静电纺丝类肝素细菌纤维素/壳聚糖仿生膜的表面微观结构与血液相容性

项目名称： 静电纺丝类肝素细菌纤维素/壳聚糖仿生膜的表面微观结构与血液相容性

项目编号： No.21264007

项目类型： 地区科学基金项目

立项/批准年度： 2013

项目学科： 数理科学和化学

项目作者： 尹学琼

作者单位： 海南大学

项目金额： 55万元

中文摘要： 细菌纤维素（BC）具有由微生物发酵合成、纤维束更细、力学性能更强、纯度更高等优于植物纤维素的优点，是制备医用高分子材料的理想天然大分子。本项目拟通过选择性化学改性制备具有设计结构的细菌纤维素硫酸酯（SBC）和羧甲基壳聚糖（CMC），再采用静电纺丝法将SBC 和CMC复合，获得具有类肝素化学结构和类细胞外基质微纳米形态的仿生膜（HBC），研究SBC和CMC化学结构及聚集态结构、纺丝参数等对HBC表面微观结构（化学组成、纤维束大小、孔隙大小及孔隙率、表面电荷、表面自由能等）和血液相容性的影响，探索表面微观结构与血液相容性的关系，以期获得调控HBC表面微观结构和血液相容性的方法，为设计和制备血液相容性良好的BC生物材料提供理论依据。目前未见选择性改性的SBC以及复合纤维素硫酸酯与CMC制备类肝素材料的报道。细菌纤维素和壳聚糖均是海南富产资源，本研究对促进地区生物资源开发利用具有重要基础理论意义。

中文关键词： 细菌纤维素硫酸酯；静电纺丝；壳聚糖；血液相容性；复合膜

英文摘要： Bacterial cellulose (BC) is an ideal natrual macromolecule raw material for biomedical polymer material because it has many better properties than plant cellulose, such as synthesized by microorganism, smaller fibre, stronger mechanical strength, higher purity, etc. In this project, BC and chitosan will be regioselectively modified to prepare BC sulfate (SBC) and carboxymethyl chitosan (CMC), respectively. Then SBC and CMC will be electrospunned to prepare bionic membrane (HBC) which has both similar chemical struture with heparin and similar nano and micro-morphology with extra cellular matrix. The effects of the chemical and aggregation structures of SBC and CMC, the electrospinning conditions on the surface microstructure (including surface chemical components, fibre size, pore size and porosity, surface charge and surface free energy) and the hemocompatibility of HBC will be investigated. And the relationship between the surface microstructure and hemocompatibility will be analyzed. It is expected to obtain the methods to control the surface microstructure and hemocompatibility of HBC. The project is aimed to supply theoretical data for design and preparation of hemocompatible BC biomedical material. No publications about regioselective substituted SBC and heparinoid from cellulose sulfate and CMC have been

英文关键词： Bacterial cellulose sulfate；electrospinning；chitosan；blood compatibility；composite membrane