激光微结构3D聚合物生物相容性植入物

M. Malinauskas, D. Baltriukienė, Antanas Kraniauskas, P. Danilevičius, E. Balčiūnas, A. Žukauskas, V. Purlys, R. Širmenis, V. Bukelskiene, R. Gadonas, V. Sirvydis, A. Piskarskas
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摘要

本文介绍了基于干细胞体外生长实验的生物相容性实验结果,以及飞秒激光三维微/纳米结构光聚合物在体内与聚合物植入物的反应。对微米级和厘米级快速三维支架材料的协同制备及其体内体外生物相容性进行了研究。系统的研究提供了一致的信息,对进一步开展细胞生长和组织工程实验具有重要意义。所选择的材料有四种不同的类别:著名的生物相容性杂化ORMOCER (Ormocore b59, Micro Resist)[1],广泛使用的可生物降解的二丙烯酸酯聚乙二醇(PEG-DA-258, Sigma-Aldrich)[2],纯丙烯酸酯AKRE (SR368, Sartomer)[3]和新型的高品质激光结构材料ORMOSIL (SZ2080, FORTH)[4]。所有材料都通过飞秒激光结构的适用性进行了评估,飞秒激光结构是一种快速灵活地生产3D微/纳米结构的技术。所有的光聚合物都可以用<分辨率为1µm,整体尺寸可达cm,从而实现具有所需孔径和孔隙率的支架的计算机模型。支架的典型尺寸为5 × 5 × 0.5 mm3的圆盘,孔径为25µm,孔隙率为40-60%。
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Laser microstructured 3D polymeric biocompatible implants
In this report we present experimental results on biocompatibility based on stem cell growth experiments in vitro as well as reaction of living organism to polymer implants in vivo of femtosecond laser 3D micro/nanostructurable photopolymers. A synergetic study on materials for rapid 3D scaffold fabrication having micrometer features and being centimeter in size, their biocompatibility in vitro and in vivo was done. The systematic study was performed providing consistent information which is important for further progress in cell growth and tissue engineering experiments. The chosen materials where of four different classes: well known biocompatible hybrid ORMOCER (Ormocore b59, Micro Resist) [1], widely used biodegradable di-acrylated poly(ethylene)glycol (PEG-DA-258, Sigma-Aldrich) [2], pure acrylate AKRE (SR368, Sartomer) [3] and novel high quality laser structurable material ORMOSIL (SZ2080, FORTH) [4]. All of the materials were evaluated by their suitability for femtosecond laser structuring, which is well established as a technique enabling rapid and flexible production of 3D micro/nanostructures. All photopolymers could be 3D structured with < 1 µm resolution and up to cm in overall sizes, thus materializing the computer models of the scaffolds with required pore sizes and porosities. The typical dimensions of scaffolds were 5 × 5 × 0.5 mm3 discs with 25 µm pore sizes and 40–60% porosity.
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