Enhanced intestinal lymphatic absorption of saquinavir through supersaturated self-microemulsifying drug delivery systems

The therapeutic potential of saquinavir, a specific inhibitor of human immunodeficiency virus(HIV)-1 and HIV-2 protease enzymes, has been largely limited because of a low solubility and consequnt low bioavailability. Thus, we aimed to design a supersaturated selfmicroemulsifying drug delivery system(S-SMEDDS) that can maintain a high concentration of saquinavir in gastro-intestinal fluid thorugh inhibiting the drug precipitation to enhance the lymphatic transport of saquinavir and to increase the bioavailability of saquinavir considerably. Solubilizing capacity of different oils, surfactants, and cosurfactants for saquinavir was evaluated to select optimal ingredients for preparation of SMEDDS.Through the construction of pseudo-ternary phase diagram, SMEDDS formulations were established. A polymer as a precipitation inhibitor was selected based on its viscosity and drug precipitation inhibiting capacity. The S-SMEDDS and SMEDDS designed were administered at an equal dose to rats. At predetermined time points, levels of saquinavir in lymph collected from the rats were assessed. SMEDDS prepared presented a proper selfmicroemulsification efficiency and dispersion stability. The S-SMEDDS fabricated using the SMEDDS and hydroxypropyl methyl cellulose 2910 as a precipitation inhibitor exhibited a signficantly enhanced solubilizing capacity for saquinavir. The drug concentration in a simulated intestinal fluid evaluated with the S-SMEDDS was also maintained at higher levels for prolonged time than that examined with the SMEDDS. The S-SMEDDS showed a considerably enhanced lymphatic absoprtion of saquinavir in rats compared to the SMEDDS.Therefore, the S-SMEDDS would be usefully exploited to enhance the lymphatic absorption of hydrophobic drugs that need to be targeted to the lymphatic system.

Preparation and evaluation of alpha-mangostin solid self-emulsifying drug delivery system

Alpha-mangostin(AMG),a natural xanthone extracted from Garcinia mangostana Linn,has a variety of pharmacological therapeutic effects such as antioxidant activity,antibacterial activity,anticancer,and anti-inflammatory[1].However,it has poor aqueous-solubility and dissolution,which results in low bioavailability.Solid self-emulsifying drug delivery system(solid-SEDDS),an effective pharmaceutical strategy,offers the potential for enhancing the oral bioavailability of poorly water-soluble drugs[2].Therefore,solid-SEDDS is of interest as a potential method for enhancing the solubility and dissolution of AMG.

木犀草素过饱和自乳化释药系统的制备与大鼠药动学的研究

目的制备木犀草素过饱和自微乳化给药系统(luteolin supersaturation self microemulsifying drug delivery system,LUT-S-SMEDDS),以提高木犀草素的口服生物利用度。方法根据木犀草素在不同种类油相、乳化剂和助乳化剂中的溶解度、配伍相容性以及伪三元相图确定了LUT-SMEDDS的处方,并加入沉淀抑制剂制备成LUT-S-SMEDDS;评价了LUT-SMEDDS和LUT-S-SMEDDS的理化性质;比较了LUT-混悬剂、LUT-SMEDDS和LUT-S-SMEDDS经大鼠口服后体内药动学。结果选择单亚油酸甘油酯(maisine)为油相,辛酸/癸酸聚乙二醇甘油酯(labrasol)为乳化剂,二乙二醇单乙基醚(transcutol,HP)为助乳化剂,配比为体积比4∶4.5∶1.5,制备的LUT-SMEDDS和LUT-S-SMEDDS具有较强的自乳化性和分散稳定性;使用Soluplus作为沉淀抑制剂制备的LUT-S-SMEDDS可以在长时间内维持药物处于较高浓度状态;与LUT-混悬剂和LUT-SMEDDS相比,LUT-S-SMEDDS显著提高了大鼠的口服生物利用度。结论将木犀草素制备成过饱和自乳化释药系统,可加快药物溶出,抑制药物析晶,显著提高药物口服生物利用度。

载体-抑晶剂多元体系过饱和环孢素固体分散体的制备及体外溶出研究

目的 制备载体-抑晶剂多元体系过饱和环孢素固体分散体,并对其进行体外溶出研究。方法 采用热熔挤出技术,分别以HME专用辅料AFFINISOL HPMC 15LV、HPMC 100LV、聚乙烯吡咯烷酮VA64为载体,泊洛沙姆188、羟丙甲纤维素(HPMC E5)、聚乙烯己内酰胺-聚乙酸乙烯酯-聚乙二醇接枝共聚物(Soluplus)为抑晶辅料,制备单元及多元体系固体分散体。利用粉未X射线衍射法(PXRD)与差示扫描量热法(DSC)对其进行物相表征,并通过体外模拟过饱和溶出试验对聚合物的过饱和增溶能力、抑晶剂的抑晶效果进行考察。结果 结果表明,HPMC 100LV型号聚合物在过饱和增溶上具有较强优势。析晶抑制能力表现为泊洛沙姆188> HPMC E5> Soluplus,且抑晶剂联合用量在药物的0.5倍时抑晶效果最优。结论本研究构建了载体-抑晶剂多元体系固体分散体,可为进一步解决难溶性药物在胃肠道析出及过饱和释药系统的开发提供理论指导。

Supersaturated polymeric micelles for oral silybin delivery: the role of the Soluplus–PVPVA complex

Increasing the degree of supersaturation of drugs and maintaining their proper stability are very important in improving the oral bioavailability of poorly soluble drugs by a supersaturated drug delivery system(SDDS). In this study, we reported a complex system of Soluplus–Copovidone(Soluplus–PVPVA)loaded with the model drug silybin(SLB) that could not only maintain the stability of a supersaturated solution but also effectively promote oral absorption. The antiprecipitation effect of the polymers on SLB was observed using the solvent-shift method. In addition, the effects of the polymers on absorption were detected by cellular uptake and transport experiments. The mechanisms by which the Soluplus–PVPVA complex promotes oral absorption were explored by dynamic light scattering, transmission electron microscopy, fluorescence spectra and isothermal titration calorimetry analyses. Furthermore, a pharmacokinetic study in rats was used to demonstrate the advantages of the Soluplus–PVPVA complex. The results showed that Soluplus and PVPVA spontaneously formed complexes in aqueous solution via the adsorption of PVPVA on the hydrophilichydrophobic interface of the Soluplus micelle, and the Soluplus–PVPVA complex significantly increased the absorption of SLB. In conclusion, the Soluplus–PVPVA complex is a potential SDDS for improving the bioavailability of hydrophobic drugs.

高良姜素过饱和自纳米乳的制备及质量评价

目的研究高良姜素过饱和自纳米乳递药系统(galangin-SSNEDDS)的处方组成,并进行评价。方法通过溶解度试验、配伍试验及伪三元相图,筛选高良姜素自纳米乳处方,运用星点设计-效应面法优化处方;再以粒径、抑晶效果及溶出试验等考察高良姜素过饱和自纳米乳处方并对其进行理化性质及稳定性等评价。结果优化得到的高良姜素过饱和自纳米乳处方中油相为油酸聚乙二醇甘油酯(26.68%)、表面活性剂为聚氧乙烯蓖麻油(49.67%)、助表面活性剂为聚乙二醇400(23.65%)、促过饱和物质为聚乙烯己内酰胺-聚醋酸乙烯酯-聚乙二醇接枝共聚物(Soluplus)(3.0 mg·g^(-1)),载药量为28.0 mg·g^(-1)。高良姜素过饱和自纳米乳为金黄色透明黏稠液体,分散液为O/W型乳液,乳化时间为(67±4)s,平均粒径为(29.96±0.71)nm,PDI为(0.230±0.007),电位为(-6.00±0.63)mV。高良姜素过饱和自纳米乳稳定性良好,可在2 h内维持较高的过饱和度,有效避免药物结晶析出,显著提高原料药的释放量。结论高良姜素过饱和自纳米乳制备工艺简单,粒径分布均匀,稳定性好,能有效提高高良姜素的体外释放度,抑制结晶析出,有望提高高良姜素的生物利用度。

聚合物对pH依赖性药物沉淀抑制作用的研究进展

近年来,溶解度具有pH依赖性的药物在难溶性药物中占有越来越高的比例。药物学家通常利用过饱和药物递送系统来解决难溶性药物的溶解与释放问题,往往忽视pH依赖性药物即使在普通固体制剂中,也会在体内达到过饱和状态。聚合物对于维持过饱和状态有着显著的作用,对聚合物沉淀抑制作用的研究通常通过过饱和药物递送系统,这需要考虑其稳定性、复杂的制备过程等其他因素。因此,通过简单方法研究聚合物的沉淀抑制作用具有重要意义。本文介绍了“弹簧-降落伞”理论,综述了小规模实验对聚合物的沉淀抑制作用的研究,并对其机制进行了初步的探讨,以期为选择合适的沉淀抑制剂提供参考。

Integrated in silico formulation design of selfemulsifying drug delivery systems

The drug formulation design of self-emulsifying drug delivery systems(SEDDS)often requires numerous experiments,which are time-and money-consuming.This research aimed to rationally design the SEDDS formulation by the integrated computational and experimental approaches.4495 SEDDS formulation datasets were collected to predict the pseudo-ternary phase diagram by the machine learning methods.Random forest(RF)showed the best prediction performance with 91.3% for accuracy,92.0% for sensitivity and 90.7% for specificity in 5-fold cross-validation.The pseudo-ternary phase diagrams of meloxicam SEDDS were experimentally developed to validate the RF prediction model and achieved an excellent prediction accuracy(89.51%).The central composite design(CCD)was used to screen the best ratio of oil-surfactant-cosurfactant.Finally,molecular dynamic(MD)simulation was used to investigate the molecular interaction between excipients and drugs,which revealed the diffusion behavior in water and the role of cosurfactants.In conclusion,this research combined machine learning,central composite design,molecular modeling and experimental approaches for rational SEDDS formulation design.The integrated computer methodology can decrease traditional drug formulation design works and bring new ideas for future drug formulation design.

山楂叶总黄酮过饱和自乳化处方中不同脂链长度油相沉淀抑制能力研究

目的评价山楂叶总黄酮过饱和自乳化释药系统在水性介质的分散过程中油相的脂链长度与沉淀抑制能力的关系。方法以前期优化的山楂叶总黄酮自乳化处方为基础(吐温80-Transcutol P-油酸乙酯=47∶40∶13),将处方油相分别替换为长链油相Labrafil M 1944、Castor oil及中链油相Labrafac CC、Capryol 90和正辛酸;在体外模拟胃肠道溶出环境中,考察各油相过饱和自乳化处方的溶出度、载药前后的粒径变化。结果中链油相处方过饱和载药后粒径明显增大,粒径大小受不同溶出介质的影响明显,体外溶出30 min左右开始出现沉淀;长链油相处方的粒径受过饱和载药和溶出介质的影响不明显,体外溶出90 min无沉淀现象的出现。结论与中链油相相比,长链油相更有助于提高山楂叶总黄酮过饱和自乳化体系的沉淀抑制能力。

辅酶Q10过饱和自微乳的制备及特性研究

目的:制备辅酶Q10过饱和自微乳化释药系统(S-SMEDDS),并对其体外特性进行研究。方法:以粒径和自乳化时间为指标,通过Box-Behnken响应面法优化得出最佳SMEDDS处方比例;再通过考察混合油相中辅酶Q10的饱和溶解度来确定辅酶Q10 SMEDDS处方载药量;最后考察促饱和物质与辅酶Q10 SMEDDS的相容性及乳化后的稳定性,得出加入促饱和物质的种类和用量;并对辅酶Q10 S-SMEDDS的理化特性进行测定。结果:辅酶Q10 S-SMEDDS的最优处方为中链甘油三酯(MCT)-聚氧乙烯醚氢化蓖麻油(Cremophor EL)-辛酸癸酸聚乙二醇甘油酯(Labrasol)配比为30.92∶58.94∶40,辅酶Q10的载药量为8.3%,羟丙甲基纤维素K100(HPMC K100)的加入量为2%,形成的微乳粒径平均值为28.90 nm,乳化时间平均值为29.49 s,电位平均值为-31.15 mV,溶出度在20 min时达到90.11%。结论:所制备的辅酶Q10 S-SMEDDS可明显提高其溶解度,且乳化后稳定性更好,比普通SMEDDS更具有优势。

头孢托仑匹酯超饱和自乳化颗粒剂的制备及质量评价

目的制备添加了沉淀抑制剂的头孢托仑匹酯超饱和自乳化释药系统(CEFP-S-SEDDSs)及其颗粒剂,并评价其质量。方法通过溶解度实验和伪三元相图确定头孢托仑匹酯自乳化释药系统(CEFP-SEDDSs)的处方组成及比例,并以羟丙基甲基纤维素(HPMC-E5)作为沉淀抑制剂,制备得到CEFP-S-SEDDSs;采用硅酸铝镁作为载体固化CEFP-SSEDDSs,并与其他辅料混合制备成CEFP-S-SEDDSs颗粒剂;评价CEFP-S-SEDDSs颗粒剂的理化性质——热力学稳定性、自乳化效果、稀释稳定性、微观形态;比较CEFP-S-SEDDSs颗粒剂和市售头孢托仑匹酯颗粒剂的体外溶出度。结果CEFPSEDDSs的处方组成:单亚油酸甘油酯(Maisine CC)为油相,15-羟基硬脂酸聚乙二醇酯(Solutol HS15)为乳化剂,二乙二醇单乙基醚(Transcutol HP)为助乳化剂,配比为6∶2∶2。CEFP-S-SEDDSs及其颗粒剂经pH 1.2盐酸溶液稀释后均形成的微乳呈球状,分散性良好,其形成的微乳粒径分别为(104.6±3.7)、(139.5±3.8)nm,分散性指数(PDI)分别为(0.174±0.009)和(0.208±0.012),Zeta电位分别为(−13.6±0.6)mV和(−13.4±0.3)mV。CEFP-S-SEDDSs颗粒剂在pH 1.2盐酸介质溶液中溶出速度与市售头孢托仑匹酯颗粒剂相当;但当介质溶液pH值升高至6.8后,市售CEFP颗粒剂中的药物浓度急剧下降,大量药物以沉淀形式析出,CEFP-S-SEDDSs颗粒剂仅有少部分以沉淀形式析出。结论CEFP-SSEDDSs颗粒剂能够有效抑制因pH值变化而导致CEFP析出沉淀,有望促进药物充分吸收,提高药物生物利用度.

Membrane fusion reverse micelle platforms as potential oral nanocarriers for efficient internalization of free hydrophilic peptides

Orally administered peptides or proteins are garnering increasing preference owing to their superiority in terms of patient compliance and convenience.However,the development of oral protein formulations has stalled due to the low bioavailability of macromolecules that encounter the aggressive gastrointestinal environment and harsh mucus villi barrier.Herein,we propose an ideal reverse micelle/self-emulsifying drug delivery system(RM/SEDDS)nanoplatform that is capable of improving the oral bioavailability of hydrophilic peptides by preventing enzymatic degradation and enhancing mucosal permeability.Upon the passage through the mucus,the self-emulsifying drug delivery system with optimal surface properties effectively penetrates the viscoelastic mucosal barrier,followed by the exposure of the inner reverse micelle amphipathic vectors,which autonomously form continua with the lipidic cell membrane and facilitate the internalization of drugs.This membrane-fusion mechanism inaugurates a new way for hydrophilic peptide delivery in the free form,circumventing the traditional impediments of the cellular internalization of nanocarriers and subsequent poor release of drugs.And more importantly,reverse micelles are not spatially specific to the laden drugs,which enables their delivery for a myriad of peptide clinical drugs.In conclusion,as an exquisitely designed nanoplatform,RM/SEDDS overcomes multiple physiological barriers and opens a new path for drug cellular entry,providing new prospects for the development of oral drug delivery systems.

Soluplus在药物制剂中的应用

Soluplus(聚乙烯己内酰胺-聚乙酸乙烯酯-聚乙二醇接枝共聚物)为一种新型的两亲性非离子型药用高分子材料,玻璃转化温度(T_g)约70℃,安全性高,具有增溶、抑晶、空间稳定、助悬、热敏、成膜等作用,已在提高难溶性药物溶出速率和生物利用度等方面展示出良好的应用前景。本文综述了Soluplus在固体分散体、聚合物胶束、药物纳米晶体、过饱和自乳化给药系统等领域的应用进展,也指出Soluplus由于T_g值低、亲水性较强而适用范围受限。

水飞蓟宾过饱和自微乳给药系统在大鼠体内的药动学研究

目的研究水飞蓟宾过饱和自微乳给药系统(S-SMEDDS)在大鼠体内的药动学特征。方法 12只雄性SD大鼠随机分为对照组和实验组,每组6只,对照组大鼠ig给予水飞蓟宾自微乳(SMEDDS)533 mg/kg,实验组大鼠ig给予水飞蓟宾-S-SMEDDS 533 mg/kg。采用Accusampler清醒动物自动采血装置于不同时间点采血,HPLC法测定大鼠ig水飞蓟宾-S-SMEDDS后水飞蓟宾的血药浓度,非房室模型的统计矩分析方法计算药动学参数。结果对照组和实验组的tmax分别为(1.00±0.40)、(1.50±0.84)h,Cmax分别为(5.68±0.52)、(16.10±4.06)μg/mL,AUC0→t分别为(27.30±3.29)、(82.64±12.36)μg.h.mL 1。结论将水飞蓟宾制成S-SMEDDS可进一步提高其口服生物利用度。

水飞蓟宾过饱和自乳化给药系统的制备及性质研究

目的制备水飞蓟宾过饱和自乳化给药系统(S-SEDDS),并对其基本性质进行研究。方法通过溶解度试验、处方配伍试验和伪三元相图的绘制,以乳化时间、色泽和粒径为指标,筛选过饱和自微乳的处方组成。采用HPLC法测定水飞蓟宾S-SEDDS中药物;并以水飞蓟宾自乳化给药系统(SEDDS)为对照,考察药物溶出特征。结果水飞蓟宾S-SEDDS的最佳处方组成为:油相中链甘油三酯(MCT)40%、乳化剂聚氧乙烯氢化蓖麻油(Cremophor RH40)48%、助乳化剂辛酸癸酸聚乙二醇甘油酯(Labrasol)12%,羟丙甲纤维素(HPMC)的加入量为50 mg/g;水飞蓟宾S-SEDDS的平均粒径为49.6 nm,自乳化时间<3 min,载药量为39.3 mg/g;体外溶出试验表明处方中加入少量的沉淀抑制剂,可有效维持药物在S-SEDDS中的过饱和溶解状态。结论所制备的水飞蓟宾过饱和自微乳处方达到了设计要求,为新制剂开发奠定了基础。

促过饱和物质对多西他赛自乳化系统体外释药特性的影响

目的研究促过饱和物质对多西他赛自乳化系统(DTX-SEDDS)释药特性的影响。方法测定DTX-SEDDS的体外溶出度,并考查不同的促过饱和物质,促过饱和物质的不同用量,不同的投药量以及不同的释放介质对DTX-SEDDS体外释药特性的影响。结果不同的促过饱和物质如羟丙基甲基纤维素(HPMC)、十二烷基磺酸钠(SDS)、聚维酮(PVPK30)、AvicelRC591中,HPMC的促溶和稳定作用最强;不同厂家同黏度的HPMC对药物溶出影响差异不显著,同浓度不同黏度的HPMC对药物溶出影响有显著性差异,低黏度的好于高黏度HPMC;HPMC的不同用量对DTX-SEDDS体外释药有一定影响;当低黏度HPMC的用量为1%～8%,累积溶出百分率无显著差异,当高黏度HPMC的用量≤0.5%或≥8%时药物溶出明显减少;不同介质对药物溶出影响无显著性差异。推荐自乳化处方中选择加入1%～8%的低黏度HPMC(型号:山东50,山东100或上海K100)效果较好。结论过饱和物质HPMC可以明显提高DTX-SEDDS的溶出和稳定性,同时可减少自乳化油的用量,可提高自乳化制剂的临床安全性。

亲水性聚合物对自乳化药物传递系统稳定性的影响

目的:研究亲水性聚合物对自乳化药物传递系统(SMEDDS)稳定性的影响。方法:以非洛地平(FDP)为模型药物,采用高效液相色谱法测定FDP含量,考察不同介质种类[纯水和0.5%的共聚维酮VA64、羟丙基甲基纤维素(HPMC)E5、HPMC K100LV、HPMC K4M、聚乙烯吡咯烷酮(PVP)K30水溶液],以及不同介质浓度[0.1%、0.5%、1.0%的HPMC E5和共聚维酮VA64水溶液]对SMEDDS中剩余溶解状态FDP含量的影响。结果:SMEDDS在共聚维酮VA64、HPMC E5、HPMC K100LV、PVP K30、HPMC K4M、纯水中室温放置1 h时剩余溶解状态FDP的含量分别为92.7%、63.6%、50.2%、46.2%、36.0%和24.0%,表明维持系统过饱和能力的顺序为共聚维酮VA64>HPMC E5>HPMC K100LV>PVP K30>HPMC K4M>纯水。SMEDDS在0.1%、0.5%、1%的共聚维酮VA64和HPMC E5水溶液中室温放置1 h时剩余溶解状态FDP的含量分别为93.2%、95.1%、96.0%和48.4%、62.1%、75.1%。结论:共聚维酮VA64和HPMC E5可显著抑制药物从SMEDDS中析出,适于作为SMEDDS的稳定剂,其中共聚维酮VA64效果更好。

羟丙甲基纤维素作为过饱和自乳化给药系统的沉淀抑制剂的机制研究

羟丙甲基纤维素可促使自乳化给药系统(SEDDS)在胃肠道形成过饱和状态,对增强水难溶性药物吸收具有重要意义。本文在体外模拟胃肠道环境中研究了不同黏度的羟丙甲基纤维素[HPMC(K4M、K15M、K100M)]对SEDDS药物沉淀的抑制作用及其机制。结果显示:HPMC通过抑制晶核形成和晶体生长而抑制SEDDS在胃分散后的药物沉淀;HPMC对SEDDS的脂解速率有明显影响,而且有利于SEDDS脂解后药物分配进入水性分散相并抑制药物沉淀,其机制与HPMC黏度、分子质量以及形成的网络空间结构有关。这些研究结果为选择合适类型的HPMC作为过饱和SEDDS的沉淀抑制剂提供了参考依据。

超饱和体系在经皮给药中的应用

超饱和体系通过提高药物在溶剂中的热力学活度,从而增加药物释放及透皮驱动力,达到促渗目的。与传统物理及化学促渗法相比,该技术具有促渗效果显著、皮肤刺激性小、成本低廉、应用方便等显著优势,可单独使用或与其他促渗手段联用。但超饱和体系属热力学不稳定系统,极易形成结晶,影响透皮效果,在产品制备过程中应通过加入结晶抑制剂等方法维持体系的稳定性。本文简要概述了超饱和体系在经皮给药领域的应用及其结晶抑制现状。

穿心莲内酯过饱和自微乳化释药系统的制备及体外评价

目的：优选穿心莲内酯过饱和自微乳化释药系统的处方工艺,以提高穿心莲内酯的溶解度及生物利用度。方法：通过溶解度试验及伪三元相图的工艺初步筛选后,采用单纯形网格法,以粒径、多分散指数和乳化时间为指标,确定穿心莲内酯自微乳的处方;以析晶情况、粒径、多分散指数、乳化时间以及穿心莲内酯的溶出度为考察指标筛选最佳促过饱和抑制剂。结果：穿心莲内酯过饱和自微乳处方为油酸乙酯-（聚山梨酯-80）-聚乙二醇400-羟丙基甲基纤维素K4M（20∶35∶45∶1）。穿心莲过饱和自微乳乳化后的平均粒径（29.26±0.56）nm,多分散指数0.19±0.02,Zeta电位（-10.23±2.34）mV,乳化时间（62.39±2.03）s,1 h累积溶出度高达91%。结论：加入羟丙基甲基纤维素K4M后可明显抑制穿心莲内酯自微乳液的析晶时间,增加自微乳的稳定性;相较于普通自微乳可明显提高穿心莲内酯的体外溶出度,进而提高该成分的生物利用度。