非洛地平固体分散体的制备和体外溶出度考察

目的应用固体分散技术,提高非洛地平的体外溶出度。方法以PVPK30、Lutrol F68、Tween80(与吸附剂,如PVPP)为载体,分别采用溶剂法、熔融法、溶剂蒸发-沉积等技术制备非洛地平固体分散体,考察不同载体对固体分散体溶出度的影响。并着重考察以Tween 80为增溶剂,不同种类吸附剂为载体对固体分散体外观、溶出度的影响。应用差示热分析和X射线衍射鉴别药物在载体中的存在状态。结果采用不同载体和方法制备的非洛地平固体分散体均能明显促进药物的溶出,溶出速度依次为Tween 80>Lutrol F68>PVPk30。其中m(药物)∶m(Tween 80)∶m(PVPP)=1∶4∶5时,溶出速度最快,1 h累积释放率达90%以上。差示热分析固体分散体中药物吸热峰前移或消失,X射线衍射固体分散体中药物的结晶衍射峰消失,推测药物在载体中以无定形或分子形式存在。结论制备非洛地平固体分散体可以提高其体外溶出度,尤其是含有表面活性剂的固体分散体可进一步提高药物的溶出。     

固体分散体技术改善吴茱萸次碱溶出特性的研究

目的:制备吴茱萸次碱(Rut)固体分散体,提高Rut体外溶出度.方法:分别以聚乙烯吡咯烷酮(PVP)为载体,采用溶剂-共沉淀法,制备含不同辅助载体的Rut固体分散体;采用差示热分析和X-射线衍射分析对固体分散体进行物相鉴别,并进行体外溶出度试验;考察载体用量、载体中表面活性剂的加入和不同溶出介质对药物溶出特性的影响.结果:Rut以微晶形式存在于固体分散体中;其中,以微粉硅胶和乳糖为辅助载体制备的Rut-PVP-微粉硅胶(1∶2∶1)和Rut-PVP-乳糖(1∶2∶2)固体分散体,其累积溶出度较其物理混合物提高了约6倍.结论:Rut-PVP-微粉硅胶(1∶2∶1)和Rut-PVP-乳糖(1∶2∶2)固体分散体可显著提高药物的溶出速度和程度.     

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。     

米非司酮固体分散体的制备及性质研究

目的:增加米非司酮的溶解度和体外溶出速率,为阴道环的成功制备奠定基础。方法:以PVPK30为载体,采用溶剂法制备米非司酮固体分散体。考察其体外溶出特性,并采用差示扫描量热法、红外光谱法和粉末X-射线衍射法鉴别药物在固体分散体中的存在状态。结果:固体分散体大大提高了米非司酮的溶出速率,最佳比例为1∶3。药物在分散体中以无定型状态存在。结论:溶剂法制备的固体分散体可显著提高药物的溶出速率,从而提高了阴道环中药物的释放量。     

长春西汀固体分散体的制备及体外溶出特性

目的:制备长春西汀固体分散体,提高其溶出速度和程度。方法:以泊洛沙姆188(F68)为载体,用溶剂-熔融法制备固体分散体;差热分析、X-射线粉末衍射分析以鉴别药物在载体中的存在状态;并考察载体的用量、溶出介质和转速对药物体外溶出特性的影响。结果:长春西汀的固体分散体中药物部分以分子状态分散,部分以微晶分散。固体分散体VIN-F68(1∶6,w/w)的溶出参数t50t、d与相应物理混合物、原料药粉末和市售片剂间差异存在显著性(P<0.01),溶出介质和转速的选择对药物的溶出有一定影响。结论:长春西汀的固体分散体能显著提高药物的溶出速度和程度。     

酮康唑固体分散体及共研磨物的制备及其体外溶出作用研究

目的:制备酮康唑固体分散体及其共研磨物并考察其体外溶出作用。方法:分别以聚乙二醇(PEG)、聚维酮(PVP)和泊洛沙姆(F68)作为载体材料,采用熔融法或溶剂法制备药物与载体不同比例(1∶1、1∶3、1∶5、1∶10)的酮康唑固体分散体;另制备药物与低取代羟丙基纤维素(L-HPC)不同比例(1∶0.5、1∶1、1∶1.5)的酮康唑共研磨物;研究各固体分散体和共研磨物的体外溶出情况,同时与酮康唑原料药进行比较。结果:与原料药比较,载药固体分散体和共研磨物可以显著提高酮康唑的溶出水平,且溶出速率随着载体比例的增加而增大,各固体分散体(1∶10)和共研磨物(1∶1.5)在20min时累积溶出率均大于90%,而原料药低于50%。结论:酮康唑制成固体分散体和共研磨物可以显著提高其体外溶出度。     

格列吡嗪固体分散体及其片剂的制备及质量评价

目的:制备格列吡嗪固体分散体,以改善难溶性药物格列吡嗪的溶解度及生物利用度。以固体分散体为中间体,通过处方筛选及工艺优化,制备格列吡嗪固体分散体片,并对其进行质量研究。方法:以泊洛沙姆407和葡甲胺为载体材料,采用溶剂法制备固体分散体。扫描电子显微镜(SEM)、X射线衍射(XRD)对固体分散体中药物的存在状态进行表征。药动学实验比较原料药、物理混合物及固体分散体体内吸收情况。以固体分散体为中间体,粉末直接压片法制备格列吡嗪固体分散体片。以曼迪宝为参比制剂、溶出相似因子f₂为标准,对处方及工艺进行筛选及优化。结果:格列吡嗪∶泊洛沙姆407∶葡甲胺=1∶4∶3制备的固体分散体与原料药相比,溶解度得到改善,血药浓度-时间曲线下面积(AUC)提高了4.08倍。SEM,XRD结果显示药物以无定形态均匀分布于固体分散体中。固体分散体20%、玉米淀粉2.5%、乳糖∶微晶纤维素为2∶1、硬脂酸镁1%、二氧化硅0.5%、混料时间为5 min时,所得的格列吡嗪固体分散体片与市售制剂的溶出曲线相似因子均>50。结论:固体分散体技术改善了格列吡嗪的溶出度及生物利用度,制备的格列吡嗪...     

磷脂固体分散体对槲皮素溶出促进作用的研究

目的研究磷脂固体分散体对槲皮素溶出的促进作用。方法用溶剂法制备了不同比例的槲皮素的磷脂固体分散体 ,与其相应的物理混合物及槲皮素的PVP或PEG4 0 0 0 (1∶1)固体分散体并进行了溶出的对比研究。结果所制得固体分散体均可改善槲皮素的溶出 ,而质量比为 1∶1的槲皮素 磷脂固体分散体的溶出促进作用最为显著。DSC和X射线粉末衍射的研究表明 ,在质量比为1∶1的槲皮素 磷脂固体分散体中 ,槲皮素以无定形的状态分散于载体磷脂中 ,其熔点吸热峰消失。结论槲皮素溶出度的增大与其无定形的存在状态、磷脂对其的润湿作用以及磷脂在水中可形成脂质体有关     

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。     

艾地苯醌固体分散体的制备及体外溶出度研究

目的:制备艾地苯醌固体分散体,并考察其体外溶出度。方法:以泊洛沙姆407(P407)为载体,单因素考察不同制备方法(熔融法和溶剂法)和不同药载比(1∶1、1∶3、1∶8)对药物溶出度的影响,并采用差式扫描量热(DSC)、X-射线粉末衍射(XRD)鉴别药物在固体分散体中的存在状态。结果:以溶剂法制备的药载比为1∶3的艾地苯醌固体分散体,其体外溶出度约为80%。艾地苯醌在固体分散中主要以无定型或分子状态存在。结论:成功制得体外溶出度较高的艾地苯醌固体分散体。     

Enhanced release of solid dispersions of etodolac in polyethylene glycol

This work examines the release of etodolac from various molecular weight fractions of polyethylene glycol (PEG) solid dispersions. Solid dispersions of etodolac were prepared in different molar ratios of drug/carrier by using solvent and melting methods. The release rate of etodolac from the resulting complexes was determined from dissolution studies by use of USP dissolution apparatus 2 (paddle method). The physical state and drug:PEG interaction of solid dispersions and physical mixtures were characterized by X-ray diffraction (XRD), infrared spectroscopy (IR) and differential scanning calorimetry (DSC). The dissolution rate of etodolac is increased in all of the solid dispersion systems compared to that of the pure drug and physical mixtures. The solid dispersion compound prepared in the molar ratio of 1:5 by the solvent method was found to have the fastest dissolution profile. The physical properties did not change after 9 months storage in normal conditions.     

The dissolution enhancement of piroxicam in its physical mixtures and solid dispersion formulations using gluconolactone and glucosamine hydrochloride as potential carriers

Abstract

The solid dispersion technique is one of the most effective methods for improving the dissolution rate of poorly water-soluble drugs; however this is reliant on a suitable carrier and solvent being selected. The work presented explores amino sugars (d-glucosamine HCl and d-gluconolactone) as potential hydrophilic carriers to improve dissolution rate of a poorly water-soluble drug, piroxicam, from physical mixtures and solid dispersion formulations. Solid dispersions of the drug and carrier were prepared using different ratios by the conventional solvent evaporation method. Acetone was used as solvent in the preparation of solid dispersions. Physical mixtures of piroxicam and carrier were also prepared for comparison. The properties of all solid dispersions and physical mixtures were studied using a dissolution tester, Fourier transform infrared, XRD, SEM and differential scanning calorimetry. These results showed that the presence of glucosamine or gluconolactone can increase dissolution rate of piroxicam compared to pure piroxicam. Glucosamine or Gluconolactone could be used as carrier in solid dispersion formulations and physical mixtures to enhance the dissolution rate. Solid state studies showed that no significant changes occurred for piroxicam in physical mixtures and solid dispersion.     

Enhancement of dissolution rate of class II drugs (Hydrochlorothiazide); a comparative study of the two novel approaches; solid dispersion and liqui-solid techniques

Liqui-solid technique and solid dispersion formation are two novel approaches for enhancement of dissolution rate of BCS class II drugs. Liqui-solid compact converts a liquid drug or drug solution into a free flowing powder with enhanced dissolution rate. In case of solid dispersion drug is molecularly dispersed in a hydrophilic polymer in solid state. In the present study, Liqui-solid and solid dispersion techniques were applied to enhance the dissolution of the Hydrochlorothiazide. Three formulations of Hydrochlorothiazide were prepared by liqui-solid technique using micro crystalline cellulose as carrier material and colloidal silicon dioxide as coating material. Water, poly ethylene glycol-400 and Tween-60 were used as solvent system. Solid dispersions of Hydrochlorothiazide were prepared by solvent fusion method using PEG-4000 as carrier polymer. Tablets were subjected to evaluation of various physical and chemical characteristics. Dissolution profiles of tablets prepared by the novel techniques were compared with marketed conventional tablets. Model independent techniques including similarity factor, dissimilarity factor and dissolution efficiency were applied for comparison of dissolution profiles. The results obtained indicated that liqui-solid compact formulations were more effective in enhancing the dissolution rate compared with solid dispersion technique. The liqui-solid compacts improved the dissolution rate up to 95% while the solid dispersion increased it to 88%.     

马来酸罗格列酮固体分散体及其溶出速率

目的提高难溶性药物马来酸罗格列酮的体外溶出速率 ,满足脉冲制剂的设计要求。方法选用PVPK3 0为载体 ,用溶剂法制备了马来酸罗格列酮固体分散体 ,比较考察了原料药及其物理混合物和固体分散体的溶出差别 ,并通过红外光谱及X 射线粉末衍射对固体分散体进行了鉴定。结果体外溶出结果表明固体分散体能显著增加药物在水中及人工肠液中的溶出速率 ;红外光谱分析结果表明药物与载体之间没有发生化学反应 ;X 射线粉末衍射图谱表明药物以无定形状态分散于载体PVPK3 0中。结论固体分散体体外溶出速率的提高可以满足脉冲制剂的设计要求。     

槲皮素PVP固体分散体的制备及物相鉴定

目的用溶剂法制备槲皮素-PVP固体分散体并考察其溶出特性并对物相进行鉴定。方法采用溶剂法制备槲皮素-PVP固体分散体,通过溶出实验对槲皮素溶出率的测定研究固体分散体的溶出性质,利用差热分析（Differentialscanning calorimetry,DSC）、红外光谱分析（Infrared spectroscopy,IR）、粉末X衍射（X-ray powder diffractometry,PXRD）、扫描电镜（Scanning electron microscopy,SEM）等方法对其进行物相鉴定。结果槲皮素-PVP固体分散体的溶出速率相对其物理混合物有了明显的改善; 溶解实验显示固体分散体中槲皮素的溶解度有了显著的提高;热差分析及粉末X衍射结果表明固体分散体中槲皮素呈非结晶形式;扫描电镜下固体分散体中无槲皮素晶体。结论采用溶剂法制备槲皮素-PVP固体分散体可显著提高槲皮素的溶解度及溶出速度。     

紫杉醇-PVP固体分散体的制备、物相鉴定及细胞药效

用溶剂法制备紫杉醇-PVP固体分散体，对其溶解度及体外溶出特性进行考察并对物相进行鉴定。采用溶剂法制备紫杉醇-PVP固体分散体，对固体分散体中紫杉醇的溶解度和溶出率进行测定，研究固体分散体的溶出性质。同时，利用差热分析（Differential scanning calorimetry，DSC）、粉末X衍射（X-ray powder diffractometry,PXRD）、扫描电镜（Scanning electron microscopy，SEM）等方法对其进行物相鉴定。采用SRB法对紫杉醇-PVP固体分散体对SKOV-3细胞药效进行测定。紫杉醇-PVP固体分散体中紫杉醇的溶解度和溶出速率相对其原料药和物理混合物均有了明显的提高；热差分析及粉末X衍射结果表明固体分散体中紫杉醇呈非结晶形式；扫描电镜下固体分散体中无紫杉醇晶体。细胞药效结果表明紫杉醇-PVP固体分散体的细胞药效强于紫杉醇纯药。采用溶剂法制备的紫杉醇-PVP固体分散体可显著提高紫杉醇的溶解度和溶出速度。     

Solid dispersion particles of amorphous indomethacin with fine porous silica particles by using spray-drying method

The solid dispersion particles of indomethacin (IMC) were prepared with different types of silica, non-porous (Aerosil 200) or porous silica (Sylysia 350) by using spray-drying method. Powder X-ray diffraction analysis showed that IMC in solid dispersion particles is in amorphous state irrespective of the type of silica formulated. In DSC analysis, the melting peak of IMC in solid dispersion particles with Sylysia 350 shifted to lower temperature than that in solid dispersion particles with Aerosil 200 although the peak of each solid dispersion particles was much smaller than that of original IMC crystals. Dissolution property of IMC was remarkably improved by formulating the silica particles to the solid dispersion particles. In comparing the effect of the type of the silica particles, the dissolution rate of solid dispersion particles with Sylysia 350 was faster than that with Aerosil 200. The formulation amount of IMC did not affect on the amorphous state of IMC in the resultant solid dispersion particles in powder X-ray diffraction patterns. However, the area of the melting peak of IMC in the solid dispersion particles increased and an exothermic peak owing to recrystallization was observed with increasing the IMC content in the DSC patterns. The dissolution rate of IMC from the solid dispersion particles with Sylysia 350 was faster than that of Aerosil 200 irrespective of IMC content. In stability test, amorphous IMC in the solid dispersion particles with each silica particles did not crystallize under storing at severe storage conditions (40 degrees C, 75% RH) for 2 months, while amorphous IMC without silica easily crystallized under same conditions.     

Studies on Flash Evaporation for Preparation of Porous Solid Dispersions Using Piroxicam as a Model Drug

An amalgamation of solid dispersion and capillarity has been attempted in present study for enhancement of dissolution rate of poorly soluble drugs. Flash evaporation technique was utilized for enhancement of the dissolution rate of piroxicam. One of the major problems with this drug is its very low solubility in biological fluids, which results in poor bioavailability after oral administration. An attempt was made to enhance the dissolution rate of piroxicam by converting it into porous solid dispersion by flash evaporation method using polyvinylpyrrolidone (PVP) 40,000 as a water-soluble carrier. The resulting solid dispersions were characterized by DSC, FTIR, and X-ray diffraction. In vitro dissolution study revealed significant improvement of dissolution profile of piroxicam. The release of drug from porous solid dispersions containing PVP was superior to those of marketed product, conventional nonporous solid dispersion prepared by solvent evaporation method and drug alone. The steep increase in dissolution rate of porous form is attributable to combined effect of solid dispersion and capillarity.     

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.     

Preparation, characterization and in vitro dissolution studies of solid dispersion of meloxicam with PEG 6000

The poor solubility and wettability of meloxicam leads to poor dissolution and hence showing variations in bioavailability. The present study is aimed to increase solubility and dissolution of the drug using solid dispersion techniques. The solid binary systems were prepared at various drug concentrations (5-40%) with polyethylene glycol 6000 by different techniques (physical mixing, solvent evaporation). The formulations were characterized by solubility studies, differential scanning calorimetry, fourier transform infrared spectroscopy and in vitro dissolution rate studies. The solubility of drug increased linearly with increase in polymer concentration showing A(L) type solubility diagrams. Infrared spectroscopy studies indicated the possibility of hydrogen bonding with polymer. The differential scanning calorimetry and powder X ray diffraction demonstrated the presence of polymer as eutectica or monotectica in solid dispersion along with the physical characteristics of the drug (crystalline, amorphous or a mixture of both). The solid dispersions of the drug demonstrated higher drug dissolution rates than physical mixtures and pure meloxicam, as a result of increased wettability and dispersibility of drug in a solid dispersion system.