核壳聚乙烯醇-明胶静电纺纳米纤维支架的绿色制造

RAN Pub Date : 2017-04-01 DOI:10.11159/icnb17.106
Mustafa Şengör, M. A. Gulgun, S. Altıntaş
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引用次数: 0

摘要

在组织工程中,通过静电纺丝方法获得的天然/合成聚合物纤维复合材料支架支持细胞粘附和组织再生。然而,天然聚合物的静电纺丝需要使用有毒溶剂,这对细胞增殖和所生产的支架的生物相容性有负面影响,此外还需要使用酸性溶剂,这将导致体内大量的生物降解。在这里,我们提出了一种对患者甚至对使用有害和高挥发性溶剂的实验人员来说更安全的方法。利用两种聚合物模拟了组织细胞外基质的主要特征,即明胶和同轴组织纳米纤维。采用同轴静电纺丝技术制备了芯(PVA)-壳(明胶)纳米纤维。壳中的材料为组织细胞提供了识别位点,而芯材料提供了机械耐久性。与传统方法不同的是,本文提出的工作旨在通过仅使用去离子水作为溶剂来降低支架在损伤组织中的应用步骤。将PVA和明胶溶解在高于凝胶温度的去离子水中,而不是在有毒和酸性溶剂中溶解。后来,同轴静电纺丝增加了细胞扩散和机械刚度。用扫描电镜和透射电镜对样品进行了表征。实验结果表明,在8%浓度明胶溶液中制备的静电纺丝纤维具有珠状结构,而在相同浓度溶液中同轴制备的PVA和明胶则不具有珠状结构。此外,芯壳纤维的直径可低至180纳米。结果表明,聚乙烯醇有助于明胶纤维的均匀形成,具有较高的机械稳定性。导致这些结果的电子显微镜分析得到了萨班齐大学纳米技术研究和应用中心的支持。
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Green Manufacturing of Core-Shell Polyvinyl Alcohol-Gelatin Electrospun Nanofiber Scaffolds
Extended Abstract In tissue engineering, natural/synthetic polymer based fibrous composite scaffolds obtained via electrospinning method were shown to support the cell adhesion and tissue regeneration. However, electrospinning of natural polymers requires the use of toxic solvents that are negatively affecting the cell proliferation and biocompatibility of the produced scaffolds in addition to the usage of acidic solvents which will result in massive biodegradation inside the body[1] .Here, a method was proposed that is higher safety for the patient and even for the experimentalists who are using harmful and highly volatile solvents. Two types of polymers were used in the synthesis of the scaffolds by mimicking the key features of the tissue extracellular matrix which contains gelatin and coaxially organized nanofibers. Coaxial electrospinning technique was used to obtain core(PVA)-shell (gelatin) nanofibers. While material in the shell provides recognition sites for the tissue cells, core material provides mechanical endurance. Different from conventional methods, proposed work aims to lower the steps of application of the scaffold to the harmed tissue by using only deionized water as solvent. Instead of dissolving PVA and gelatin in toxic and acidic solvents, they were dissolved in the deionized water above the gelation temperature. Later, coaxial electrospinning generated increased cell spread and mechanical stiffness. The samples were characterized by scanning and transmission electron microscopy. Based on the experimental results it is concluded that electrospun fibers obtained from the 8% concentrated gelatin solution had a beaded structure, whereas the coaxially fabricated PVA and gelatin from the same concentration solutions did not show any beaded morphology. Also core-shell fibers have diameters down to 180 nm. This result showed that PVA aids to the uniform gelatin fiber formation which, may give higher mechanical stability. The electron microscopy analysis leading to these results has received support by the Nanotechnology Research and Application Center at Sabanci University.
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