基因重组人干扰素-α微球的制备及理化性质研究

目的:制备基因重组人干扰素-α聚乳酸乙醇酸微球,并考察其理化性质。方法:采用复乳溶剂挥发法制备干扰素-α微球,考察其形态、粒径、分布、载药量、包封率及微粉学性质,并通过体外释药考察其缓释效果,用气/质联用法测定其有机溶剂残留量。结果:所制微球球形圆整,粒度分布范围较窄,平均粒径为45.54μm,包封率达83.49%,载药量为8.03%,流动性等较好。微球体外释药行为符合Higuchi方程,其有机溶剂残留量<0.05%。结论:所制干扰素-α微球各方面理化性质良好。     

替莫唑胺乳酸-羟基乙酸共聚物微球的制备及表征

采用乳化-溶剂挥发法制备替莫唑胺微球,考察了制备工艺中影响微球粒径、载药量和包封率的主要因素,筛选处方工艺.按优化工艺制得的微球形态圆整,表面光滑,平均粒径62.2μm,载药量7.5%,包封率83.5%,体外试验表明该载药微球有明显的缓释效果.     

阿司匹林缓释微球的制备及其体外释药性能研究

目的:制备阿司匹林缓释微球,并考察其体外释药性能。方法:采用改良的乳化溶剂挥发法,以聚乳酸-羟基乙酸共聚物(PLGA)为载体材料、载药量和包封率为指标,固定PLGA为100 mg正交设计试验优化阿司匹林缓释微球的阿司匹林用量、外水相体积、丙酮-二氯甲烷体积比和聚乙烯醇(PVA)浓度,对最优处方所制微球进行验证和体外释放度考察。倒置显微镜和电子显微镜下观察微球表面形态,激光粒度分析仪考察微球粒径。结果:PLGA为100 mg时的最优处方:阿司匹林用量为20 mg、外水相体积为150 ml、丙酮-二氯甲烷体积比为1∶1、PVA浓度为1 mg/100 ml;所制微球的平均粒径为139.95μm,电镜下微球表面光滑圆整,载药量为8.6%,包封率为33%,240 h体外累积释放度为85.56%。结论:成功制得具有明显缓释作用的阿司匹林缓释微球。     

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。     

雌二醇生物可降解缓释微球的制备四氢呋喃的加入对微球性质的影响

目的　在本实验中 ,以生物可降解和生物相容性良好的聚乳酸 (PLA)或乳酸 -乙醇酸共聚物 (PLGA)为载体材料制备含有雌二醇药物的缓释微球 ,考察在制备过程中水溶性更强的四氢呋喃的加入对微球性质的影响。方法　以乙酸乙酯和四氢呋喃为有机溶剂、采用乳化 -溶剂萃取法制备含药微球 ,分别从成球性、粒径、包封率和体外释药等方面 ,进行制备工艺研究以及微球相关性质的研究。结果　在乙酸乙酯中加入四氢呋喃 ,使包封率降低 ,但在乙酸乙酯体积比大于 5 0 %时 ,增加四氢呋喃的用量对包封率无明显影响。相同条件下 ,在考察范围内 ,粒径随四氢呋喃用量比例的增大而增大 ,而载体的性质和微球含药量是影响微球释药的主要因素。结论　尽管在制备过程中的油相中加入了水溶性更强的四氢呋喃 ,但是通过控制制备工艺和条件 ,仍然可以得到球形态好、有适当粒径分布范围、载药量高并且突释程度小的雌二醇生物可降解缓释微球     

载羟基喜树碱聚乳酸微球的制备与体外释药研究

目的:研究载羟基喜树碱的聚乳酸微球的制备方法并考察其体外释药性质。方法:以PLA为成膜材料,采用改良乳化-溶剂挥发法,制备载羟基喜树碱的聚乳酸微球并优化制备工艺;对载药微球进行表征;超声介导下进行载药微球的体外释药试验。结果:微球粒径在1～7μm,大小均一;羟基喜树碱浓度在10mg.mL-1下,载药微球包封率为62.2%,载药量为1.69%;药物体外释药符合Higuchi方程。结论:采用乳化-溶剂挥发法,以PLA为成膜材料可制得具有较高包封率的羟基喜树碱微球,有望实现降低羟基喜树碱给药量、减少不良反应,提高靶向性的目标。     

布比卡因缓释微球的制备及体外释药特性评价

目的研究布比卡因缓释微球制备方法并对其体外释药特性进行评价。方法采用紫外分光光度法测定布比卡因微球载药量、包封率;采用HPLC法测定微球体外释放;通过正交设计优选微球制备工艺;以乳酸羟基乙酸共聚物为载体,使用乳化溶剂挥发法制备布比卡因微球;用扫描电镜观察所得微球的粒径和形态;通过体外释药实验考察布比卡因乳酸羟基乙酸共聚物微球的缓释作用。结果微球载药量、包封率和体外释放的测定方法符合方法学要求;按照优选处方制备所得的微球为圆整球体,表面多孔,呈蜂窝状,粒径50~100μm之间的微球占80%;体外释放符合Ritger-Peppas方程,t1/2=242.05 h。结论乳化溶剂挥发法适用于布比卡因乳酸羟基乙酸共聚物微球的制备,所制得的微球形态圆整,在体外具有明显缓释作用。     

正交试验法优化西咪替丁中空微球的处方工艺及微球体外释药模式研究

目的优化西咪替丁中空微球的制备条件并对其释药模式进行研究。方法采用溶剂扩散-挥发法制备西咪替丁中空微球。以微球包封率、收率及漂浮率为指标,采用正交试验法优化处方工艺,最终得到分散性良好的微球。以优化处方制备的中空微球进行体外溶出实验,进行释放机理的探讨。结果采用正交试验法优化了西咪替丁中空微球的处方工艺,在最优处方下制得的微球外观圆整,微球的粒径较均匀,载药量与包封率分别为19.48%与65.37%,在人工胃液中12 h漂浮率可达99%。结论该方法制备工艺简单、重现性好,制得的中空微球在人工胃液中具有良好的漂浮及缓释特性,体外释药符合Higuchi模型。     

GM-1缓释微球的制备及体外释药特性研究

目的:制备GM-1的乳酸/羟基乙酸共聚物(PLGA)微球,考察其一般性质和体外释药特性。方法:应用W/O/W型乳化溶剂干燥法制备GM-1的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+0.03705(r=0.9950)。结论:GM-1微球体外释药特性及其制备工艺良好,体外具有明显缓释作用。     

盐酸雷尼替丁中空缓释微球的制备及其特性

目的:以盐酸雷尼替丁(RH)为模型药物,研究中空微球的制备,并对制备过程中的影响因素进行考察。方法:以乙基纤维素(EC)为载体材料,乙醇/乙醚为混合溶剂,采用溶剂扩散-挥发法制备盐酸雷尼替丁中空微球。以产率、平均粒径、载药量和微球形态为指标,考察了处方工艺对微球性能的影响。并考察了EC粘度,RH/EC比例以及粒径对微球释药速率的影响。结果:中空微球产率为84.51%,粒径分布均匀,平均粒径632μm,载药量13.71%,包封率55.86%。电镜扫描显示:微球外观圆整光滑,内部为中空结构。体外释药研究表明随着EC粘度的增加释药速率降低;随着RH/EC比例和搅拌速度的增加释药速率增加。最终所得到的中空微球缓释可达24h,体外漂浮实验表明在人工胃液中可持续漂浮48h以上。结论:该处方工艺简便可行,制得的盐酸雷尼替丁中空微球在人工胃液中缓释性和漂浮性良好。中空微球有望成为吸收窗药物的又一新型给药系统。     

Disodium norcantharidate loaded poly(epsilon-caprolactone) microspheres I. Preparation and evaluation

Poly(varepsilon-caprolactone) (PCL) microspheres encapsulating disodium norcantharidate (DSNC), a drug in salt form and with high water solubility, were prepared by s/o/w solvent evaporation technique and characterized in terms of size, morphology, encapsulation efficiency and drug release. The viscosity of s/o dispersion was crucial to the successful encapsulation of DSNC. Scanning electron microscopy (SEM) studies showed that the drug-loaded microspheres had coarse surface and porous internal structure. The analysis of X-ray diffraction (XRD) indicated that there was no interaction between DSNC and PCL, but the degree of crystallinity of PCL decreased with the introduction of the drug. The drug release profiles indicated an initial burst release followed by a slow release, and a further investigation into the release mechanism implied that the release of DSNC from PCL microspheres was caused by a combination of diffusion and osmotic pressure.     

超微粒制备系统制备利培酮长效注射微球

目的:制备利培酮长效注射微球并进行体外释药动力学考察。方法:选用聚乳酸-羟基乙酸共聚物[poly(D,L-lactic-co-glycolic acid),PLGA]为载体,采用新型超微粒制备系统制备利培酮PLGA微球。以转碟上聚合物析出量、丝状物的形成和微粒表面形态为考察指标单因素实验优化制备工艺参数及处方;观察微球表面形态,测定其粒径、包封率、考察其体外释药动力学。结果:20%和30%载药量的微球表面均光滑圆整,分散性好;其包封率分别为94.7%和93.94%,中值粒径分别为31.65和28.13μm;持续释药时间均可达16 d,释放数据用释放动力学方程拟合符合一级和Higuchi方程。20%载药量微球1 h释药率仅为4.2%,突释率低,且其释放速率和释放时间与市售利醅酮微球(恒德)快速释放期基本一致而无延滞期。结论:超微粒制备系统(UPPS)可单步骤制备长效微球,工艺稳定,简单可行,有望成为一种适合工业微球制备技术。UPPS制备的20%载药量微球可开发为释放2周的制剂,由于无释放延滞期,将比市售品更具临床优势。     

beta-Estradiol biodegradable microspheres: effect of formulation parameters on encapsulation efficiency and in vitro release

The purpose of this work was to study the effect of organic solvent and surfactant type on the in vitro release behavior in general and on the burst release in particular of beta-estradiol from PLA/PLGA microspheres. Also the effect of these variables on the encapsulation efficiency was investigated. The microspheres were prepared by solvent evaporation technique using dichloromethane (DCM), ethyl acetate (EtAc), tetrahydrofuran (THF), chloroform (CHCl3) or acetone (AC) as organic solvent and polyvinyl alcohol (PVA), Tween 80, sodium lauryl sulfate (SLS) or benzalkonium chloride (BKCI) as surfactant. The obtained microspheres were tested for encapsulation efficiency and in vitro drug release using 50% methanol/buffer pH 7.4 as dissolution medium. EtAC and PVA formulations showed the highest encapsulation efficiency and the lowest burst release. These microspheres were further characterized for particle size distribution, SEM and zeta potential. The results suggested that these materials could be starting materials to prepare a beta-estradiol biodegradable controlled delivery system.     

载药蒙脱石/丙烯酸树脂微球的制备与体外释放性能的研究

目的以丙烯酸树脂为膜材制备载药蒙脱石/丙烯酸树脂微球并考察其体外释放性能。方法以盐酸倍他洛尔为模型药物,采用O/O溶剂挥发法制备蒙脱石载药微球,通过正交实验设计,考察柠檬酸三乙酯及甘油用量、乳化剂与膜材比例及用量、内外相体积比等因素对微球载药量、包封率、体外释放性能的影响,采用扫描电镜对其外观形态进行表征。结果所得微球外观圆整,粒径分布较均匀,平均粒径为20.7μm,平均载药量为14.31%±0.47%,平均包封率为94.35%±1.01%。结论该法制备载药蒙脱石丙烯酸树脂微球是可行的,体外释放研究表明微球具有一定的缓释作用。     

Effects of the rate of solvent evaporation on the characteristics of drug loaded PLLA and PDLLA microspheres

We investigated the effects of the rate of solvent removal by varying ambient pressure at a fixed temperature on the morphology, particle sizes, drug encapsulation efficiency and releases pattern of lidocaine loaded poly-L-lactatide (PLLA) and poly-D,L-lactatide (PDLLA) microspheres, prepared with O/W emulsion-solvent evaporation process. Prepared in the fast rate of solvent evaporation (FRSE) process by reducing ambient pressure, smoothly morphological surface of drug loaded PLLA and PDLLA microspheres was observed. While in the normal rate of solvent evaporation (NRSE) process, roughness or pinhole surface was only found at drug loaded PLLA microspheres. Fabricated in the FRSE process, both PLLA and PDLLA microspheres showed smaller particle sizes and lower drug encapsulation efficiencies than those prepared in NRSE process. In regard to two materials, PLLA microspheres had higher drug encapsulation efficiencies than PDLLA ones for both processes. Although initial burst releases of drug were observed for both PLLA and PDLLA microspheres prepared in whatever solvent removal process, drug release for PLLA microspheres was slightly less than that for PDLLA ones in the earlier stage of drug release. However, in the subsequent stage of drug release, there was no difference between two materials. In corporation with different crystalline characteristics of PLA polymer and its derivatives, FRSE process by reducing ambient pressure could be further applied to produce different characteristics of microspheres for drug delivery.     

利福平丝素蛋白载药微球的制备及性能研究

目的通过测定利福平丝素蛋白微球的载药量、包封率及释放度,考察乳化转速、有机溶剂与丝素蛋白溶液比例,对微球的制备方法进行优化,筛选微球的最佳制备方法。方法采用乳化法制备利福平丝素蛋白微球,以不同转速、有机溶剂与丝素蛋白溶液不同比例分别制备利福平丝素蛋白微球,采用扫描电镜观察微球的形态,用紫外分光光度法测定微球的载药量、包封率及释放度,以形态、载药量、包封率及释放度为指标,筛选微球的最佳制备方法。在此基础上,采用最佳处方制备3批利福平丝素蛋白微球,对微球的形态、粒径、包封率、载药量和释放度进行考察。结果有机溶剂与丝素蛋白溶液体积比为4∶1、转速为200 r·min^-1时所得利福平丝素微球形态均匀,近似球形,载药量和包封率较高,所得载药微球有较好的缓释作用。以最佳处方制得微球载药量为66.1%±0.87%,包封率为87.80%±2.23%。结论有机溶剂与丝素蛋白溶液体积比为4∶1、转速为200 r·min^-1时载药量、包封率和释放度较好,故选择此处方为利福平丝素蛋白微球的最佳制备处方。     

Effects of solvent evaporation rate on the properties of protein-loaded PLLA and PDLLA microspheres fabricated by emulsion-solvent evaporation process

This paper investigated the effects of the rate of solvent removal by varying the ambient pressure at a fixed temperature on the morphology, particle size, encapsulation efficiency and release pattern of albumin-loaded PLLA and PDLLA microspheres, prepared by the W/O/W emulsion-solvent evaporation process. For PLLA microspheres prepared either with a fast rate of solvent evaporation (FRSE) or a normal rate of solvent evaporation (NRSE) process, the difference in morphology was minor. In contrast, the different processes did affect the morphology of PDLLA microspheres. Large (surface) pores were observed for PDLLA microspheres fabricated with a FRSE process, while a smooth surface was seen in those with a NRSE process. With the FRSE process, both PLLA and PDLLA microspheres showed smaller particle sizes and lower albumin encapsulation efficiencies than those prepared in the NRSE process. PLLA microspheres prepared with the NRSE process had higher drug encapsulation efficiencies than PDLLA ones, but this was not the case for the FRSE process. An initial burst release of albumin was observed for both PLLA and PDLLA microspheres prepared with the NRSE process, while a lesser burst release was seen for those prepared with the FRSE process. In subsequent stages of drug release, PLLA microspheres prepared with the two different processes showed differences, but this was not the case for PDLLA ones.     

Effects of solvent evaporation rate on the properties of protein-loaded PLLA and PDLLA microspheres fabricated by emulsion-solvent evaporation process

This paper investigated the effects of the rate of solvent removal by varying the ambient pressure at a fixed temperature on the morphology, particle size, encapsulation efficiency and release pattern of albumin-loaded PLLA and PDLLA microspheres, prepared by the W/O/W emulsion-solvent evaporation process. For PLLA microspheres prepared either with a fast rate of solvent evaporation (FRSE) or a normal rate of solvent evaporation (NRSE) process, the difference in morphology was minor. In contrast, the different processes did affect the morphology of PDLLA microspheres. Large (surface) pores were observed for PDLLA microspheres fabricated with a FRSE process, while a smooth surface was seen in those with a NRSE process. With the FRSE process, both PLLA and PDLLA microspheres showed smaller particle sizes and lower albumin encapsulation efficiencies than those prepared in the NRSE process. PLLA microspheres prepared with the NRSE process had higher drug encapsulation efficiencies than PDLLA ones, but this was not the case for the FRSE process. An initial burst release of albumin was observed for both PLLA and PDLLA microspheres prepared with the NRSE process, while a lesser burst release was seen for those prepared with the FRSE process. In subsequent stages of drug release, PLLA microspheres prepared with the two different processes showed differences, but this was not the case for PDLLA ones.     

双嘧达莫中空微球的制备及评价

目的制备双嘧达莫中空微球,并对其进行初步评价。方法采用溶剂扩散-挥发法制备双嘧达莫中空微球,以外观、平均粒径、载药量及包封率为指标进行单因素考察优化处方,并对优化处方制备的中空微球进行体外漂浮及体外释放实验。结果双嘧达莫中空微球的最优处方及工艺为:乙基纤维素质量浓度为100 g.L-1、乙基纤维素与药物的质量比为5:1、乙醇与乙醚的体积比为4:l、乳化剂质量浓度为10 g.L-1、硬脂酸镁质量浓度为0.2 g.L-1,反应温度为30℃,搅拌速度为300 r.min-1。以最优处方制备的双嘧达莫中空微球,其载药量为11.57%,包封率为70.12%。该微球在人工胃液中12 h漂浮率可达94%,在人工胃液中12 h释放达80%,且无突释现象。结论双嘧达莫中空微球具有较理想的体外漂浮及缓释特性。     

Influence of microencapsulation method and peptide loading on formulation of poly(lactide-co-glycolide) insulin nanoparticles

Insulin stability during microencapsulation and subsequent release is essential for retaining its biological activity. Therefore we investigated a novel solid/oil/water anhydrous encapsulation method with a combination of stabilizers for maintaining the integrity of insulin during formulation and delivery. Two methods were used for preparation of nanoparticles, namely water/oil/water solvent evaporation and s/o/w anhydrous encapsulation to study the influence of the microencapsulation method on nanoparticle characteristics such as size and morphology, drug content, encapsulation efficiency, and in vitro and in vivo release profile. Poly (lactic-co-glycolic) acid (PLGA) with co-polymer ratio 50:50 was selected to prepare drug-loaded nanoparticles. When nanoparticles were prepared by solvent evaporation higher encapsulation efficiencies could be obtained, e.g. 74 +/- 13 with 5% target loading, whereas with 12% target loading, encapsulation efficiency was 27 +/- 8.6. The s/o/w method has a direct influence on the evaluation parameters where very poor encapsulation efficiencies 11 +/- 6.8 (max) were observed. The presence of stabilizers in the nanoparticles resulted in an increase in particle size but a reduction of encapsulation efficiency. Insulin release rate was comparatively higher for the batches prepared by the w/o/w method containing stabilizers than the s/o/w method. Also the presence of stabilizers resulted in sustained release of insulin resulting in prolonged reduction of blood glucose levels in streptozotocin induced diabetic rats. From the in vitro and in vivo studies, it can be concluded that careful selection of processing conditions and combination of stabilizers also result in beneficial effects without compromising the advantages of these delivery systems.