Department of Mechanical Engineering, Indian Institute of Technology Delhi, New Delhi, 110016, India.
Stem Cell Facility, Centre of Excellence for Stem Cell Research, All India Institute of Medical Sciences, New Delhi, 110029, India.
Mater Sci Eng C Mater Biol Appl. 2020 Jan;106:110247. doi: 10.1016/j.msec.2019.110247. Epub 2019 Oct 14.
Biodegradable porous iron having topologically ordered porosity and tailorable properties as per the required application has been the major requirement in the field of biodegradable biomaterials. Hence, in the present study, iron scaffolds with the topologically ordered porous structure were developed and for the first time, the effect of the variation in the topology on the in vitro degradation behaviour, cytocompatibility and hemocompatibility were investigated. Iron scaffold samples were fabricated using a novel process based on the combination of 3D printing and pressureless microwave sintering. To investigate the effect of topology, two different types of topological structures namely Truncated Octahedron (TO) (with variable strut size) and Cubic (C) were used. From the morphological characterization, it was found that fabricated iron scaffold possessed interconnected porosity varying from 50.70%-80.97% which included the random microporosities in the strut and designed macroporosity. Furthermore, it was inferred that the topology of the iron scaffold significantly affected its degradation properties and cytocompatibility. Increase in the weight loss, corrosion rate and reduction in cell viability with the reduction in porosity were obtained. The maximum corrosion rate and weight loss achieved was 1.64 mmpy and 6.4% respectively. Direct cytotoxicity test results revealed cytotoxicity, while prepared iron scaffold samples exhibited excellent hemocompatibility and anti-platelet adhesion property. A comparative study with relevant literature was performed and it was established that the developed iron scaffold exhibited favorable degradation and biological properties which could be tailored to suit appropriate bone tissue engineering applications.
具有拓扑有序多孔结构和可根据所需应用进行定制的可生物降解多孔铁一直是可生物降解生物材料领域的主要要求。因此,在本研究中,开发了具有拓扑有序多孔结构的铁支架,并且首次研究了拓扑结构变化对体外降解行为、细胞相容性和血液相容性的影响。铁支架样品是使用基于 3D 打印和无压微波烧结相结合的新工艺制造的。为了研究拓扑结构的影响,使用了两种不同类型的拓扑结构,即截断八面体 (TO)(具有可变支柱尺寸)和立方 (C)。从形态特征来看,发现制造的铁支架具有 50.70%-80.97%的相互连接的孔隙率,其中包括支柱中的随机微孔和设计的大孔。此外,推断铁支架的拓扑结构显著影响其降解性能和细胞相容性。随着孔隙率的降低,获得了重量损失、腐蚀速率和细胞活力降低的增加。达到的最大腐蚀速率和重量损失分别为 1.64 mmpy 和 6.4%。直接细胞毒性试验结果显示出细胞毒性,而制备的铁支架样品表现出优异的血液相容性和抗血小板黏附性能。与相关文献进行了比较研究,结果表明,所开发的铁支架表现出良好的降解和生物学性能,可以根据适当的骨组织工程应用进行定制。
