Study of Pneumococcal Surface Protein, PspA, Incorporated in Poly(Vinyl Alcohol) Hydrogel Membranes

This study investigates poly(vinyl alcohol) (PVA) membranes as controlled release micro-matrices, which can be useful in therapeutic applications for optimizing the administration of drugs. Currently, the use of hydrogels is limited by protein size. This study investigates the delivery of PspA, a large protein of approximately 38 kD. Pneumococcal surface protein A (PspA) has been shown to provide protective immunity against pneumococcal infection and is considered as a pneumococcal vaccine. The protein release experiments demonstrated that from an initial pH 7.4, approximately 60% of PspA diffuse into a neutral environment with an initial burst and a declining rate reaching equilibrium. The results indicate that the protein was successfully incorporated and released from the membrane over time. The hydrogel and protein interaction is temporary, and the membrane system is ideal for protein drug delivery. The data confirm that the protein did not aggregate and was active after release. The protein release is promising and a step forward to develop microneedles to facilitate high molecular weight protein delivery as well as vaccine delivery.

Physicochemical Properties of Poly(Vinyl Alcohol)/Chitosan/Soluble Starch Composite Hydrogel

Fabricating of hydrogels based upon polymers and inorganic matter is an innovative replacement for the generation of adaptable matrices.In this study,the poly(vinyl alcohol)(PVA)/chitosan(CS)/soluble starch(SS)composite hydrogel was prepared by the solution blending method,in which SS was used as a cross-linking agent to cross-link with PVA in order to improve the stability of PVA in the tissue fluid.The composition and the thermal stability of hydrogels were characterized by Fourier transform infrared(FTIR)spectroscopy and thermo gravimetric analysis(TGA).The result shows that the PVA/CS/SS composite hydrogel possesses potentially morphological and thermal stability and can be used for tissue engineering.

天然纤维素/PVA复合水凝胶的形成机理及力学性能研究

为提高聚乙烯醇(PVA)水凝胶的力学性能,利用Na OH/尿素溶剂,通过物理交联循环冷冻-解冻法,制备了α-纤维素(α-CE)/PVA复合水凝胶。红外光谱,扫描电镜结果表明α-CE与PVA水凝胶基体形成互穿交联网状结构。研究发现α-CE与PVA分子链上的羟基间所形成的氢键使两者牢固结合。力学性能测试表明,复合水凝胶的力学性能得到了大幅度提高,当α-CE含量为4%(wt)时,复合水凝胶的拉伸强度以及在压缩型变量60%下的压缩应力分别由0.09和0.07 MPa提高到0.64和0.52 MPa,比纯PVA水凝胶提高了611%和643%。此外发现,α-CE能明显增强PVA水凝胶的弹性及压缩后的形变回复能力。

高透明度聚乙烯醇水凝胶的制备、表征及透明机理研究

用二甲基亚砜(DMSO)水溶液通过冷冻/解冻法制备了高透明度聚乙烯醇(PVA)水凝胶,使用差示扫描量热仪(DSC)、紫外吸收光谱、力学性能分析仪、紫外-可见分光光度计等分析了DMSO浓度对聚乙烯醇水凝胶透光率的影响,并表征了PVA水凝胶的含水率、结晶度、力学性能等性质。结果表明,用含量为80%(质量分数)的DMSO水溶液制备的PVA水凝胶得到了高达(99.8±0.2)%透明度,其抗拉强度达到3MPa以上,断裂拉伸率>600%。研究发现,DM-SO与水形成的1DMSO/2H2O网络结构能够限制PVA分子在三维方向的结晶,同时能够促进二维方向PVA晶体的生长。当DMSO含量为80%时,溶液中DMSO与水的比例略>1∶2,存在少量未形成1∶2网络结构的DMSO分子,该分子与PVA羟基形成氢键限制了PVA分子在二维方向的结晶,最终导致PVA水凝胶中PVA晶体的体积最小、PVA晶体的数目最多,从而得到了最高的水凝胶透明度和较好的力学性能。

聚乙烯醇水凝胶/钛合金摩擦磨损特性的正交试验研究

利用冷冻-解冻法制备聚乙烯醇(PVA)水凝胶,运用正交试验法在球-盘摩擦磨损试验机上研究滑动速度、载荷和润滑状态对PVA水凝胶/钛合金摩擦副摩擦系数的影响及在不同载荷下的磨损性能.结果表明:滑动速度、载荷和润滑状态3种因素对PVA水凝胶/钛合金球摩擦副的摩擦系数影响显著程度由高到低依次为载荷>滑动速度>润滑状态;在干摩擦和水润滑状态下,摩擦系数变化甚微,平均摩擦系数随滑动速度的增加而下降,随着载荷增加而升高;当转速从110 r/min升至220 r/min时,平均摩擦系数从0.038降至0.031,降幅达19.4%;当载荷从5 N增至10 N时,平均摩擦系数从0.027增至0.042,增幅达51.8%;PVA水凝胶的磨损率随载荷增加而降低且载荷对磨损率影响的显著程度逐渐降低;当载荷从5 N增至10 N时,磨损率降幅高达2.6倍,当载荷从10 N增至15 N时,仅下降35%.

聚氧化乙烯R-150辐射共聚水凝胶膜的理化性能研究

本工作研究了聚氧化乙烯 Ｒ１５０ 与聚乙烯醇（ Ｐ Ｖ Ａ）经辐射共聚交联所形成的水凝胶膜的理化性能。实验结果表明：聚氧化乙烯 Ｒ１５０ 共聚水凝胶的交联密度与辐射剂量呈正相关，与混合物质量分数呈负相关，与聚乙烯醇含量则未见明显相关性；该水凝胶的交联密度明显低于单纯聚乙烯醇水凝胶的交联密度。聚氧化乙烯 Ｒ１５０ 共聚水凝胶的平衡水含量与辐射剂量和聚乙烯醇含量呈负相关，与其混合物质量分数呈正相关，并且明显高于单纯聚乙烯醇的平衡水含量。聚乙烯醇水凝胶的硬度与辐射剂量呈正相关；聚氧化乙烯 Ｒ１５０ 共聚水凝胶的硬度与其混合物质量分数呈负相关，而与聚乙烯醇含量呈正相关。混合物质量分数对聚氧化乙烯 Ｒ１５０ 共聚水凝胶理化性能的影响与聚氧化乙烯 Ｒ１５０ 和聚乙烯醇的双重作用有关。

层状纳米纤维素膜/PVA复合水凝胶的制备与力学性能研究

采用叠层复合与物理相分离的方法制备了层状纳米细菌纤维素(BC)膜/聚乙烯醇(PVA)复合水凝胶.研究了聚乙烯醇的质量百分数、BC膜的复合层数以及制备条件对复合水凝胶力学性能的影响;通过扫描电镜(SEM)观察比较了复合水凝胶中BC膜层与PVA界面结合情况.结果表明,复合水凝胶的力学性能与PVA的质量百分数和BC膜含水量、BC膜的层数以及制备条件有关.PVA质量百分数较高,流动性变差,界面结合差,导致复合水凝胶力学性能下降.当PVA质量百分数为15%、BC膜的层数为2层时,在相同的温度和条件下制备的复合水凝胶界面黏结良好,弹性模量、抗拉强度为7.82、1.74 MPa.

含载药粒子壳聚糖温敏性水凝胶的制备及性能

制备了一种含载药粒子的壳聚糖/聚乙烯醇(CTS/PVA)温敏性水凝胶,研究了影响凝胶性能的因素.实验结果表明,与单纯的CTS/PVA水凝胶相比,含载药粒子的CTS/PVA水凝胶的凝胶强度增加了一倍左右,药物释放实验没有出现突释现象,释放速度较慢且平稳,缓释效果较好,14 d累积释放了32%.