Institute of Science and Technology for Ceramics (ISTEC), National Research Council (CNR) , Faenza, Italy .
Tissue Eng Part A. 2017 Dec;23(23-24):1423-1435. doi: 10.1089/ten.TEA.2017.0028. Epub 2017 Aug 4.
The need of synthetic bone grafts that recreate from macro- to nanoscale level the biochemical and biophysical cues of bone extracellular matrix has been a major driving force for the development of new generation of biomaterials. In this study, synthetic bone substitutes have been synthesized via biomimetic mineralization of a recombinant collagen type I-derived peptide (RCP), enriched in tri-amino acid sequence arginine-glycine-aspartate (RGD). Three-dimensional (3D) isotropic porous scaffolds of three different compositions are developed by freeze-drying: non-mineralized (RCP, as a control), mineralized (Ap/RCP), and mineralized scaffolds in the presence of magnesium (MgAp/RCP) that closely imitate bone composition. The effect of mineral phase on scaffold pore size, porosity, and permeability, as well as on their in vitro kinetic degradation, is evaluated. The ultimate goal is to investigate how chemical (i.e., surface chemistry and ion release from scaffold) together with physical signals (i.e., surface nanotopography) conferred via biomimetic mineralization can persuade and guide mesenchymal stem cell (MSC) interaction and fate. The three scaffold compositions showed optimum pore size and porosity for osteoconduction, without significant differences between them. The degradation tests confirmed that MgAp/RCP scaffolds presented higher reactivity under physiological condition compared to Ap/RCP ones. The in vitro study revealed an enhanced cell growth and proliferation on MgAp/RCP scaffolds at day 7, 14, and 21. Furthermore, MgAp/RCP scaffolds potentially promoted cell migration through the inner areas reaching the bottom of the scaffold after 14 days. MSCs cultured on MgAp/RCP scaffolds displayed higher gene and protein expressions of osteogenic markers when comparing them with the results of those MSCs grown on RCP or Ap/RCP scaffolds. This work highlights that mineralization of recombinant collagen mimicking bone mineral composition and morphology is a versatile approach to design smart scaffold interface in a 3D model guiding MSC fate.
需要合成骨移植物,从宏观到纳米尺度重建骨细胞外基质的生化和生物物理线索,这是开发新一代生物材料的主要驱动力。在这项研究中,通过仿生矿化富含三氨基酸序列精氨酸-甘氨酸-天冬氨酸(RGD)的重组 I 型胶原蛋白衍生肽(RCP)合成了合成骨替代品。通过冷冻干燥开发了三种不同组成的各向同性多孔支架:未矿化(RCP,作为对照)、矿化(Ap/RCP)和存在镁的矿化支架(MgAp/RCP),它们紧密模仿骨组成。评估了矿物相对支架孔径、孔隙率和渗透性的影响,以及它们的体外动力学降解。最终目标是研究化学信号(即支架表面化学和离子释放)与物理信号(即表面纳米形貌)如何通过仿生矿化赋予并指导间充质干细胞(MSC)的相互作用和命运。三种支架组成物表现出最佳的骨传导孔径和孔隙率,彼此之间没有明显差异。降解测试证实,与 Ap/RCP 支架相比,MgAp/RCP 支架在生理条件下具有更高的反应性。体外研究表明,在第 7、14 和 21 天,在 MgAp/RCP 支架上细胞生长和增殖增强。此外,MgAp/RCP 支架在 14 天后有可能通过内部区域促进细胞迁移,到达支架底部。与在 RCP 或 Ap/RCP 支架上生长的 MSC 相比,在 MgAp/RCP 支架上培养的 MSC 表现出更高的成骨标志物的基因和蛋白表达。这项工作强调了模拟骨矿物质组成和形态的重组胶原蛋白矿化是设计 3D 模型中智能支架界面以指导 MSC 命运的多功能方法。
