左炔诺孕酮-聚3-羟基丁酸酯缓释微球的研究

目的：优化制备工艺,用可生物降解的成球材料制备缓释并有优良抗生育效果的左炔诺孕酮-聚3-羟基丁酸酯微球。方法：以均匀设计优化微球的液中干燥法制备工艺,用DTA确证含药微球的形成,对微球的外观、粒径、载药量、体外释药、稳定性及小鼠体内抗生育等进行了研究。结果：微球平均粒径为64 μm,(28.7～85.8) μm的微球占总数90％以上,微球中氯仿残留量低于0.001％,体外释药符合Higuchi方程,释药T_1/2比原药延长约1.8倍,4,25及40℃(RH 75%)放置3个月稳定。对小鼠具有抗生育效果。结论：微球的制备工艺满意,与原药相比,微球对小鼠有明显的缓释、延长抗生育时间和降低毒性的作用。     

肺靶向利福平聚乳酸微球的研究

在单因素考察的基础上进行正交试验设计,筛选出肺靶向利福平聚乳酸微球的最佳制备工艺条件;利用桨板法研究了微球的体外释药规律;考察了微球在不同温度下的稳定性;用新西兰兔为实验对象,研究了利福平聚乳酸微球的体内药动学及组织药物分布。结果制得的微球形态圆整,粒径在5～15μm范围内的占总体积的86.54%,微球平均粒径为9.00±4.08μm;包封率为31.9%;载药量为16.0%;体外释药方程为Q=20.77+10.12T_1/2(γ=0.9892);微球在冰箱4℃和室温(20～25℃)条件下性质稳定;体内实验表明微球具有长效和肺靶向双重作用。     

盐酸川芎嗪肺靶向微球的研究

用乳化法制备盐酸川芎嗪明肢微球,优化了工艺。对微球的外观、粒径与其分布、含量、体外释药、稳定性及体内分布等进行研究。结果表明平均粒径为12.65μm,粒径范围5.0～24.9μm占总数的87.5%,球内含药量平均为16.49%±0.49%(n=3),冰箱或室温放置稳定,体外释药符合一级动力学规律,释药t_1/2比原药延长约5倍。小鼠静注微球后20 min,在肺内的相对分布百分率明显高于其它组织与血液,与溶液对照组相比,提高近6倍。     

莪术油明胶微球用于肝动脉栓塞

目的　制备符合肝动脉栓塞要求的莪术油明胶微球(ZT-GMS)。方法　用正交设计优化了微球的制备工艺,对微球的制备工艺、粉体学性质、体外释药、初步稳定性和初步药效进行了研究。结果　球径在40～160 μm的微球占97.16%,平均产率为89.73%,平均含药量为2.13%,平均包封率为19.36%(均以莪术醇计)。体外释药12 h达80%,符合一级动力学模型,释药机理为溶蚀加扩散。稳定性考察实验结果表明其稳定性较好。肝动脉栓塞荷瘤大鼠实验结果表明大鼠平均生存率显著延长(P<0.01),肿瘤体积显著减小(P<0.01)。结论　微球的制备工艺及粒径分布较好,体外释药有明显的缓释作用,有一定疗效。     

关节腔内注射用氟比洛芬明胶微球

目的:制备关节腔注射用氟比洛芬明胶微球。方法:按均匀设计法筛选乳化冻凝法制备氟比洛芬明胶微球(FP GMS)的最佳制备工艺。结果:微球粒径范围为2.5～12.3μm,平均粒径为7.53μm,氟比洛芬含量为5.02%(w/w)。其体外释药符合Higuchi方程,稳定性实验表明,FP-GMS的稳定性良好,兔关节腔内注射后,与溶液剂对照组相比氟比洛芬体内平均驻留时间(MRT)显著延长(P<0.01),峰时比对照组延长2.03倍,峰浓度比对照组减小5.57倍。体内外相关性研究表明,FP-GMS体外累积溶出百分率与兔体内药物吸收分数呈显著相关(P<0.01)。结论:本法制备的氟比洛芬明胶微球粒径分布集中,粒径大小符合设计要求,体内外释药结果表明氟比洛芬明胶微球具有明显的缓释作用。     

多柔比星壳聚糖微球的制备及其特性研究

目的 以壳聚糖为载体材料,多柔比星为模型药物, 制备脑内局部给药缓释微球。方法 以液体石蜡为油相,L-抗坏血酸棕榈酸酯为交联剂,司盘-80为乳化剂,采用乳化化学交联技术制备多柔比星脑用微球。用动态透析法检测微球的体外释放特性。结果 多柔比星/壳聚糖的质量比为1：9的载药微球形态良好,粒径分布较为均匀,平均粒径为（9.41±2.43） μm,载药量为（8.49±0.37）%,包封率为（70.56±4.23）%。体外释放具有良好的缓释效果。结论 所优化的制备工艺稳定,适用于多柔比星壳聚糖脑用微球的制备.     

碱性成纤维细胞生长因子缓释微球的制备及其性质研究

目的 通过碱性成纤维细胞生长因子(bFGF)缓释微球的制备研究,为bFGF的缓释制剂提供科学依据。方法 以聚乳酸-聚乙二醇共聚物为包裹材料,采用复乳包囊法制备bFGF-聚乳酸-聚乙二醇共聚物缓释微球,并对微球的形态学、粒径分布、载药量、包封率和体外释药等进行研究。结果 所制备的微球表面光滑圆整,球体均匀度好;微球平均粒径为1.543±0.070 μm,平均径距为1.273±0.08;载药量和包封率分别为0.0267％和65.32％;微球的体外释药过程较为稳定,两周释药率为59.98％。结论 bFGF缓释微球比bFGF有明显的缓释作用。     

GM-l PLGA微球的制备及其体外释药性质研究

目的制备GM l PLGA微球，考察其一般性质和体外释药特性。方法应用W/O/W乳化溶剂干燥法制备GM l PLGA微球，测定微球粒径、载药量、包封率和体外释药曲线。结果微球形态规则，粒径约为（18±8） μm，载药量约为4.9%，包封率约为61%，微球体外释药规律符合Higuichi方程：Q=0.153t1/2+0.037 05(r=0.995)。结论GM l PLGA微球的制备工艺良好，体外释药呈明显的缓释作用。     

载体的组成对地西泮微球释药性能的影响

以天然细菌合成的可降解生物材料聚 3 羟基丁酸酯 (poly 3 hydroxybutyrate ,PHB) ,羟基丁酸酯 羟基戊酸酯共聚物 (polyhydroxybutyrate hydroxyvalerate ,PHBV) ,以及PHBV与D ,L PLA共混物 ,PHBV与明胶 (gel)双层结构材料作为药物载体 ,以抗焦虑药物地西泮 (diazepam ,DZP)为模药 ,用O/W单乳化与O/W /O双乳化溶剂蒸发法 ,制备了地西泮缓释微球 (DZP MS)。微球平均粒径约 30～ 40 μm,平均载药量 15 %～ 2 0 % ,包封率 5 9%～ 81%。用扫描电镜观察与比较了 4种微球结构形态 ,阐述了载体材料机构对释药性能影响 ,初步研究了PHBV/PLA微球动物体内药代动力学     

非布司他纳米缓释微丸的制备与体外释放度研究

摘 要 目的：制备非布司他纳米混悬剂,并进一步制备成缓释微丸,考察其体外释放度。方法: 采用高压均质法制备非布司他纳米混悬剂,通过流化床底喷包衣技术制备非布司他载药微丸,使用丙烯酸树脂 RL30D和丙烯酸树脂 RS30D包缓释层衣,制备成非布司他纳米缓释微丸,并评价其释药机制。结果:制备的非布司他纳米混悬剂的平均粒径为（212.5±36.3）nm,多相分散系统（PdI）为（0.193±0.018）,Zeta电位为（-12.4±0.3）mV,扫描电镜显示非布司他纳米混悬剂大小分布较均一;制备的非布司他纳米缓释微丸体外释药较为平缓,符合一级释放模型。结论:本研究制备非布司他纳米混悬缓释微丸体外释药平缓,为非布司他临床应用提供全新给药方案。     

植入瘤体内的氟尿嘧啶微球

目的为提高抗癌疗效,制备可植入瘤体内的氟尿嘧啶微球。方法以聚乳酸为载体材料,O/W型乳化挥发法制备氟尿嘧啶微球;考察了微球性质、体外释药及植入实体瘤Lewis肺癌的抑瘤效果。结果微球载药量为(10.30±0.20)%,包封率为(68.3±1.5)%;外观圆整光滑,为物理包载;突释很少,体外释药T_1/2较原药延长约168倍,属扩散-溶蚀机制;抑瘤率可达60.6%,降低了毒副作用。结论O/W型乳化挥发法制备的氟尿嘧啶聚乳酸缓释微球,植入瘤体内杀灭肿瘤细胞将可能成为肿瘤化疗的有效方法。     

顺铂壳聚糖微球的制备及特性研究

对顺铂壳聚糖微球的制备、载药量、大小及分布、形态及表面状态、体外释放及降解性进行了研究。微球用乳化-化学交联技术制备,平均粒径为74.80μm,顺铂含量为20.83%±0.36%。电镜扫描显示,微球球形圆整,表面粗糙。生理盐水中放置1h微球轻微溶胀,其体外释药符合一级方程,微球经⁶⁰Co辐射灭菌达到无菌要求。犬肝动脉栓塞后一个月,病理切片可见栓塞区仍有壳聚糖微球存在。     

Preparation and testing of cefquinome-loaded poly lactic-co-glycolic acid microspheres for lung targeting

The aim of this study was to prepare cefquinome-loaded poly lactic-co-glycolic acid (PLGA) microspheres and to evaluate their in vitro and in vivo characteristics. Microspheres were prepared using a spry drier and were characterized in terms of morphology, size, drug-loading coefficient, encapsulation ratio and in vitro release. The prepared microspheres were spherical with smooth surfaces and uniform size (12.4?±?1.2?μm). The encapsulation efficiency and drug loading of cefquinome was 91.6?±?2.6 and 18.3?±?1.3%, respectively. In vitro release of cefquinome from the microspheres was sustained for 36?h. In vivo studies identified the lung as the target tissue and the region of maximum cefquinome release. A partial lung inflammation was observed but disappeared spontaneously as the microspheres were removed through in vivo decay. The sustained cefquinome release from the microspheres revealed its applicability as a drug delivery system that minimized exposure to healthy tissues while increasing the accumulation of therapeutic drug at the target site. These results indicated that the spray-drying method of loading cefquinome into PLGA microspheres is a straightforward method for lung targeting in animals.     

Preparation oral levofloxacin colon-specific microspheres delivery: in vitro and in vivo studies

The aim of this study was to prepare levofloxacin-loaded chitosan microspheres and to evaluate their in vitro and in vivo characteristics. Glutaraldehyde-crosslinked microspheres were prepared using a spray-drying method, and characterized in terms of the morphological examination, particle size distribution, entrapment efficiency, drug loading and in vitro release. Pharmacokinetics and colon biodistribution studies were used to evaluate that microspheres have more advantage than the conventional formulations. The surface morphology of the freeze-dried microspheres were smooth, discrete with a regular spherical to near-spherical shape. Size of the microspheres after freeze-drying was 4.96?±?0.76?μm and well-distributed. The zeta potential of microspheres was ?29.3?±?2.1?mV. An average drug loading of 9.3?±?0.4% and encapsulation efficiency of 81.1?±?4.7% of levofloxacin microspheres were obtained with the optimized preparation parameters. The cumulative release rate of levofloxacin microspheres was followed by a sustained release and fitted for classic Higuchi kinetic model. In vivo studies showed that chitosan microspheres are thought to have the potential to maintain levofloxacin concentration within target ranges for a long time, decreasing side effects caused by concentration fluctuation, ensuring the efficiency of treatment and improving patient compliance by reducing dosing frequency. It also does not cause any harmful or toxic effect in colon and rectum as evaluated by histopathologic studies.     

肝动脉栓塞米托蒽醌乙基纤维素微球的研究

利用正交实验设计法,优选适用于肝动脉栓塞的米托蒽醌乙基纤维素微球制备条件和工艺;采用动态透析法研究了该微球的体外释药规律;根据混悬液的稳定性理论,优选并制备了适于临床肝动脉介导栓塞使用的米托蒽醌乙基纤维素微球混悬注射液。结果表明∶在优化工艺条件下制得的米托蒽醌乙基纤维素微球外形圆整,球径在40～200μm范围内的占总数的91.9%,平均球径为110.24±38.19μm;包封率为55.6%;载药量为12.5%;体外释药符合单指数模型,释药方程为lg(Y_∞-Y)=-0.116t-1.198×10^-3(γ=0.9992,t₅₀=2.6h);其混悬液适于临床应用。用狗进行的实验表明肝血药浓度高,平均驻留时间比注射剂长2.45倍。     

Formulation,development, and performance evaluation of metoclopramide HCl oro-dispersible sustained release tablet

The present study was undertaken to develop and evaluate an oro-dispersible, sustained release tablet of metoclopramide HCl. The technology was comprised of developing sustained release microparticles, and compression of resultant microspheres into a fast dispersible tablet by direct compression. The microspheres of metoclopramide HCl were prepared by an emulsification-solvent evaporation method using ethylcellulose as the matrix polymer. The prepared microspheres were evaluated for morphology, particle size, entrapment efficiency, and in vitro drug release characteristics. Scanning electron microscopy demonstrated spherical particles with a mean diameter of 81.27 ± 5.87 μm and the drug encapsulation efficiency was found to be 70.15 ± 3.06%. The process and formulation variables such as rotation speed, polymer concentration, and drug concentration influenced the drug encapsulation efficiency and in vitro drug release. Optimized microspheres were compressed into tablets which were comprised of metoclopramide HCl microspheres, 53% (w/v) of D-mannitol granules, 7% (w/w) of Polyplasdone XL 10, and 0.5% (w/w) of calcium stearate. The tablets demonstrated a hardness of 59 ± 3 N, friability of 0.21% and disintegration time of 27 ± 3 sec. The formulations were subjected to stability studies as per ICH guidelines and were found to be stable after a 6 month study. In vivo experiments conducted in rats demonstrated that a constant level of metoclopramide HCl in plasma could be maintained for up to 20 h at a suitable concentration for antiemetic activity. An appropriate combination of excipients made it possible to obtain orally disintegrating sustained release tablets of metoclopramide HCl using simple and conventional techniques.     

响应面法优化肉苁蓉松果菊苷肠溶微球的制备

目的 制备肉苁蓉松果菊苷肠溶微球,筛选最佳制备工艺,并考察其体外释放特性。方法 用离子凝胶-干燥法制备肉苁蓉松果菊苷肠溶微球,以包封率为考察指标,用响应面法优化其制备工艺。结果 制备肉苁蓉松果菊苷肠溶微球最佳工艺参数：海藻酸钠浓度36.33 mg/ml、氯化钙浓度10.82 mg/ml、壳聚糖浓度10.93 mg/ml。结论 优选的工艺稳定、可行,制备的微球包封率高、缓释效果较好。     

苯妥英钠羧甲基壳聚糖缓释微球的制备及其对牙周常见致病菌的抑菌效果研究

目的 采用正交试验法优化制备苯妥英钠羧甲基壳聚糖微球（PHT-CMCS-MS）的处方,观察其组分对2种牙周常见致病菌的抑菌效果。方法 采用乳化化学交联固化法制备PHT-CMCS-MS,以载药量、包封率为指标,采用正交试验设计优化制备工艺,观察载药微球表面形态,测定微球的释药性能及初步稳定性。并采用洞-平板法对牙周常见致病菌牙龈卟啉单胞菌和伴放线放线杆菌进行抑菌实验对比,以抑菌圈直径作纵横向比较,分析药物影响。结果 制备的PHT-CMCS-MS外观形态圆整,粒径分布较均匀,粒径分布范围为0.8~12µm,载药量为8.2%,包封率为48.9%,PHT-CMCS-MS在PBS（pH=7.3）的溶液中具有明显缓释效果。体外抑菌试验结果显示较高浓度的羧甲基壳聚糖、苯妥英钠及其缓释微球对Pg、Aa生长均有不同程度的抑菌作用。结论 结合苯妥英钠及羧甲基壳聚糖良好的生物活性及抑菌作用,制备载药微球缓释作用良好,可结合手术或局部注射辅助应用于牙周治疗,达到促进牙周组织再生的目的。