聚合物智能纳米凝胶的反相微乳液聚合法合成与性能

以N,N-亚甲基双丙烯酰胺(MBA)为交联剂,过硫酸铵和亚硫酸氢钠为氧化还原引发剂,采用反相微乳液聚合将丙烯酰胺(AM)、衣康酸(IA)和N-异丙基丙烯酰胺(NIPAM)共聚制备pH/温度双重刺激响应性智能纳米凝胶;探讨了IA和NIPAM质量比对智能纳米凝胶吸水率、吸盐率以及对温度和pH敏感性的影响,并通过透射电镜、热重分析对智能纳米凝胶的形貌和热稳定性进行了表征。结果表明,随着IA和NIPAM质量比的增加,智能纳米凝胶的吸水率和pH敏感性增加,吸盐率和温度敏感性降低,智能纳米凝胶表现出较明显的pH/温度双重刺激响应性。当吸水溶胀时间从1 h增加到5 h,智能纳米凝胶的平均粒径从0.54μm增加到8.08μm,能够满足渗透率小于1×10-3μm2、孔喉半径小于8μm的特低渗透油藏调剖堵水的要求。透射电镜表明,智能纳米凝胶基本为球形,形状较规整,粒径范围为30 nm^75 nm,平均粒径为47 nm;热重分析表明,智能纳米凝胶具有良好的热稳定性。

智能纳米凝胶的合成及其生物医学应用

本文首先阐述了高分子微凝胶材料的研究概况、智能纳米微凝胶的研究进展及其应用前景 ;然后系统分析了微凝胶的合成方法及其特点、智能纳米高分子凝胶的合成方法及粒径控制 ;最后详细介绍智能纳米栽药体系的特点、靶向与释放机制及其在基因工程治疗上的应用。

具有“开关”效应的纳米金/智能凝胶复合物导电机理

制备了纳米金/智能凝胶复合物,并对其导电行为进行了研究。研究表明:以智能凝胶为基体的复合物电性能表具有良好的"开关"效应;其导电过程在不同的温度区域符合不同的导电机理。低温时,复合物处于溶胀状态,其导电行为符合隧道效应和场制发射理论;高温时,复合物为收缩状态,其导电行为基本符合欧姆定律。

Research on Polymer Materials in Bio Medical and Its Application

Intelligent hydrogels is as drug carrier, and it has a good application prospect. There are some changes factors in the human environment, such as temperature, pH. Therefore, the temperature sensitive hydrogels and pH sensitive hydrogels can release system for drugs in the body. So the paper detailed descript a novel MWCNTs good dispersion of PMAA/MWCNTs nano hybrid hydrogels. The introduction of MWCNTs significantly increased the hydrogel pH response and mechanical strength, and depends on the MWCNTs component ratio, particle size and concentration of cross-linking agent. The study found, swelling rate of hybrid hydrogels was faster than the pure PMAA hydrogel, and the swelling behavior were explained. The compression stress-strain experiments should be found, MWCNTs load transfer plays an important role in improving the mechanical properties of the hybrid hydrogels network compression.