载10-甲氧基喜树碱缓释纳米粒的制备、表征与体外释药研究

以高分子多聚物聚乳酸(PLA)为材料,10-甲氧基喜树碱(Me OCPT)为模型药物,采用乳化溶剂挥发法制备载10-甲氧基喜树碱缓释纳米粒,表征并考察其体外释药特性。透射电子显微镜观察缓释纳米粒具有明显的球状结构,确定了最佳投料比为0.02∶1,平均粒径在100~250 nm之间,包封率和载药量分别为83.57±3.45%和3.10±1.19%,体外持续缓慢释放达48 h以上,累计释放率超过70%,缓释效果明显。以乳化溶剂挥发法成功制备的载10-甲氧基喜树碱缓释纳米粒,为聚乳酸作为药物缓控释载体的进一步研究提供依据,为难溶性小分子药物研究提供方向。     

凝聚法制备川芎嗪固体脂质纳米粒

目的:制备川芎嗪固体脂质纳米粒.方法:采用凝聚法制备,并以包封率和载药量为指标采用正交设计法优化川芎嗪固体脂质纳米粒的制备工艺,并利用透射电镜、激光粒度分析仪、Zeta电位测定仪表征了其药剂学性质结果:所得川芎嗪固体脂质纳米粒的最佳制备处方是川芎嗪45mg,卵磷脂600mg,硬脂酸450mg,0.4%的泊洛沙姆60ml 结论:该处方可用于川芎嗪固体脂质纳米粒的制备,工艺简单、可行.     

无籽刺梨多糖纳米粒制备工艺优化及表征

目的:采用双乳化溶剂蒸发法,优化无籽刺梨多糖纳米粒制备工艺,并对其进行表征.方法:采用响应面法以内水相W1和有机相O的比例、初级乳PE和外水相W2的比例以及泊洛沙姆P188的浓度为自变量,纳米粒的包封率为响应值,对制备工艺进行优化.结果:最佳制备工艺为W1和O的比例为1:8,PE和W2的比例为1:7,泊洛沙姆P188的...     

靶向肿瘤新生血管纳米粒的构建和质量控制

目的：制备F56多肽修饰的长春新碱纳米粒（F56-VCR-NP）,并建立其质量控制方法。方法：乳化－溶剂挥发法优化制备F56．VCR-NP：HPLC法测定其载药量、包封率,透射电镜下观察其形态,激光粒度分析仪测定其粒径和Zeta电位,CBQCA试剂盒测定纳米粒表面多肽密度,XPS进行表面元素分析。结果：优化制备的F56－VCR-NP粒径约为153nm,Zeta电位为－20．8mv,包封率为21．4％,载药量为1．9％,多肽连接效率为26．3％。结论：以聚乙二醇－聚乳酸（PEG-PLA）为原料,长春新碱为模型药物,成功制备出纳米粒子,并建立起有效的质量控制方法,对该实验样品进行了表征。结果表明此类纳米粒子尺寸均匀,表面多价连接F56多肽,载药量和包封率稳定可控,工艺成熟。     

抗肿瘤多药耐药纳米粒的制备及其对MCF-7/ADR 细胞的体外评价

目的:肿瘤的多药耐药现象会显著降低肿瘤细胞内药物浓度,本研究通过制备抗肿瘤多药耐药的靶向给药系统来逆转肿瘤的耐药性以提升细胞对药物的敏感性,从而降低该现象对癌症治疗的阻碍。方法:本文使用乳化溶剂挥发法制备以含姜黄素两亲性嵌段共聚物载体、以紫杉醇和磁性粒为核心的抗肿瘤多药耐药纳米粒,使用透射电镜和动态粒径散射仪等对纳米粒进行表征和磁响应性测试后,使用MTT法测定纳米粒对肿瘤耐药细胞MCF-7/ADR的抑制率以探究给药系统的耐药逆转性能。结果:制备的抗肿瘤多耐药纳米粒粒径为105 nm左右,磁响应性良好。所制得载紫杉醇纳米粒包封率为74.74%,载药率为12.40%。纳米粒可以通过磁场和生物素受体介导作用促进肿瘤细胞对粒子的内化,以增加抗癌药物的蓄积。与游离紫杉醇相比,逆转细胞耐药指数达8.5。结论:纳米系统在维持自身稳定性同时,能够凭借协同作用和靶向作用较大程度提升药物对耐药肿瘤细胞的杀伤效果。     

甘油三酯介质中制备壳聚糖纳米粒工艺研究

用乳化溶剂扩散法结合离子沉淀交联法从甘油三酯介质中制备壳聚糖纳米粒,用L9(34)正交设计优选纳米粒制备的处方工艺条件,用显微镜测定纳米粒的粒径,用透射电镜观察纳米粒的形态。结果:正交设计确定纳米粒制备的最优处方工艺条件为:搅拌速度150 r.min-1,壳聚糖质量分数0.10%,壳聚糖分子量9.1万,甘油三酯与壳聚糖酸溶液体积之比200:1,制备的纳米粒平均粒径为(150±50)nm。甘油三酯介质中制备壳聚糖纳米粒工艺简便,制剂具有广泛应用前景。     

藤黄酸聚乳酸纳米粒的研制

以新型材料聚乳酸(PLA)为载体,研制出质量稳定的藤黄酸聚乳酸纳米粒(GA-PLA-NPs)乳液制剂,并对其安全性进行评价。采用改良的溶剂蒸发法制备藤黄酸聚乳酸纳米粒(GA-PLA-NPs);用透射电子显微镜（TEM）观察纳米粒的形态;用激光粒度分析仪测定其平均粒径大小和分布;经超速离心后用紫外分光光度计测定纳米粒的包封率与载药量;考察藤黄酸纳米粒的体外释放特性;经急性毒性实验考察藤黄酸纳米粒的安全性。得到确定处方工艺为：水相∶有机相为2∶1（v/v）,表面活性剂在有机相中的浓度为0.5%（w/v）,藤黄酸（GA）在有机相中的浓度为0.1%（w/v）,GA∶PLA为1∶4（w/w）。处方条件下制备的纳米粒平均粒径为51.36 nm;平均包封率与载药量分别为98.87%和13.3%;藤黄酸纳米粒的体外释药分为两相：突释期和缓释期;急性毒性试验测得藤黄酸纳米粒的ID50为26.3mg/kg。制备的藤黄酸聚乳酸纳米粒（GA-PLA-NPs）质量稳定、分散性良好。聚乳酸可能成为藤黄酸的新型载体。     

硫酸长春碱聚乳酸缓释纳米粒的制剂学研究和体外释放度考察

目的:制备硫酸长春碱聚乳酸纳米粒(VLB-PLA-NPs)并考察其体外释放度.方法:采用复乳挥发法制备VLB-PLA-NPs,以包封率为主要指标评价指标,选择聚乳酸用量、超声时间、外水相浓度为考察因素,优化制备工艺,考察体外释放度.结果:优化工艺制备得VLB-PLA-NPs平均粒径为65±3.03nm,包封率为(99.68±0.30)%,载药量为3.323±0.01μg/mg,体外释放可持续20天.结论:该制备工艺操作简便,结果稳定,缓释特征明显,应用前景良好.     

星点设计效应面法优化姜黄素微球的制备工艺

采用乳化溶剂扩散法来制备姜黄素微球。以包封率为评价指标,通过单因素试验法、星点设计效应面法优化制备处方工艺。最佳处方及工艺条件:乙基纤维素与姜黄素的质量比为20.04∶1,吐温80用量为21.68 mg/mL,转速为600 r/min,搅拌时间为30 min以及水相和油相体积比为1.47∶1。此条件下制备的姜黄素微球外形圆整,释放平稳,包封率高达93.66%,且制备工艺简单,效应面法建立的数学模型预测良好。     

不同pH值与电位耦合对牛血清白蛋白包被酒石酸长春瑞滨纳米粒制备工艺的影响

在反溶剂法制备纳米粒过程中,pH值在一定程度上会对其产生影响。本文通过在不同酸碱环境下运用反溶剂法制备牛血清白蛋白包被酒石酸长春瑞滨纳米粒,进而借助于电位耦合作用来研究纳米粒制备工艺。研究结果表明:当pH=4.5至7.5时,酒石酸长春瑞滨和牛血清白蛋白带有异种电荷,而当pH=2.5,3.5,8.5,9.5时它们均带有同种电荷。当pH=7.5时,牛血清白蛋白带有负电荷即-8.52 mV,酒石酸长春瑞滨带有正电荷即+4.48mV。此时得到牛血清白蛋白包被酒石酸长春瑞滨纳米粒粒径为193.3 nm,Zeta电位为-30.86 mV,而且在该pH下对纳米粒制备工艺进行了优化,最终它的载药量和包封率达到了45.6%和90.6%。     

Poly(D,L-Lactide-Co-Glycolide) microspheres containing 5-fluorouracil: Optimization of process parameters

The objective of this research was to optimize the processing parameters for poly(D,L-lactide-coglycolide) (PLGA) microspheres of 5-fluorouracil (5-FU) and to mathematically relate the process parameters and properties of microspheres. Microspheres were prepared by a water-in-oil-in-water emulsion solvent evaporation technique. A 3² factorial design was employed to study the effect of the volume of the internal phase of the primary emulsion and the volume of the external phase of the secondary emulsion on yield, particle size, and encapsulation efficiency of microspheres. An increase in the volume of the internal phase of the primary emulsion resulted in a decrease in yield and encapsulation efficiency and an increase in particle size of microspheres. When the volume of the external phase of the secondary emulsion was increased, a decrease in yield, particle size, and encapsulation efficiency was observed. Microspheres with good batch-to-batch reproducibility could be produced. Scanning electron microscopic study indicated that microspheres existed as aggregates.     

Statistical Design for Formulation Optimization of Hydrocortisone Butyrate-Loaded PLGA Nanoparticles

The aim of this investigation was to develop hydrocortisone butyrate (HB)-loaded poly(d,l-lactic-co-glycolic acid) (PLGA) nanoparticles (NP) with ideal encapsulation efficiency (EE), particle size, and drug loading (DL) under emulsion solvent evaporation technique utilizing various experimental statistical design modules. Experimental designs were used to investigate specific effects of independent variables during preparation of HB-loaded PLGA NP and corresponding responses in optimizing the formulation. Plackett–Burman design for independent variables was first conducted to prescreen various formulation and process variables during the development of NP. Selected primary variables were further optimized by central composite design. This process leads to an optimum formulation with desired EE, particle size, and DL. Contour plots and response surface curves display visual diagrammatic relationships between the experimental responses and input variables. The concentration of PLGA, drug, and polyvinyl alcohol and sonication time were the critical factors influencing the responses analyzed. Optimized formulation showed EE of 90.6%, particle size of 164.3 nm, and DL of 64.35%. This study demonstrates that statistical experimental design methodology can optimize the formulation and process variables to achieve favorable responses for HB-loaded NP.     

装载于PLGA中的5-氟尿嘧啶缓释微球的制备及其体外释放的研究

目的：研究装载于不同分子量的PLGA中的5-氟尿嘧啶微球的制备方法及其在体外条件下的缓释行为。方法：以水包油包固复乳法将5-氟尿嘧啶包裹在高分子聚乳酸-聚羟基乙酸共聚物（PLGA）中,形成缓释微球,考察其大小,外观,包封率等理化性质,以紫外分光光度法为检测方法研究其体外释放行为。结果：经扫描电子显微镜观察,所制备的微球形态完整,大小较均匀。具有一定得包封率和载药量,体外释放研究表明其处方1和处方2的缓释时间为8天和23天。结论：以水包油包固复乳法制备的PLGA 5-氟尿嘧啶微球能够达到缓释的目的。     

Poly ε -Caprolactone Microparticles Containing Biosurfactants: Optimization of Formulation Factors

The objective of this research was to optimize the formulation factors and evaluate the release profiles of ε -polycaprolactone microparticles containing rhamnolipid biosurfactant (RhBS). Microparticles were prepared by a water-in-oil-in-water emulsion solvent evaporation technique. Optimization was studied through the effects of the volumes and concentrations of the internal and external phases of the microparticles on percent yield, particle size, encapsulation efficiency, and biosurfactant loading. Manipulation of the formulation factors yielded microparticles that were statistically the same size and generally classified as small. An increase in the volume of the internal phase above 1 ml caused a general decrease in yield and encapsulation efficiency and an increase in biosurfactant loading. When the volume of the external phase increased above 50 ml, decreases in percent yield and encapsulation efficiency and increases in biosurfactant loading were observed. Formulations with the highest encapsulation efficiencies and percentage yield and the lowest biosurfactant loading efficiencies were selected for further evaluation in release studies. Release studies were conducted in 15 and 32 ppt artificial seawater and deionized water. After 30 days microparticle formulations gradually released 80% to 100% of the encapsulated RhBS in all release media, with no significant differences in release rates in the different release media.     

壳聚糖-有机累托石/海藻酸钠复合纳米粒的制备

目的:以BSA作为模型药物,制备壳聚糖季铵盐-OREC复合物纳米微粒,建立一种安全有效的药物控释传递系统。方法:超声条件下,制备不同质量比的具有壳聚糖硅酸盐插层结构的复合物纳米微粒,观察其形态学特征、进行红外光谱分析。同时,测定OREC对BSA包封率和载药量的影响。结果:成功制备了不同质量比的OREC-HTCC纳米粒子。电镜结果显示纳米粒呈圆球形,均匀,平均粒径约为30nm。红外图谱分析证实,HTCC插入了OREC插层中,BSA成功地包裹入HTCC-ALG/OREC混合材料制备的纳米微粒。加入OREC后,纳米粒子的包封率及载药量均明显提高,但随着加入量的增加,包封率及载药量逐渐减少。结论:OREC-HTCC纳米粒子是良好的蛋白药物载体,具有粒径小、包封率高、缓释效果好等优点,为CS-OREC作为潜在的药物给药系统的进一步应用提供科学依据。     

Lyophilized Oral Sustained Release Polymeric Nanoparticles of Nateglinide

The objective of this study is to formulate lyophilized oral sustained release polymeric nanoparticles of nateglinide in order to decrease dosing frequency, minimize side effects, and increase bioavailability. Nateglinide-loaded poly Ɛ-caprolactone nanoparticles were prepared by emulsion solvent evaporation with ultrasonication technique and subjected to various studies for characterization including scanning electron microscopy (SEM), Fourier transform infrared spectroscopy, photon correlation spectroscopy and evaluated for in vitro drug release and pharmacodynamic studies. The influence of increase in polymer concentration, ultrasonication time, and solvent evaporation rate on nanoparticle properties was investigated. The formulations were optimized based on the above characterization, and the formulation using 5% polymer, 3-min sonication time, and rota-evaporated was found to have the best drug entrapment efficiency of 64.09 ± 4.27% and size of 310.40 ± 11.42 nm. Based on SEM, nanoparticles were found to be spherical with a smooth surface. In vitro drug release data showed that nanoparticles sustained the nateglinide release for over 12 h compared to conventional tablets (Glinate 60 mg), and drug release was found to follow Fickian mechanism. In vivo studies showed that nanoparticles prolonged the antidiabetic activity of nateglinide in rats significantly (p ≤ 0.05) compared to the conventional tablets (Glinate 60 mg) over a period of 12 h. Accelerated stability data indicated that there was minimal to no change in drug entrapment efficiency.KEY WORDS: drug encapsulation efficiency, nanoparticles, poly Ɛ-caprolactone (PCL), probe sonication     

Influence of Some Formulation Variables on the Optimization of pH-dependent,Colon-targeted,Sustained-release Mesalamine Microspheres

The aim of this work was to understand the influence of different formulation variables on the optimization of pH-dependent, colon-targeted, sustained-release mesalamine microspheres prepared by O/O emulsion solvent evaporation method, employing pH-dependent Eudragit S and hydrophobic pH-independent ethylcellulose polymers. Formulation variables studied included concentration of Eudragit S in the internal phase and the ratios between; internal to external phase, drug to Eudragit S and Eudragit S to ethylcellulose to mesalamine. Prepared microspheres were evaluated by carrying out in vitro release studies and determination of particle size, production yield, and encapsulation efficiency. In addition, morphology of microspheres was examined using optical and scanning electron microscopy. Emulsion solvent evaporation method was found to be sensitive to the studied formulation variables. Particle size and encapsulation efficiency increased by increasing Eudragit S concentration in the internal phase, ratio of internal to external phase, and ratio of Eudragit S to the drug. Employing Eudragit S alone in preparation of the microspheres is only successful in forming acid-resistant microspheres with pulsatile release pattern at high pH. Eudragit S and ethylcellulose blend microspheres were able to control release under acidic condition and to extend drug release at high pH. The stability studies carried out at 40°C/75% RH for 6 months proved the stability of the optimized formulation. From the results of this investigation, microencapsulation of mesalamine in microspheres using blend of Eudragit S and ethylcellulose could constitute a promising approach for site-specific and controlled delivery of drug in colon.     

Nanoparticles of Polyethylene Sebacate: A New Biodegradable Polymer

The present study demonstrates feasibility of preparation of nanoparticles using a novel polymer, polyethylene sebacate (PES), and its application in the design of drug-loaded nanocarriers. Silymarin was selected as a model hydrophobic drug for the present study. Two methods of preparation, viz., nanoprecipitation and emulsion solvent diffusion, were evaluated for preparation of nanoparticles. Effect of surfactants polyvinyl alcohol (PVA), lutrol F 68, and Tween 80 on the preparation of blank and silymarin-loaded PES nanoparticles was evaluated. Nanoprecipitation resulted in the formation of nanoparticles with all the surfactants (<450 nm). Increase in surfactant concentration resulted in decrease in entrapment efficiency and particle size except with PVA. The type and concentration of surfactant was critical to achieve low size and adequate drug entrapment. While increase in concentration of PES resulted in larger nanoparticles, inclusion of acetone in the organic phase resulted in particles of smaller size. In case of emulsion solvent diffusion, nanoparticles were obtained only with lutrol F 68 as surfactant and high surfactant concentration. The study revealed nanoprecipitation as a more versatile method for preparation of PES nanoparticles. Scanning electron microscopy studies revealed spherical shape of nanoparticles. Freeze-dried nanoparticles exhibited ease of redispersion, with a marginal increase in size. Differential scanning calorimetry and X-ray diffraction analysis revealed amorphous nature of the drug. The study demonstrates successful design of PES nanoparticles as drug carriers.     

Cellular uptake of Poly-(D,L-lactide-co-glycolide) (PLGA) nanoparticles synthesized through solvent emulsion evaporation and nanoprecipitation method

Poly-(D,L-lactide-co-glycolide) (PLGA) nanoparticles have been widely studied for drug delivery. The aim of this study is to determine how cellular uptake of these nanoparticles is influenced by different surface properties, incubation time, particle concentration and cell types. Spherical coumarin-6 loaded PLGA nanoparticles with a size of about 100 nm were synthesized through solvent emulsion evaporation and nanoprecipitation methods. In vitro cellular uptake efficiency was determined using human bronchial epithelial cells (BEAS-2B) and murine monocyte-derived macrophage (RAW264.7) cells. PLGA nanoparticles were incubated with these cells in a concentration range of 10-300 μg/ml for different time periods. The results show that cellular uptake decreased for nanoparticles surface coated with PVA surfactant and was especially limited for severely aggregated particles. At higher particle concentration, the total amount of particles taken up by cells increased while the uptake efficiency decreased. In addition, cells could take up more particles with longer incubation time, although the uptake rate decreased gradually with time. Finally, RAW264.7 cells show increased uptake compared to BEAS-2B cells. The information drawn from this study would provide important clues on how nanomaterials interact with cells and how these interactions can influence biocompatibility or toxicity.