水飞蓟素前体脂质体的制备和大鼠药代动力学的研究水飞蓟素前体脂质体的制备和大鼠药代动力学的研究

目的为了提高水飞蓟素的口服生物利用度，研制水飞蓟素前体脂质体并对其理化性质进行考察；研究水飞蓟素前体脂质体的大鼠体内生物利用度。方法采用薄膜载体沉积法制备水飞蓟素前体脂质体，通过研究水合后脂质体的包封率、粒径、稳定性来考察其理化性质；将水飞蓟素前体脂质体在体外进行水合，再给予大鼠灌胃，用RP-HPLC法测定不同时间血浆中总的和游离的水飞蓟素的浓度，通过3P97程序计算药代动力学参数。结果用该法制得的前体脂质体包封率可达90%以上，平均粒径为238.8 nm，稳定性较好；药代动力学研究表明水飞蓟素脂质体在体内吸收较快，生物利用度较高。结论采用薄膜载体沉积法制备水飞蓟素前体脂质体，制备工艺简单，易于工业化生产；将水飞蓟素制备成前体脂质体提高了水飞蓟素的生物利用度。     

川陈皮素自组装前体脂质体大鼠在体肠吸收研究

目的 考察川陈皮素自组装前体脂质体在大鼠肠道的吸收情况。方法 以川陈皮素溶液、普通脂质体为对照,采用单向灌流法,研究不同肠段川陈皮素自组装前体脂质体的大鼠肠道吸收动力学。结果 3种制剂在全肠段都有吸收,在各个肠段,3种制剂的净累积吸收量、Ka和Peff均表现为川陈皮素自组装前体脂质体>川陈皮素普通脂质体>川陈皮素(P<0.05)。结论 川陈皮素自组装前体脂质体可显著促进川陈皮素的口服吸收。     

槲皮素前体脂质体的质量考察

目的制备液体型槲皮素前体脂质体,并对制剂质量进行考察。方法采用一种新型前体脂质体制备方法制备液体型槲皮素前体脂质体,将脂质体膜材和药物等以一定比例溶于分散介质中,形成一种无水的澄明溶液。考察其水合后粒子形态、粒径、电位、包封率及自组装速度等理化性质,并评价其体外释药性质。结果槲皮素前体脂质体遇水即可快速自组装成纳米级含药脂质体混悬液,水合后形态多为类球形,平均粒径为228.7nm,Zeta电位为21.2 mV,包封率可达90%以上,体外释药符合Higuchi方程。结论槲皮素口服前体脂质体制备工艺简单可行,包封率高,具有一定的缓释效果。     

洛伐他汀自组装前体脂质体的制备及其理化性质的研究

目的:为研究洛伐他汀新剂型,制备洛伐他汀新型前体脂质体,并对其质量进行考察。方法:采用一种新型前体脂质体制备方法将洛伐他汀制成自组装前体脂质体,对水合后脂质体的形态、粒径、Zeta电位、包封率、自组装速度、稳定性等进行考察,验证这种新型前体脂质体制备方法用于制备洛伐他汀脂质体的可行性。结果:所形成的洛伐他汀脂质体包封率为95.4%±6.7%,平均粒径为(327.4±29.6)nm,Zeta电位值为-(22.4±1.5)mV。洛伐他汀自组装前体脂质体可在60 s内自发形成脂质体并达到分散平衡;以人工胃液为稀释介质,洛伐他汀脂质体在12 h内稳定。结论:采用新型前体脂质体制备方法可将洛伐他汀制成洛伐他汀脂质体,形成的脂质体包封率较高且具有良好的稳定性。     

丹皮酚前体脂质体的研制及其特性

目的：研究丹皮酚前体脂质体的制备方法，提高丹皮酚脂质体的稳定性。方法：采用薄膜一超声一冷冻干燥法。选择合适的冻干保护剂制备丹皮酚前体脂质体，并对水合后脂质体的形态、粒径、包封率和稳定性进行考察。结果：选择10％的蔗糖为保护剂。制得的丹皮酚前体脂质体经水合后主要为单室脂质体，粒径分布较均匀。平均粒径149．7nm．药物包封率为73．9％，25℃贮存6个月，外观、含量及包封率无明显变化。结论：该方法制备丹皮酚前体脂质体可行，包封率较高且有良好的稳定性。     

柔红霉素长循环脂质体的药剂学性质及大鼠体内药代动力学研究

目的研究柔红霉素长循环脂质体的药剂学性质及大鼠体内药代动力学。方法考察柔红霉素长循环脂质体的形态和粒径分布、包封率和加速实验稳定性;建立脂质体中柔红霉素含量测定的可见分光光度法和HPLC方法;考察脂质体在Hepes缓冲液(pH 7.5)和大鼠血清中的体外释放行为。考察脂质体在大鼠体内的药代动力学行为。结果制备的柔红霉素长循环脂质体包封率高(>85%)、稳定性好,平均粒径为56.3 nm,体外释放慢;长循环脂质体的T_1/2α和AUC分别是注射剂的17.6和96倍。结论制备的长循环脂质体包封率较高,药剂学性质稳定,在大鼠体内的药代动力学参数优于注射剂,能达到长循环目的。     

卡巴拉汀脂质体的制备及其大鼠鼻腔给药的药代动力学

制备卡巴拉汀脂质体,研究其在大鼠鼻腔给药的药代动力学。采用硫酸铵梯度法制备包载卡巴拉汀的脂质体,考察粒径、zeta电位和包封率,测定脂质体在磷酸盐缓冲液中的释放;大鼠鼻腔给予卡巴拉汀脂质体,以安替比林为内标,采用高效液相色谱-串联质谱法(HPLC/MS)测定血浆中卡巴拉汀的浓度,运用DAS 2.0软件拟合药代动力学参数。经筛选制备的脂质体包封率为(33.41±6.58)%,平均粒径在154～236 nm,zeta电位(-10.47±2.41)mV。脂质体的体外释放符合一级动力学方程。大鼠鼻腔给药后,Cmax,Tmax和AUC0-∞分别为(1.50±0.15)mg.L-1,15 min和(89.06±8.30)mg.L-1.min。卡巴拉汀制备成脂质体经大鼠鼻腔给药后,吸收迅速,血药浓度可以达到一定水平。     

葛根素前体脂质体的质量考察

目的:制备葛根素前体脂质体,并对制剂质量进行考察。方法:采用山梨醇载体沉积法制备葛根素前体脂质体,并对制剂的形态学、包封率、粒径分布、体外释药、稳定性等性质进行考察。结果:本实验制备的脂质体形态多为圆形或椭圆形,平均粒径为278nm,Zeta电位为-17.5mV,包封率为(43.5±1.3)%,体外释药符合一级动力学方程,常温放置稳定。结论:葛根素前体脂质体包封率较高,具有一定的缓释效果,稳定性较好。     

异甘草素脂质体的制备及稳定性考察

目的:制备异甘草素脂质体并考察其包封率及稳定性.方法:采用超声波薄膜分散法制备异甘草素脂质体,正交设计优选制备工艺;透射电镜观察形态;激光粒径仪测定平均粒径;葡聚糖凝胶层析法分离含药脂质体与游离药物并测定包封率;离心加速实验考察脂质体的稳定性.结果:异甘草素脂质体的平均粒径为233.1 nm,跨距为0.74,平均包封率为82.57%,稳定性良好.结论:该法制备异甘草素脂质体工艺可行,质量稳定.     

尼莫地平前体脂质体的制备及其质量评价

目的制备尼莫地平前体脂质体,并进行质量评价,以期得到高效、低毒和稳定的尼莫地平新剂型。方法采用叔丁醇-水共溶剂冻干法制备尼莫地平前体脂质体,考察了影响药物包封率的因素,并对重建脂质体的药物含量、包封率、粒径、Zeta电位、溶血性及稳定性进行考察。结果磷脂浓度、表面电荷是影响尼莫地平脂质体包封率的主要因素。尼莫地平脂质体包封率大于98%,平均粒径为57 nm,Zeta电位小于-20 mV,无溶血性,稳定性好。结论采用叔丁醇水共溶剂冻干法获得了高包封率、粒径均一、无溶血性、稳定的尼莫地平前体脂质体制剂,可用于静脉注射给药。     

盐酸小檗碱前体脂质体的制备及理化性质研究

目的制备盐酸小檗碱前体脂质体,并对其理化性质进行考察。方法采用薄膜载体沉积法制备盐酸小檗碱前体脂质体,正交实验优选处方;透射电镜观察形态;马尔文激光粒度仪测定粒径;高效液相色谱法测定包封率。结果电镜下观察脂质体形态多为圆形或椭圆形,平均粒径为741nm,包封率为(29.93±1.32)%。结论该方法制备工艺简单,易于工业化生产。     

Preparation of silymarin proliposome: a new way to increase oral bioavailability of silymarin in beagle dogs

The aim of the present study was to find a method to increase oral bioavailability of silymarin, that is to say, by the preparation of silymarin proliposome and to compare the pharmacokinetic characteristics and bioavailability after oral administration of silymarin proliposome and silymarin in beagle dogs. Silymarin proliposome was prepared by the film-deposition on carriers. After the proliposome was contacted with water, the silymarin liposome suspensions formed automatically. The tests of physicochemical properties including SEM, TEM, encapsulation efficiency, dissolution studies, particle size of the reconstituted liposome and stability of the silymarin proliposome were determined by laser-particle-sizer, HPLC, etc. The concentrations of silymarin in plasma of beagle dogs and its pharmacokinetic behaviors after oral administration of silymarin liposome suspensions and silymarin were studied by RP-HPLC. The pharmacokinetic parameters were computed by software program 3p97. The encapsulation efficiency of silymarin liposome could be more than 90%, with an average particle size of about 196.4 nm and the proliposome appeared a very stability at 40 degrees C during 3 months. It was found that mean plasma concentration-time curves of silymarin after oral administration of liposome suspensions and silymarin in beagle dogs were both in accordance with open two-compartments model and first-order absorption. Pharmacokinetic parameters of silymarin proliposome and silymarin in beagle dogs were Tmax both 30 min; Cmax 472.62 and 89.78 ng mL(-1); and AUC0-infinity 2606.21 and 697 ng mL(-1)h, respectively. The high bioavailability of silymarin proliposome could be obtained by oral administration. Silymarin proliposome was stable and did enchance the gastrointestinal absorption of silymarin.     

A novel method to prepare liposomes containing amikacin.

This work describes a novel method to prepare liposomal amikacin composed of soyabean lecithin and cholesterol; these were also prepared using two other methods (cast film method and proliposome method). Encapsulation efficiency was evaluated. Liposomes prepared by the new method, which combines the method of preparing proliposomes with freeze-drying, had the highest encapsulation efficiency. The influence of drug to lipid ratio on the encapsulation efficiency was investigated. The in vitro efflux of amikacin from liposomes with different lecithin: cholesterol ratios was also investigated.     

两亲性壳聚糖包覆紫杉醇脂质体的制备及体外释放研究

目的:制备两亲性壳聚糖N-辛基-N,O-羧甲基壳聚糖包覆紫杉醇脂质体(PTX-LP-OCC),并考察其理化性质及体外释放行为。方法:采用基于乙醇的前体脂质体法制备紫杉醇脂质体并以OCC包覆,并以普通脂质体(PTX-LP)为对照,测定其包封率、粒径大小、电位,观测其形态及稳定性,然后采用全体液平衡反向透析法研究体外释放行为。结果:紫杉醇脂质体包封率为89.5%,粒径为236.5 nm,Zeta电位为-31.4 mV,多糖包覆修饰后药物包封率无显著变化,粒径及Zeta电位显著增加,脂质体稳定性显著提高,药物释放呈缓释特征,且突释显著降低。结论:两亲性壳聚糖包覆脂质体是一个有前景的抗肿瘤药物递送载体     

Formulation Development and in vitro Characterization of Proliposomes for Topical Delivery of Aceclofenac

Non-steroidal antiinflammatory drugs are routinely prescribed for the patients with rheumatic disease and such patients are at increased risk of serious gastrointestinal complications, when non-steroidal antiinflammatory drugs administered by oral route. The aim of the present study was to develop and characterized a vesicular drug carrier system (proliposome) for topical delivery of aceclofenac to overcome the problems related with oral route. Aceclofenac proliposome were prepared by the film-deposition on carriers method and characterized for size and surface morphology, drug content in both proliposomes and liposomal system, percent yield, in vitro drug release studies and drug permeation studies. The prepared system was also characterized for drug-excipients interaction by Fourier transform infrared spectrophotometer and stability studies. The size and surface morphology were studied using optical microscopy, scanning electron microscopy and transmission electron microscopy. A spherical shape of reconstituted aceclofenac liposome with an average vesicular size of about 500 nm was observed in photomicrographs. The maximum entrapment efficiency of reconstituted liposomes was 80.31% whereas the drug content in proliposomes was found to be more than 90%. In vitro release of drug was significantly retarded indicating sustained release of aceclofenac from proliposomes. Stability study was performed at various temperatures indicating that aceclofenac proliposomes are stable at lower temperature.     

兰索拉唑脂质体的制备及其药剂学性质考察

目的:研究兰索拉唑阳离子脂质体的制备方法并考察其药剂学性质。方法:采用正交设计筛选处方,乙醇注入法制备兰索拉唑脂质体;超滤法测定其包封率;用透射电镜观察脂质体的外观形态,并用粒径分析仪和Zeta电位仪分别测定脂质体的粒径和Zeta电位;进一步考察脂质体的释放规律。结果:所得脂质体包封率约为(80±1.23)%;形态为粒径均匀的球形和类球形,粒径为(184±21)nm,Zeta电位为(36.1±5)mV;脂质体的体外释放符合一级方程;具有较好的稳定性。结论:优选得到的脂质体处方和制备工艺合理、稳定,其体外释放具有缓释特点。     

依托泊苷隐形前体脂质体的构建及家兔体内药动学研究

构建依托泊苷隐形前体脂质体，并考察其在家兔体内的药动学。采用薄膜分散法构建窄白隐形脂质体；硫酸铵梯度法包封依托泊苷；结合真空冷冻干燥技术构建依托泊苷隐形前体脂质体。采用凝胶色谱法测定脂质体包封率；透射电镜观察脂质体的形态；电泳光散射技术测定Zeta电位与粒径分布；以市售依托泊苷注射液和普通脂质体为参比制剂，评价其在家兔体内药动学特点。脂质体平均包封率为83．92％±3．65％，粒径为（124．5±26．9）nm，Zeta电位为（-39．50±1．04）mV，家兔单剂量静脉注射1．5mg／kg依托泊苷制剂后呈二室模型特征，依托泊苷隐形前体脂质体的T1/2β为（19．26±3．16）h，AUC为（26．04±3．53）μg／h／mL；注射液的T1/2β为（0．94±0．21）h，AUC为（0．98±0．26）μg／h／mL；普通脂质体的T1/2β为（7．99±1．36）h,AUC为（11．65±1．70）μg/mL。构建的隐形前体脂质体包封率高，且延长了依托泊苷在血液中的循环时间。