铜掺杂聚合物/生物活性玻璃复合支架的制备与表征

RAN Pub Date : 2016-04-01 DOI:10.11159/NDDTE16.104
Nuray Yerli, M. E. Taygun, Yakup Yürektürk, S. Küçükbayrak
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引用次数: 0

摘要

组织损伤和退行性疾病(如大骨缺损)是世界范围内导致器官衰竭和死亡的最严重的人类健康问题之一[1-3]。骨组织工程是修复骨缺损的一种很有前途的方法,特别是由于创伤、感染、肿瘤或遗传畸形导致的大骨缺损[2-4]。在骨组织工程的应用中,支架的发展及其结构加工变得越来越重要。三维(3D)支架应该显示出高度多孔,开放的结构,以允许植入物的适当血管化,以及营养物质和废物通过支架的流动。骨组织工程支架的主要问题包括合适的支架基质材料的使用、支架孔隙率和孔隙特性的控制、支架的机械强度以及支架的降解性能[5]。理想的生物活性多孔支架在骨组织工程中的应用,应满足血管生成、骨刺激和抗菌等多功能特性,用于治疗大型骨缺损[2]。在这些特性中,血管生成对新组织的形成和修复起着重要作用,因为血管为新形成的组织提供营养和氧气。与使用生长因子相比,通过生物材料支架输送无机离子刺激血管生成可以降低治疗成本并防止生物副作用,因此近年来引起了相当大的兴趣[6]。这项研究的重点是先进的生物活性支架,使组织内部生长和控制治疗离子的输送。为了能够实现这一目标,在第一阶段生物活性玻璃(成分重量;SiO2为45%,Na2O为24.5%,P2O5为6%,CaO为24.5%,CuO为2%),具有抗菌和血管生成性能。生物活性玻璃制备完成后,采用泡沫复制技术制备生物活性玻璃/聚合物三维复合多功能支架。然后,他们被涂上不同百分比的海藻酸盐(重量;1,2,3 %),以改善其性能。在不同的时间点(1、7、14和28天)将获得的支架浸入模拟体液(SBF)中,研究样品的生物活性和生物降解行为。采用不同的表征技术对所得支架的物理和微观结构性能进行了测定。扫描电镜研究表明,支架具有高孔隙结构,具有良好的孔隙连通性。在SBF中浸泡28 d后,支架表面明显形成羟基磷灰石层。x射线衍射(XRD)和傅里叶变换红外光谱(FTIR)分析也证实了所获得的支架的生物活性。利用红外光谱(FTIR)获得了羟基磷灰石的特征化学键,并用XRD分析结果检测了羟基磷灰石的程度。对复合材料支架的物理力学性能进行了研究和比较。采用电感耦合等离子体(ICP)分析了支架在SBF中的铜释放行为,结果表明海藻酸盐包被支架可以控制铜离子的释放,但与未包被支架相比,铜离子的释放量较少。综上所述,三维复合材料支架在骨组织工程领域具有广阔的应用前景。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fabrication and Characterization Of Copper Doped Polymer/Bioactive Glass Composite Scaffolds
Extended Abstract Tissue damage and degenerative diseases such as large bone defects are among the most human health issues which lead to organ failure and death all over the world [1-3]. Bone tissue engineering emerges a promising approach to repair bone defects, especially large bone defects resulting from trauma, infections, tumors or genetic malformations [2-4]. The development of scaffolds and their processing into structures are becoming increasingly important in bone tissue engineering applications. Three-dimensional (3D) scaffolds should show a highly porous, open structure to allow a proper vascularisation of the implant, as well as the flow of nutrients and waste products through the scaffold. Major issues of bone tissue engineering scaffolds include the use of appropriate matrix materials for scaffolds, control of porosity and pore characteristics of scaffolds, mechanical strength of scaffolds as well as scaffold degradation properties [5]. Ideal bioactive porous scaffolds, which are used in bone tissue engineering applications, should meet multifunctional properties such as angiogenesis, osteostimulation and antibacterial properties for the treatment of large bone defects [2]. Among these properties, angiogenesis plays an important role for the formation and repair of new tissue because blood vessels provide for newly formed tissues to receive nutrients and oxygen. The stimulation of angiogenesis by the delivery of inorganic ions from biomaterial scaffolds provide to reduce cost of treatments and also prevent biological side effects when compared to the use of growth factors and so it has been attracting considerable interest in recent years [6]. The focus of this study is on advanced bioactive scaffolds enabling internal growth of tissue and controlled delivery of therapeutic ion. To be able to achieve this goal, in the first stage bioactive glass (composition in weight; 45% SiO2, 24.5% Na2O, 6% P2O5, 24.5% CaO, 2% CuO) were developed which have antibacterial and angiogenic properties. After the production of bioactive glass, bioactive glass/polymer 3D composite multifunctional scaffolds were fabricated by using foam replication technique. Then, they were coated with alginate at different percentages (in weight; 1, 2, 3 %) to improve the properties of them. The obtained scaffolds were immersed in simulated body fluid (SBF) at different time points (1, 7, 14 and 28 day) to investigate the bioactivity and biodegradability behavior of the samples. Physical and micro structural properties of the obtained scaffolds were determined by using different characterization techniques. Scanning electron microscopy investigations showed that scaffolds have highly porous structure with a good pore interconnectivity. After immersion in SBF for 28 days, the hydroxyapatite layer formation was observed significantly on the surface of the scaffolds. X-Ray Diffraction (XRD) and Fourier Transform Infrared Spectroscopy (FTIR) analysis also verified the bioactivity of the obtained scaffolds. Characteristic chemical bonds which belongs to hydroxyapatite were obtained with FTIR and degree of hydroxyapatite was detected from the result of XRD analysis. Physical and mechanical properties of the composite scaffolds were studied and compared with each other. Inductively Coupled Plasma (ICP) analysis was also applied to investigate the copper release behavior of the scaffolds in SBF and the results indicated that the alginate coated scaffolds allowed controlled release of copper ions but in low amounts compared to uncoated ones. The overall results showed that three dimensional composite scaffolds could be promising candidates for bone tissue engineering applications.
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