硝苯地平固体分散体制备工艺的研究

目的利用固体分散技术将硝苯地平制成固体分散体,提高其体外溶出速率。方法分别以聚乙二醇6000(PEG6000)、聚乙二醇4000(PEG4000)、聚乙烯吡咯烷酮K30(PVPK30)、泊洛沙姆188(Pluronic F68)等为载体,用熔融法、溶剂法、溶剂-熔融法和喷雾干燥法制备硝苯地平固体分散体。采用差热分析法(DTA)分析药物在固体分散体中的存在状态,并进行体外溶出度试验。结果各种固体分散体均能加快药物的溶出速率,并且随着载体在固体分散体中的比例增大,溶出速率增大。DTA分析显示硝苯地平在PVPK30的固体分散体中以微细结晶存在。结论将硝苯地平制成固体分散体能显著提高硝苯地平的体外溶出速率。     

硝苯地平固体分散体制备工艺的研究

目的利用固体分散技术将硝苯地平制成固体分散体,提高其体外溶出速率。方法分别以聚乙二醇6000(PEG6000)、聚乙二醇4000(PEG4000)、聚乙烯吡咯烷酮K30(PVPK30)、泊洛沙姆188(Pluronic F68)等为载体,用熔融法、溶剂法、溶剂-熔融法和喷雾干燥法制备硝苯地平固体分散体。采用差热分析法(DTA)分析药物在固体分散体中的存在状态,并进行体外溶出度试验。结果各种固体分散体均能加快药物的溶出速率,并且随着载体在固体分散体中的比例增大,溶出速率增大。DTA分析显示硝苯地平在PVPK30的固体分散体中以微细结晶存在。结论将硝苯地平制成固体分散体能显著提高硝苯地平的体外溶出速率。     

固体分散技术提高黄芩提取物溶出度的研究

目的：通过制备固体分散体，提高黄芩提取物的溶出度。方法：采用熔融法和溶剂法，制备聚乙二醇4000（PEG4000），聚乙二醇6000（PEG6000），聚乙烯吡咯烷酮K30（PVPK30）3种载体材料及不同比例条件下的固体分散体。通过比较原药材、固体分散体、机械混合物的溶出性能，从而确定制备的最佳方法和最佳比例。结果：不同载体不同比例的固体分散体均能提高药物的溶出度，且载体比例越大，药物的溶出越快，3种载体的增溶效果依次为PVPK30〉PEG4000〉PEG6000。结论：以PVP为载体，采用溶剂法所制备的药物/载体比例为1：6的固体分散体能显著提高黄芩提取物的溶出速率。     

杨梅素固体分散体的制备以及体外溶出试验

目的运用固体分散技术制备杨梅素固体分散体并提高其体外溶出速率。方法选用PEG6000和PVPK30为载体,采用溶剂法和溶剂-熔融法制备杨梅素固体分散体,采用紫外分光光度法进行含量测定,并进行溶解度、体外溶出试验。结果两种载体的固体分散体均能增加药物的溶解度和溶出速率,杨梅素在载体中以高度分散状态存在。结论以PVPK30为载体的杨梅素固体分散体体外溶解度和溶出速率明显提高。杨梅素固体分散体能显著提高杨梅素的溶出速率。     

索法酮固体分散体的制备及体外溶出特性

目的:制备索法酮固体分散体并考查其体外溶出特性.方法:以PEG 2000、PEG 4000和PEG 6000为载体,采用熔融法制备固体分散体,与物理混合物比较体外溶出度.结果:PEG 4000和PEG 6000制得的固体分散体的体外溶出度高于PEG 2000,均高于物理混合物.载体比例越大,体外溶出越快.结论:以PEG为载体,采用熔融法可制得体外溶出较快的索法酮固体分散体.     

固体分散体提高银杏叶片溶出度的研究

目的:通过制备固体分散体提高银杏叶片中银杏叶提取物(EGb)的溶出度.方法:采用溶剂熔融法、喷雾干燥法制备聚乙二醇6000(PEG 6000)和聚乙烯吡咯烷酮K17(PVPK17)2种载体材料、不同比例的固体分散体,并比较固体分散体、物理混合物和EGb、市售普通片的溶出特性.对EGb-PEG 6000固体分散体进行差示热扫描(DSC)分析.结果:溶剂熔融法和喷雾干燥法可制备不同比例的PEG 6000,PVPK17的EGb固体分散体,EGb-PEG 6000(1:2)固体分散体片溶出度增加明显,且增溶效果优干EGb-PVPK17固体分散体.结论:EGb-PEG 6000(1:2)固体分散体能有效提高银杏叶片的溶出度.     

依托泊苷固体分散体的制备及体外研究

目的 制备依托泊苷固体分散体，改善依托泊苷的溶出度。方法 应用聚乙烯吡咯烷酮（PVPK30）和聚乙二醇（PEG6000）为载体，以溶剂法制备固体分散体。采用正交实验设计考察制备固体分散体的最佳工艺条件，并对所得样品进行体外溶出度研究，以X线衍射、DSC-量热分析进行物相鉴定。结果 依托泊苷在载体PVPK30和PEG6000中结晶消失。药物的溶出速度随载体比例增加而增加。结论 采用PVPK30和PEG6000所制依托泊苷固体分散体能显著提高药物的体外溶出度，药物以无定形状态或分子态存在于载体中。     

甘草黄酮固体分散体的制备及体外溶出性能考察

目的:制备甘草黄酮(LF)-聚乙烯吡咯烷酮K30(PVP K30)固体分散体,并对其进行表征及体外释药性能考察。方法:分别以聚乙烯吡咯烷酮K30(PVP K30)、聚乙二醇(PEG 4000、 PEG 6000)、泊洛沙姆188(F68)以及胶态二氧化硅(SiO2)为载体,采用溶剂法或溶剂熔融法制备固体分散体,考察其体外释药性能,并利用差式扫描量热仪(DSC)、傅里叶变换红外光谱(FT-IR)对固体分散体的结构特征进行表征。结果:以PVP K30为载体制备的固体分散体的体外溶出率优于其他载体制备的固体分散体,且以药物-载体比例1∶5时溶出度最佳。经DSC和FT-IR结果表明,固体分散体中的药物以无定形状态存在。结论:固体分散体技术能显著提高甘草黄酮的体外溶出度。     

卡维地洛固体分散体的初步研制

目的:制备卡维地洛固体分散体并考察其体外溶出度。方法:以聚乙二醇(PEG)、聚乙烯吡咯烷酮(PVP)的混合物(2∶1、1∶2)为载体,采用溶剂熔融法和共沉淀法制备载体与药物不同比例的固体分散体并比较其体外溶出度。结果:药物溶出度随载体比例增加而增加;载体与药物比例越小,固体分散体与药物原料粉之间溶出度差异越显著;PEG∶PVP(1∶2)所制分散体体外溶出行为较优,以3、10、30、60min时溶出百分率进行比较,固体分散体是药物原料粉的3～8倍。结论:所制卡维地洛固体分散体能增加药物体外溶出度。     

索法酮固体分散体的制备及体外溶出度的研究

目的:提高制剂中索法酮体外溶出度.方法:选择水溶性载体聚乙二醇4000(PEG4000)和聚乙烯吡咯烷酮K30(PVPk30)用熔融法制备索法酮固体分散体,建立紫外-可见分光光度法测定固体分散体的溶出度的方法.结果:紫外-可见分光光度法测定索法酮的溶出度,方法准确可靠、稳定且无载体的干扰.制备的固体分散体能显著地提高索法酮的体外溶出度;以聚乙二醇(PEG4000)为载体制备的固体分散体溶出度高于聚乙烯吡咯烷酮K30(PVPk30).差示扫描热量法(DSC)研究表明,在质量比为1:8索法酮一聚乙二醇4000(PEC4000)固体分散体中,索法酮以无定形的状态分散在固体分散体中,其熔点吸热峰消失.结论:索法酮固体分散体的体外溶出度增大,与载体的结构及其在良好载体固体分散体中的无定形状态有关.     

Physicochemical Characterization and Dissolution Study of Solid Dispersions of Lovastatin with Polyethylene Glycol 4000 and Polyvinylpyrrolidone K30

Solid dispersions in water-soluble carriers have attracted considerable interest as a means of improving the dissolution rate, and hence possibly bioavailability, of a range of hydrophobic drugs. The aim of the present study was to improve the solubility and dissolution rate of a poorly water-soluble drug, Lovastatin, by a solid dispersion technique. Solid dispersions were prepared by using polyethylene glycol 4000 (PEG 4000) and polyvinylpyrrolidone K30 (PVP K30) in different drug-to‐carrier ratios. Dispersions with PEG 4000 were prepared by fusion-cooling and solvent evaporation, whereas dispersions containing PVP K30 were prepared by solvent evaporation technique. These new formulations were characterized in the liquid state by phase solubility studies and in the solid state by differential scanning calorimetry, X-ray powder diffraction, and FT-IR spectroscopy. The aqueous solubility of Lovastatin was favored by the presence of both polymers. The negative values of the Gibbs free energy and enthalpy of transfer explained the spontaneous transfer from pure water to the aqueous polymer environment. Solid-state characterization indicated Lovastatin was present as amorphous material and entrapped in polymer matrix. In contrast to the very slow dissolution rate of pure Lovastatin, the dispersion of the drug in the polymers considerably enhanced the dissolution rate. This can be attributed to improved wettability and dispersibility, as well as decrease of the crystalline and increase of the amorphous fraction of the drug. Solid dispersion prepared with PVP showed the highest improvement in wettability and dissolution rate of Lovastatin. Even physical mixture of Lovastatin prepared with both polymers also showed better dissolution profile than that of pure Lovastatin. Tablets containing solid dispersion prepared with PEG and PVP showed significant improvement in the release profile of Lovastatin compared with tablets containing Lovastatin without PEG or PVP.     

Physicochemical characterization and dissolution study of solid dispersions of Lovastatin with polyethylene glycol 4000 and polyvinylpyrrolidone K30

Solid dispersions in water-soluble carriers have attracted considerable interest as a means of improving the dissolution rate, and hence possibly bioavailability, of a range of hydrophobic drugs. The aim of the present study was to improve the solubility and dissolution rate of a poorly water-soluble drug, Lovastatin, by a solid dispersion technique. Solid dispersions were prepared by using polyethylene glycol 4000 (PEG 4000) and polyvinylpyrrolidone K30 (PVP K30) in different drug-to-carrier ratios. Dispersions with PEG 4000 were prepared by fusion-cooling and solvent evaporation, whereas dispersions containing PVP K30 were prepared by solvent evaporation technique. These new formulations were characterized in the liquid state by phase solubility studies and in the solid state by differential scanning calorimetry, X-ray powder diffraction, and FT-IR spectroscopy. The aqueous solubility of Lovastatin was favored by the presence of both polymers. The negative values of the Gibbs free energy and enthalpy of transfer explained the spontaneous transfer from pure water to the aqueous polymer environment. Solid-state characterization indicated Lovastatin was present as amorphous material and entrapped in polymer matrix. In contrast to the very slow dissolution rate of pure Lovastatin, the dispersion of the drug in the polymers considerably enhanced the dissolution rate. This can be attributed to improved wettability and dispersibility, as well as decrease of the crystalline and increase of the amorphous fraction of the drug. Solid dispersion prepared with PVP showed the highest improvement in wettability and dissolution rate of Lovastatin. Even physical mixture of Lovastatin prepared with both polymers also showed better dissolution profile than that of pure Lovastatin. Tablets containing solid dispersion prepared with PEG and PVP showed significant improvement in the release profile Lovastatin compared with tablets containing Lovastatin without PEG or PVP.     

格列喹酮固体分散体的制备及溶出度测定

目的:制备格列喹酮固体分散体并考察其体外溶出性。方法:以聚乙烯吡咯烷酮K30(PVP)、聚乙二醇6000(PEG)为载体,溶剂熔融法和溶剂法制备格列喹酮固体分散体,并与原料药比较体外溶出度。结果:载体比例越大,药物溶出愈快。载体为PVP所制固体分散体的体外溶出行为总体优于载体为PEG者。格列喹酮-PVP固体分散体(1∶7)10min内体外溶出度达到70%以上,优于格列喹酮原料药。结论:成功制备了格列喹酮固体分散体。     

替硝唑固体分散体的制备及其体外释放特性研究

目的:利用固体分散技术制备替硝唑固体分散体,增加替硝唑溶解度和溶出速度。方法:以聚乙二醇(PEG)为载体材料,采用溶剂-熔融法制成固体分散体,测定表观溶解度,进行体外溶出试验,并采用差示扫描量热(DSC)法鉴别药物在固体分散体中的存在状态。结果:替硝唑的溶出度和表观溶解度随PEG的比例不同而不同,且溶出度随载体用量增加而增加。固体分散体的DSC曲线中替硝唑药物的特征熔融峰消失。结论:所制得的固体分散体能明显提高替硝唑的溶出度和表观溶解度。     

Preparation of evodiamine solid dispersions and its pharmacokinetics

In order to increase the dissolution rate and bioavailability, solid dispersions of evodiamine in PVP K(30) with different enriched samples of evodiamine to PVP K(30) ratios were prepared by solvent method. Our studies showed that the dissolution rate of evodiamine was significantly higher in the solid dispersion system in comparison with that in enriched samples of evodiamine or physical mixtures. The increase of the dissolution rate was evidently related to the ratio of evodiamine to PVP K(30). The solid dispersion system (enriched samples of evodiamine/PVP K(30)= 1/6, w/w) gave the highest dissolution rate: about 27.7-fold higher than that of enriched samples of evodiamine in hard capsules. Powder X-ray diffraction studies showed that enriched samples of evodiamine presented a total chemical stability after its preparation as solid dispersions. In vivo administration studies indicated that solid dispersions of evodiamine in hard capsules had a higher C(max) and a shorter T(max) than those of physical mixture in hard capsules, and the differences of C(max) and T(max) between them were significant. These results suggest that solid dispersions of evodiamine in hard capsules has a notably faster and greater absorption rate than enriched samples of evodiamine in physical mixture hard capsule and corresponds with the in vitro dissolution.     

Effect of physiochemical variables on phase solubility and dissolution behavior of indomethacin solid dispersion system

To study the influence of temperature and pH on solubility and dissolution behavior of indomethacin solid dispersions were prepared using several classes of hydrophilic carriers. Investigations on dissolution of indomethacin in binary system are reported earlier. However the phase solubility and dissolution behavior at different pH and temperature left void. The present investigation includes: phase solubility study at various pH; preparation of solid dispersion by solvent evaporation, melting and kneading method; characterization of various blends by dissolution study, and solid state studies to ensure interaction of drug with carrier. The binding between drug and carriers (PVP K30, βCD and PEG) was explained by thermodynamic parameters as calculated from phase solubility study. Indomethacin in association with PVP K30 showed very high apparent binding constant (Ka) and Gibb’s free energy change (?G) in comparison to other blends. The ternary system (drug:βCD:PVP K30, 1:5:1) showed better dissolution of about 80.97 and 99 % at pH 7.2 after 5 and 30 min respectively. At higher proportion of carrier (1:9) in binary solid dispersion of drug and PVP K30, drug dissolution was 96.23 and 97.85 % after 5 and 30 min respectively. This raised solubility of indomethacin would be helpful in designing a dosage form.     

浙贝提取物固体分散体的制备及溶出特性研究

目的：制备浙贝提取物固体分散体,考察其中贝母素甲及贝母素乙的溶出效果,从而确定制备的最佳方法和最佳比例。方法：选择聚乙二醇6000（PEG6000）与聚乙烯吡咯烷酮（PVP K30）两种载体材料,分别采用熔融法和溶剂法制备浙贝提取物固体分散体;通过比较提取物、固体分散体的溶出性能,确定最佳工艺。结果：使用HPLC-ELSD法测定贝母素甲及贝母素乙的溶出量,结果准确、可靠、稳定。制备成固体分散体能显著提高贝母素甲及贝母素乙的体外溶出速度;PEG6000作为载体的浙贝提取物固体分散体溶出速度快于PVP K30为载体的浙贝提取物固体分散体。结论：以PEG6000为载体,采用熔融法制备的药物/载体比例为1∶6的固体分散体能显著提高浙贝提取物中贝母素甲及贝母素乙的溶出速率。     

丹参酮ⅡA固体分散体制备工艺研究

目的研究减压干燥法制备丹参酮ⅡA-聚乙烯吡咯烷酮K30（PVPK30）固体分散体的最佳工艺。方法采用减压干燥法制备,正交试验优化,以丹参酮ⅡA为检测指标,用高效液相色谱法进行体外溶出度的测定。结果制备丹参酮ⅡA-PVPK30固体分散体的最佳工艺为用5倍量的载体、4倍量的粮食酒精溶解,减压干燥1h。丹参酮ⅡA的体外溶出百分比为60.1%。结论用减压干燥法成功制备了丹参酮ⅡA-PVPK30固体分散体,该固体分散体对丹参酮ⅡA有很好的增溶效果。     

Preparation and characterization of solid dispersions of Quercetin with PEG4000

Objective To enhance the solubility,quicken the speed of digesting and absorption,and increase the bioavailability of quercetin(3,3',4',5,7-pentahydroxyflavone).Methods A series of Quercetin-PEG4000 solid dispersions were prepared by fusion method.The configuration and property of solid dispersion were characterized by solubility tests,dissolution tests,FTIR spectra,differential scanning calorimetry(DSC)and microphotograph.Results 1.According to solubility tests the the mass ratio of quercetin to PEG4000 affected strongly on the solubility of solid dispersions,on the whole,the relation of the solubility of solid dispersions to the mass ratio presented linear relationship.The preparation temperature had little effect on the solubility of solid dispersions.The surface-active agent,polysorbate80 increased strongly the solubility of solid dispersions.2.According to the dissolution tests,the mass ratio of quercetin to PEG4000 affected strongly on the dissolution of solid dispersions,the preparation temperature had little effect on the dissolution of solid dispersions.The surface-active agent,polysorbate80 increased strongly the dissolution of solid dispersions,and after addition polysorbate80,the dissolution of solid dispersions was two times of the dissolution of solid dispersions without polysorbate80.3.According to the DSC results,except that a little of quercetin molecular existed as crystalline state in the solid dispersion with the mass ratio was qu:PEG=1:2,quercetin existed as amorphous phase in other mass ratio solid dispersion.4.According to the FTIR spectra and microphotograph results,the relation of quercetin and PEG4000 was mainly physical mixing in quercetin-PEG4000 solid dispersion.Quercetin was just like solute in solution,and PEG4000 was just like solvent in solution.The force between quercetin and PEG4000 was mainly hydrogen bonding,so the biological activity of quercetin would not be influenced greatly after the formation solid dispersion.Conclusions These results suggest that quercetin existed mainly as amorphous phase in solid dispersion;the solubility and the dissolution in water were increased obviously after formation the solid dispersion.