共查询到17条相似文献,搜索用时 56 毫秒
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本文在可降解型聚氨酯分子设计,聚氨酯型组织工程支架制备方法,可降解聚氨酯多孔支架的生物学性能及可降解聚氨酯多孔支架在组织工程中的应用等几个方面对可降解聚氨酯型组织工程支架的最新研究进展作了综述。重点讨论了静电纺丝、冷冻干燥、相分离等几种聚氨酯多孔支架制备方法以及聚氨酯型组织工程支架的生物降解性质、生长因子嵌入、生物力学性能、生物相容性等生物学性能。目前的研究表明通过聚氨酯分子设计与各种支架制备方法结合可制得满足各种生物学性能的支架材料且这类材料已被证实在血管、软骨、硬质骨等各类组织工程中有重要的应用价值。但如何进一步提高聚氨酯支架材料的力学强度以使其能更好地与硬组织的力学性能相匹配以及如何降低或消除聚氨酯对人体的毒性仍是需要进一步研究的问题。 相似文献
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采用糖球模板法结合热致相分离技术,制备了孔径尺寸、内连通度及孔隙率高度可控的左旋聚乳酸(PLLA)支架材料,并通过扫描电镜(SEM)、红外光谱(FTIR)以及示差扫描量热法(DSC)对其空间结构及性能进行了系统研究.支架材料孔径从50μm到800μm及内连通孔径从10μm到200μm连续可调,微观孔壁结构根据不同溶剂可形成各异的微纳米结构.支架的制备对PLLA化学结构无显著影响,但相分离过程会不同程度地降低PLLA的结晶度. 相似文献
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在高压氮气作用下用溶液喷丝制备了组织工程支架.聚乙二醇/聚对苯二甲酸丁二醇酯(PEGT/PBT)共聚物的氯仿溶液经高压氮气流喷丝,继而沉积成无纺布.为了提高支架的生物相容性,将透明质酸水溶液喷涂到PEGT/PBT丝表面.结果表明,所制备的支架材料的生物相容性良好,细胞外基质透明酸能显著提高无纺布支架的生物相容性. 相似文献
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Andrew Darling Lauren Shor Saif Khalil Mark Mondrinos Peter Lelkes Selcuk Guceri Wei Sun 《Macromolecular Symposia》2005,227(1):345-356
A trend in developing biocompatible scaffolds for tissue engineering has been to seek an ideal single material for which a given cell type will exhibit favorable behavior. While an ideal single material has proven elusive, scaffold manufacture using combinations of specialist materials can produce more versatile structures. By controlling the percentage and architecture of material components, mechanical properties, cell attachment, and proliferation may be optimized for a given function. Three specialist materials, poly-ϵ-caprolactone (PCL), fibrin, and alginate, were incorporated into multi-component scaffolds for a series of experiments testing each component with culture of fibroblasts. The rigid and formable PCL provided structure, the fibrin pore-filler allowed for cell attachment, and alginate thread provided a nutrient transfer pathway in lieu of a vascular system. The efficacy of these scaffolds was judged on fibroblast distribution and population after 7-12 days of culture. 相似文献
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Polymeric scaffolds are three-dimensional, porous structures that may be used as a vehicle to deliver cells or therapeutic factors to repair tissue defects. Both biodegradable and non-biodegradable polymers have been developed for this purpose. In this review, we survey the polymers that have been investigated for cartilage tissue engineering and discuss the critical parameters for successful applications in the future. 相似文献
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Ya-Hui Liu Wei Liu Zi-Li Zheng Xin Wei Nouman Ali Shah Hao Lin Bai-Song Zhao Shi-Shu Huang Jia-Zhuang Xu Zhong-Ming Li 《高分子科学》2021,39(9):1191-1199
Mimicking the complex structure of natural bone remains a challenge for bone tissue scaffolds. In this study, a novel processing strategy was developed to prepare the bone-like scaffolds that are featured by highly oriented and fully interconnected pores. This type of biomimetic scaffolds was evolved from solid phase stretching of immiscible polycaprolactone(PCL)/poly(ethylene oxide)(PEO) blends with cocontinuous structure and the pore morphology was inherited from selective extraction of water ... 相似文献
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