-drying solubilised bone ECM within these 3D-printed scaffolds, it was possible to introduce a matrix network with microscale porosity that further enhanced cellular attachment in vitro and increased vessel infiltration and overall levels of new bone formation in vivo. To conclude, an "off-the-shelf" multiscale bone-ECM-derived scaffold was developed that was mechanically stable and, once implanted in vivo, will drive vascularisation and, ultimately, lead to bone regeneration.

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骨组织工程中多尺度骨细胞外基质支架的生物制备。

相互连接的孔隙度对再生支架的设计至关重要，因为它允许细胞迁移、血管化和支架内营养物质和调节分子的扩散。3D打印是实现这一目标的一种很有前途的策略，因为它可以控制支架的孔径、孔隙度和互联性。因此，本研究的目的是整合不同的生物制造策略，以开发一种多尺度多孔支架，该支架不仅在植入时具有机械功能，而且还促进快速血管化，并为干细胞提供适当的线索，使其能够分化为成骨细胞。为了实现这一目标，聚己内酯(PCL)与去细胞化骨细胞外基质(ECM)功能化，以生产用于3D打印的骨诱导细丝。在PCL中加入骨ECM不仅提高了支架的力学性能，而且增加了细胞附着，促进了间充质干细胞(MSCs)的成骨。在体内，支架孔隙大小决定了血管化水平，较大的纤维间距支持更快的血管生长和更多的新骨形成。通过在这些3d打印支架内冷冻干燥溶解骨ECM，可以引入具有微孔隙度的基质网络，进一步增强体外细胞附着，增加血管浸润和体内新骨形成的总体水平。总之，一种“现成的”多尺度骨- ecm衍生支架被开发出来，它具有机械稳定性，一旦植入体内，将推动血管化，并最终导致骨再生。

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

European cells & materials 生物-材料科学：生物材料

CiteScore

6.00

自引率

6.50%

发文量

审稿时长

1.5 months

期刊介绍： eCM provides an interdisciplinary forum for publication of preclinical research in the musculoskeletal field (Trauma, Maxillofacial (including dental), Spine and Orthopaedics). The clinical relevance of the work must be briefly mentioned within the abstract, and in more detail in the paper. Poor abstracts which do not concisely cover the paper contents will not be sent for review. Incremental steps in research will not be entertained by eCM journal.Cross-disciplinary papers that go across our scope areas are welcomed.