5-氟尿嘧啶壳聚糖微球的制备及其释药性能

5-氟尿嘧啶壳聚糖微球的制备及其释药性能;药物缓释剂     

磁性氟尿嘧啶壳聚糖微球的制备及其释药性能

磁性氟尿嘧啶壳聚糖微球的制备及其释药性能;氟尿嘧啶;壳聚糖;磁性微球;缓释     

海藻酸钠-壳聚糖-桑椹红微囊的制备

以海藻酸钠-壳聚糖为复合囊材采用锐孔法制备桑椹红微囊,探讨了海藻酸钠浓度、壳聚糖浓度、Ca Cl2浓度、桑椹红浓度、针头孔径、下滴高度、温度、转速等因素对微囊包封率的影响。确定了最佳制备工艺条件为海藻酸钠浓度4.0%、壳聚糖浓度2.5%、氯化钙浓度2.0%、桑椹红浓度0.50%、针头孔径0.390mm、下滴高度4cm、温度为20℃、转速为300r·min-1。制得的微囊药物含量为11.28%,包封率为88.93%。     

壳聚糖─海藻酸钠微囊对蛋白质控制释放的研究

采用乳化法制备了可注射用壳聚糖海藻酸钠微囊, 其粒径小于２００ μｍ ,且具有相对较窄的近似高斯分布。牛血清白蛋白作为模型药物在微囊中的包埋率可超过５０ ％ 。通过壳聚糖在海藻酸钠微囊表面的复合,牛血清白蛋白从微囊中的持续释放时间从几个小时延长到半个月以上。     

聚乳酸载力福平微球底制备及其释药性能

药物释放;聚乳酸载力福平微球底制备及其释药性能     

大茴香醛改性海藻酸钠凝胶的制备及释药性能

在酸催化下使海藻酸钠与对甲氧基苯甲醛(又名大茴香醛)发生缩醛化反应,使其疏水改性,并将其制备成凝胶。利用红外(FTIR)、荧光、透射电镜(TEM)、扫描电镜(SEM)、紫外、热重分析(TGA)对产物进行了表征。结果表明,大茴香醛成功地与海藻酸钠发生了反应。该凝胶可以作为药物载体对牛血清白蛋白进行包埋释放,结果发现,改性后的产物其载药率和缓释性能比未改性的海藻酸钠有了一定的提高。     

海藻酸钠的疏水改性及释药性能研究

为了提高对疏水性药物的负载量和缓释作用,将海藻酸钠氧化后与十二胺反应使其进行疏水改性.对改性后聚合物结构进行了表征.研究了聚合物在水溶液及盐溶液中的粘度变化;将聚合物分散于NaCl/CaCl2的混合溶液中制备成凝胶微球,对药物布洛芬进行了包埋释放实验.结果表明,疏水改性后的海藻酸钠粘度增加,其凝胶微球对布洛芬负载量提高,具有较好的缓释作用.     

氧化石墨烯-海藻酸钠-壳聚糖复合支架的制备及表征

通过冷冻干燥技术,将不同量的氧化石墨烯与海藻酸钠和壳聚糖复合,构建复合支架材料.研究了不同的氧化石墨烯含量(质量分数0, 0.3%, 0.5%, 0.7%, 1%)对支架材料微观结构、孔隙率、溶胀比、体外降解性能、机械性能及生物相容性的影响,以确定复合支架中最佳氧化石墨烯含量.研究结果表明,复合材料呈固态海绵状结构,具有一定的形态可塑性;扫描电子显微镜观察发现,各组支架均为三维网状结构,随着氧化石墨烯含量的增加,孔隙尺寸逐渐降低,孔壁厚度增加,孔隙尺寸在140～240μm之间;随氧化石墨烯含量的增加,复合支架溶胀比和体外降解速率逐渐降低,而机械强度明显增强;体外细胞毒性显示,当氧化石墨烯质量分数为0.3%时,细胞存活率最高,而当氧化石墨烯含量增高时,细胞活性会被明显抑制,造成细胞死亡.因此,氧化石墨烯在复合支架中最佳含量为0.3%.     

海藻酸钠和壳聚糖静电复合弹性支架的制备和表征

通过静电作用和相分离技术制备海藻酸钠/壳聚糖静电复合弹性支架,研究了冷冻温度和固含量对支架材料孔径的影响及组分比对材料力学性能、亲水性、降解性能和生物相容性的影响.固含量为2%(质量分数)及冷冻温度为-24℃时,支架孔径为110~170μm,并且亲水性良好,平衡溶胀度大于1400%.改变固含量和组分比可调控材料的力学性能;循环力学测试表明,湿态支架具有良好的弹性和一定的耐疲劳性;降解速率可由组分比调控;兔脂肪干细胞(rASCs)在支架上的培养结果表明,羧基和氨基摩尔比为2∶1和1∶1时细胞以聚集体存在;羧基和氨基摩尔比为1∶2时细胞黏附于支架上,实现细胞黏附/聚集体的调控.     

低碱法制备羧甲基壳聚糖及表征

低碱法制备羧甲基壳聚糖及表征;壳聚糖;羧甲基壳聚糖;取代度;特性粘度;低碱法     

低分子量壳聚糖制备与应用研究进展

低分子量壳聚糖因具有特殊的生物活性而日益受到人们的关注。本文概要介绍了近5年来国内外低分子量壳聚糖的研究进展,包括低分子量壳聚糖的制备方法,如酶降解法、酸水解法、氧化降解法、物理法等,以及低分子量壳聚糖在农业、医药、抗菌、化妆品、食品等方面的应用。     

海藻酸钠和壳聚糖聚电解质微胶囊及其生物医学应用

本文综述了天然多糖聚电解质海藻酸钠和壳聚糖的结构与化学性能（包括凝胶性能、生物相容性、生物可降解性及温和反应性）;微胶囊制备技术及其强度性能和膜渗透性评价方法;微胶囊作为细胞载体在体内分泌治疗性物质（如：胰岛素、多巴胺）或分解代谢毒性物质（如：尿素）,作为三维药物筛选系统、干细胞增殖分化研究工具,以及药物释放载体等生物医学领域的研究进展;最后讨论了天然多糖微胶囊研究与应用中需要解决的问题。     

褐藻酸钠的高效凝胶色谱行为及其分子量参数测定

用高效凝胶色谱法测定褐藻酸钠的分子量参数。比较了褐藻酸钠样品与非极性标样DextranT500的高效凝胶色谱行为的差异,讨论了进样浓度和进样体积对结果的影响。     

载细胞海藻酸钠/壳聚糖微胶囊的化学破囊方法研究

以海藻酸钠-壳聚糖-海藻酸钠微胶囊(简称ACA微胶囊)为研究体系,建立了一种生理条件下ACA微胶囊的化学破囊方法,破囊过程充分考虑了对囊内生物物质活性的保持.以微生物细胞PichiapastorisGS115和动物细胞L929为模型,以NaHCO₃和Na₃C₆H5O₇·2H₂O为破囊液基本组分,考察了破囊液对ACA微胶囊的破囊效果及破囊过程对囊内细胞活性的影响.结果表明,破囊操作可在30s内完成,破囊率为100%,微胶囊膜完全溶解,破囊后细胞存活率在85%以上.     

低分子量N-羧丁酰壳聚糖的合成及其吸湿保湿性

低分子量N-羧丁酰壳聚糖的合成及其吸湿保湿性;低分子量壳聚糖;低分子量N-羧丁酰壳聚糖;吸湿性;保湿性     

Investigation of the Interactions in Complexes of Low Molecular Weight Chitosan with Ibuprofen

Complexation between ibuprofen and low molecular weight chitosan (LMWC) was studied. LMWC was prepared from high molecular weight chitosan using the acid hydrolysis method. The complexes were investigated by using DSC, FT-IR and liquid-state ¹H-NMR. Molecular mechanics (MM) calculations were used to give insight into the stoichiometry of the interaction of chitosan with ibuprofen. The results showed that complexation of ibuprofen with LMWC involves ionic interaction between the ammonium group of LMWC and the carboxylate anion of ibuprofen. It was also shown that it is more efficient to prepare the complexes using lower concentration solutions of the polymer. These results were supported by molecular mechanics calculations. The experimental results may explain the discrepancies in the literature where, in many studies, the concentration of chitosan and its low average molecular weight were not considered to be important factors in the complexation process.     

Preparation of Water-Soluble Acetylaminoglucan with Low Molecular Weight and Its Anti-Tumor Activity on H22 Tumor-Bearing Mice

In this study, a novel low molecular weight of acetylaminoglucan (AGA) was obtained and its antitumor activity on H22 tumor-bearing mice was investigated. The results of UV, HPLC and FT-IR showed that AGA present high purity with low molecular weight of 2.76 × 10³ Da. Animal experiments showed that AGA could inhibit the proliferation of tumor cells in H22 tumor-bearing mice by protecting the immune organs, enhancing the phagocytosis ability of macrophages, killing activity of NK cells and proliferation capacity of lymphocytes, improving the levels of cytokines in vivo and regulating the distribution of lymphocyte subsets, and the tumor inhibition rate reached to 52.74% (50 mg/kg). Cell cycle determination further indicated that AGA could induce apoptosis of tumor cells and arrests it in S phase. These results will provide a data basis for the potential application of AGA in pharmaceutical industry.     

低截留分子量PPES超滤膜的制备

以杂萘联苯聚醚砜(PPES)为膜材料、N-甲基吡咯烷酮(NMP)为溶剂、有机小分子丙醇(PrOH)和无机小分子氯化锂(LiCl)作为混合添加剂,采用相转化法制备超滤膜.研究了聚合物浓度、混合添加剂配比、凝胶浴温度等对膜结构和性能的影响.结果表明:随聚合物浓度的增大,膜的纯水通量下降,截留率升高;混合添加剂,在PrOH含量为12%、LiCl含量为1.5%时,可制得纯水通量为252 L/(m2·h),对聚乙二醇1000(PEGl000)截留率为96%的超滤膜;随凝胶浴温度的升高,膜的纯水通量增加.     

Characterization of Chitosan/Alginate Self-Assembled Nanoparticles as a Protein Carrier

The aim of this study was to evaluate the effect of the polymeric ratios on the characteristics of chitosan/alginate (ch/alg) self-assembled nanoparticles and their potential as protein delivery vehicle. The nanoparticles were prepared using proper mixing of polymers in presence or absence of bovine serum albumin (BSA) as a protein model. Three formulations of nanoparticles comprising ch/alg ratios of 2:1, 1:1, and 1:2 were prepared. Size, shape and zeta potential of the formulations were studied by scanning electron microscopy (SEM) and nanosizer instruments. FTIR, and differential scanning calorimetery (DSC) studies were performed to investigate polymer-polymer or polymer-protein interactions. Release profiles and entrapment efficiencies of the nanoparticles were determined by calorimetric technique using appropriate techniques. Entrapment efficiency was 70% for ch/alg ratio of 1:1, 65% for 1:2, and 60% for 2:1. The z-average size of the nanoparticles were 403, 205, and 318 nm for ch/alg ratios of 2:1, 1:1, and 1:2, respectively. Average zeta potentials were ?47, +15, ?25 mV for 2:1, 1:1, and 1:2 as well. Considering the favorable features required for protein delivery systems, ch/alg (1:1) due to its smallest size, highest loading, and most homogenous shape was regarded as the best ratio.     

盐酸阿米替林/海藻酸钠/壳聚糖微球的制备及释放性能

盐酸阿米替林;海藻酸钠;壳聚糖;微球;交联;乙二醇二缩水甘油醚