An update on polymer-lipid hybrid systems for improving oral drug delivery

Introduction: A promising approach that has recently emerged to overcome the complex biobarriers and interrelated challenges associated with oral drug absorption is to combine the benefits of polymeric and lipid-based nanocarriers within one hybrid system. This multifaceted formulation strategy has given rise to a plethora of polymer-lipid hybrid (PLH) systems with varying nanostructures and biological activities, all of which have demonstrated the ability to improve the biopharmaceutical performance of a wide range of challenging therapeutics.

Areas covered: The multitude of polymers that can be combined with lipids to exert a synergistic effect for oral drug delivery have been identified, reviewed and critically evaluated. Specific focus is attributed to preclinical studies performed within the past 5 years that have elucidated the role and mechanism of the polymer phase in altering the oral absorption of encapsulated therapeutics.

Expert opinion: The potential of PLH systems has been clearly identified; however, improved understanding of the structure–activity relationship between PLH systems and oral absorption is fundamental for translating this promising delivery approach into a clinically relevant formulation. Advancing research within this field to identify optimal polymer, lipid combinations and engineering conditions for specific therapeutics are therefore encouraged.     

自乳化药物传递系统的研究进展

本文对近几年国内外有关自乳化药物传递系统的特点、吸收机制、组成、影响因素及其在药剂学方面的应用进行了归纳和分析。自乳化药物传递系统可显著地提高难溶性或亲脂性药物口服生物利用度，具有广阔的发展前景。     

Microemulsions as drug delivery systems to improve the solubility and the bioavailability of poorly water-soluble drugs

Importance of the field: Microemulsions have been studied extensively as potential drug delivery vehicles for poorly water-soluble drugs. An understanding of the physicochemical and biopharmaceutical characteristics of the microemulsions according to administration routes will provide guidance for designing the formulations of microemulsions.

Areas covered in this review: In this paper, the use and the characteristics of microemulsions as drug delivery vehicles are reviewed. As the formulations of the microemulsion always include a great amount of surfactant and co-surfactant, which may cause hemolysis or histopathological alterations of the tissue, the potential toxicity or the irritancy of microemulsions is also discussed in this paper.

What the reader will gain: Developments of microemulsions for poorly water-soluble drugs in recent years are included in this review. Several factors limiting the commercial or clinical use of microemulsions are also discussed.

Take home message: Considering the potential in enhanced drug uptake/permeation and facing the limitations, their unique properties make microemulsions a promising vehicle for poorly water-soluble drugs.     

阿立哌唑自乳化释药系统的制备与质量评价

目的 制备阿立哌唑自乳化释药系统（ARP-SEDDSs）以提高药物的口服生物利用度。方法 HPLC法检测ARP在不同的油、表面活性剂和助表面活性剂中的溶解度,根据溶解度确定处方组成;采用伪三元相图筛选SEDDSs的处方比例;通过动态光散射、透射电镜、稀释稳定性和体外溶出对ARP-SEDDSs进行表征;大鼠分别ig给予自制ARP-SEDDSs和ARP混悬液（20 mg·kg^-1）后,HPLC法进行药动学研究,考察大鼠ig ARP-SEDDSs的生物利用度。结果 以油酸作为油相,以聚乙二醇15-羟基硬脂酸酯和异丙醇作为表面活性剂和助表面活性剂,优化得到ARP-SEDDSs处方为油酸-聚乙二醇15-羟基硬脂酸酯-异丙醇为2.0∶5.6∶2.4,载药量为10 mg·g^-1;ARP-SEDDSs经水稀释后可快速形成微乳,在透射电镜下可观察到微乳呈类球形,经动态光散射仪检测其平均粒径为（54.6±2.3）nm,聚合物分散性指数（PDI）为0.201±0.011,Zeta电位（-13.5±0.4）mV;ARP-SEDDSs在pH 6.8磷酸盐缓冲液中10 min的药物溶出度接近100%,远高于阿立哌唑口崩片（约10%）。大鼠体内药动学研究表明,与ARP混悬液相比,ARP-SEDDSs相对生物利用度为248.8%。结论 将ARP制备成自乳化释药系统,有助于药物快速溶出,显著提高了ARP的口服生物利用度。     

Self-emulsifying drug delivery systems in oral (poly)peptide drug delivery

Introduction: Oral administration of most therapeutic peptides and proteins is mainly restricted due to the enzymatic and absorption membrane barrier of the GI tract. In order to overcome these barriers, various technologies have been explored. Among them, self-emulsifying drug delivery systems (SEDDS) received considerable attention as potential carriers to facilitate oral peptide and protein delivery in recent years.

Areas covered: This review article intends to summarize physiological barriers which limit the bioavailability of orally administrated peptide and protein drugs. Furthermore, the potential of SEDDS to protect incorporated peptides and proteins towards peptidases and proteases and to penetrate the mucus layer is reviewed. Their permeation-enhancing properties and their ability to release the drug in a controlled way are described. Moreover, this review covers the results of in vivo studies providing evidence for this promising approach.

Expert opinion: As SEDDS can: i) provide a protective effect towards a presystemic metabolism; ii) efficiently permeate the intestinal mucus gel layer in order to reach the absorption membrane; and iii) be produced in a very simple and cost-effective manner, they are a promising tool for oral peptide and protein drug delivery.     

Oral self-nanoemulsifying peptide drug delivery systems: impact of lipase on drug release

Abstract

It was the aim of this study to evaluate the impact of lipases on the release behaviour of a peptide drug from oral self-nanoemulsifying drug delivery systems. Octreotide was ion paired with the anionic surfactants deoxycholate, decanoate, oleate and dodecylsulphate. The lipophilic character of these complexes was characterised by determining the n-octanol/buffer pH 7.4 partition coefficient. In the following the most hydrophilic complex was incorporated in a likely lipase degradable self-nanoemulsifying drug delivery systems (SNEDDS) formulation containing a triglyceride (olive oil; Pharm.Eur.) and in a likely not lipase degradable SNEDDS containing lipids and surfactants without any ester bonds. After 1:100 dilutions in artificial intestinal fluid (AIF), the lipid droplets were characterised regarding size distribution. With these SNEDDS, drug release studies were performed in AIF with and without lipase. Results showed that the most hydrophobic complex can be formed with deoxycholate in an octreotide:anionic surfactant ratio of 1:5. Even 73.1?±?8.1% of it could be quantified in the n-octanol phase. SNEDDS containing octreotide | olive oil | cremophor EL | propylene glycol (2|57|38|3) and octreotide | liquid paraffin | Brij 35 | propylene glycol | ethanol (2|66.5|25|5|1.5) showed after dilution in AIF, a mean droplet size of 232?±?53?nm and 235?±?50?nm, respectively. Drug release studies showed a sustained release of octreotide out of these formulations for at least 24?h, whereas?>?80% of the drug was released within 2?h in the presence of lipase in the case of the triglyceride containing SNEEDS. In contrast the release profile from ester-free SNEDDS was not significantly altered (p?<?0.05) due to the addition of lipase providing evidence for the stability of this formulation towards lipases. According to these results, SNEDDS could be identified as a useful tool for sustained oral peptide delivery taking an enzymatic degradation by intestinal lipases into considerations.     

Recent approaches of lipid-based delivery system for lymphatic targeting via oral route

Abstract

Lymphatic system is a key target in research field due to its distinctive makeup and huge contributing functions within the body. Intestinal lymphatic drug transport (chylomicron pathway) is intensely described in research field till date because it is considered to be the best for improving oral drug delivery by avoiding first pass metabolism. The lymphatic imaging techniques and potential therapeutic candidates are engaged for evaluating disease states and overcoming these conditions. The novel drug delivery systems such as self-microemulsifying drug delivery system, nanoparticles, liposomes, nano-lipid carriers, solid lipid carriers are employed for delivering drugs through lymphatic system via various routes such as subcutaneous route, intraperitoneal route, pulmonary route, gastric sub-mucosal injection, intrapleural and intradermal. Among these colloidal particles, lipid-based delivery system is considered to be the best for lymphatic delivery. From the last few decades, mesenteric lymph duct cannulation and thoracic lymph duct cannulation are followed to assess lymphatic uptake of drugs. Due to their limitations, chylomicrons inhibitors and in-vitro models are employed, i.e. lipolysis model and permeability model. Currently, research on this topic still continues and drainage system used to deliver the drugs against lymphatic disease as well as targeting other organs by modulating the chylomicron pathway.     

Advances in lipid-based drug delivery: enhancing efficiency for hydrophobic drugs

Introduction: Many drug candidates with high therapeutic efficacy have low water solubility, which limits the administration and transport across physiological barriers, for example, the tumor tissue barrier. Therefore, strategies are needed to permeabilize the physiological barriers safely so that hydrophobic drugs may be delivered efficiently.

Areas covered: This review focuses on prospects for therapeutic application of lipid-based drug delivery carriers that increase hydrophobic drugs to improve their solubility, bioavailability, drug release, targeting and absorption. Moreover, novel techniques to prepare for lipid-based drug delivery to extend pharmaceuticals with poor bioavailability such as surface modifications of lipid-based drug delivery are presented. Industrial developments of several drug candidates employing these strategies are discussed, as well as applications and clinical trials.

Expert opinion: Overall, hydrophobic drugs can be encapsulated in the lipid-based drug delivery systems, represent a relatively safe and promising strategy to extend drug retention, lengthen the lifetime in the circulation, and allow active targeting to specific tissues and controllable drug release in the desirable sites. However, there are still noticeable gaps that need to be filled before the theoretical advantage of these formulations may truly be realized such as investigation on the use of lipid-based drug delivery for administration routes. This research may provide further interest within the area of lipid-based systems, both in industry and in the clinic.     

Ophthalmic drug delivery systems

New ophthalmic drug delivery systems are curently receiving increased attention, in part because of the expected emergence of new drugs with short biological half-lives whose usefulness may depend on a more continuous drug supply than eyedrops can provide, but also because of the potential of some delivery systems to reduce the side effects of the more potent drugs recently introduced or presently under investigation. Some ophthalmic delivery systems extend the duration of drug action by enhancement of corneal absorption; these systems include soluble gels and emulsions, hydrophilic ocular inserts, ion-pair associations, prodrugs, and liposomes. Since these systems enhance the “pulse entry” of the drug, they are limited to use with drugs whose dose-related side effects are not serious. Other delivery systems provide for a controlled release of drugs and therefore minimize the pulse entry with which side effects are associated. They can be based on any of several different mechanisms and include both erodible and nonerodible matrices. The various delivery systems that have recently been developed and those that are currently known to be under investigation are described in this paper, along with some observations regarding the future outlook of ophthalmic drug delivery systems.     

生物技术药物口服微粒给药系统的研究进展

综合国内外相关文献报道．对生物技术药物口服微粒给药系统在胃肠道中的吸牧机制、所遇到的主要障碍、影响因素、提高生物利用度的策略以及常用生物技术药物口服微粒给药系统等进行综述，旨在为新型生物技术药物口服给药系统提供思路和方法。     

Self-emulsifying drug delivery system and the applications in herbal drugs

Abstract

Herbal drugs have been used for thousands of years in the east and have had a recent resurgence in popularity among consumers in the west. However, most of herbal drug are poorly soluble and have hydrophobic properties and poor distribution, leading to reduced bioavailability and hence decreased treatment efficacy, requiring repeated administration or increased dose. In the past few decades, considerable attention has been focused on the development of self-emulsifying drug delivery system (SEDDS) for herbal drugs. SEDDS is isotropic and thermodynamically stable solutions consisting of oil, surfactant, co-surfactant and drug that can spontaneously form oil-in-water micro/nanoemulsion when mixed with water under gentle stirring. The formulation can be a viable alternative to classical formulations to take advantage of their lipophilic nature and to solve their problems of poor solubility, poor bioavailability, low oral absorption and instability. The mechanism of self-emulsification, solubility studies, construction of phase diagram, optimization and characterization of herbal drugs-loaded SEDDS formulation and in situ absorption evaluation of herbal drugs in rat intestine are presented in our article.     

Solid self-nanoemulsifying drug delivery system (S-SNEDDS) containing phosphatidylcholine for enhanced bioavailability of highly lipophilic bioactive carotenoid lutein

The objectives of this study was to prepare solid self-nanoemulsifying drug delivery system (S-SNEDDS) containing phosphatidylcholine (PC), an endogenous phospholipid with excellent in vivo solubilization capacity, as oil phase for the delivery of bioactive carotenoid lutein, by spray drying the SNEDDS (liquid system) containing PC using colloidal silica (Aerosil® 200 VV Pharma) as the inert solid carrier, and to evaluate the enhanced bioavailability (BA) of lutein from S-SNEDDS. The droplet size analyses revealed droplet size of less than 100 nm. The solid state characterization of S-SNEDDS by SEM, DSC, and XRPD revealed the absence of crystalline lutein in the S-SNEDDS. The bioavailability study performed in rabbits resulted in enhanced values of C_max and AUC for S-SNEDDS. The enhancement of C_max for S-SNEDDS was about 21-folds and 8-folds compared with lutein powder (LP) and commercial product (CP), respectively. The relative BA of S-SNEDDS compared with CP or LP was 2.74-folds or 11.79-folds, respectively. These results demonstrated excellent ability of S-SNEDDS containing PC as oil phase to enhance the BA of lutein in rabbits. Thus, S-SNEDDS containing PC as oil phase could be a useful lipid drug delivery system for enhancing the BA of lutein in vivo.     

Development of a high-throughput in vitro intestinal lipolysis model for rapid screening of lipid-based drug delivery systems

PurposeTo develop a high-throughput in vitro intestinal lipolysis (HTP) model, without any means of pH-stat-titration, to enable a fast evaluation of lipid-based drug delivery systems (LbDDS).Material and methodThe HTP model was compared to the traditionally used dynamic in vitro lipolysis (DIVL) model with regard to the extent of lipid digestion and drug distribution of two poorly soluble model drugs (cinnarizine and danazol), during digestion of three LbDDS (LbDDS I–III).ResultThe HTP model was able to maintain pH around 6.5 during digestion, without the addition of NaOH to neutralize the free fatty acids (FFAs), due to an increased buffer capacity. Cinnarizine was primarily located in the aqueous phase during digestion of all three LbDDS and did not differ significantly between the two models. The distribution of danazol varied from formulation to formulation, but no significant difference between the models was observed. The triacylglycerides (TAG) in LbDDS III were digested to the same extent in both models, whereas the TAG present in LbDDS II was digested slightly less in the HTP model. No TAG was present in LbDDS I and digestion was therefore not analyzed.ConclusionThe HTP model is able to predict drug distribution during digestion of LbDDS containing poorly water soluble drugs in the same manner as the DIVL model. Thus the HTP model might prove applicable for high-throughput evaluation of LbDDS in e.g. 96 well plates or small scale dissolution equipment.     

纳米给药系统在难溶性药物制剂研究中的应用

近年来,难溶性药物给药系统一直是制剂学研究的重点和难点之一。纳米载体由于其良好的生物相容性及可装载大量难溶性药物等特点而被广泛应用于难溶性药物给药系统的研究,该类载体主要包括纳米粒、脂质体、纳米乳、聚合物胶束、纳米混悬剂等。本文结合近几年国内外文献报道,对纳米给药系统在难溶性药物制剂研究中的最新进展进行概述。     

pH-Responsive carriers for oral drug delivery: challenges and opportunities of current platforms

Oral administration is a desirable alternative of parenteral administration due to the convenience and increased compliance to patients, especially for chronic diseases that require frequent administration. The oral drug delivery is a dynamic research field despite the numerous challenges limiting their effective delivery, such as enzyme degradation, hydrolysis and low permeability of intestinal epithelium in the gastrointestinal (GI) tract. pH-Responsive carriers offer excellent potential as oral therapeutic systems due to enhancing the stability of drug delivery in stomach and achieving controlled release in intestines. This review provides a wide perspective on current status of pH-responsive oral drug delivery systems prepared mainly with organic polymers or inorganic materials, including the strategies used to overcome GI barriers, the challenges in their development and future prospects, with focus on technology trends to improve the bioavailability of orally delivered drugs, the mechanisms of drug release from pH-responsive oral formulations, and their application for drug delivery, such as protein and peptide therapeutics, vaccination, inflammatory bowel disease (IBD) and bacterial infections.     

阿德福韦酯自乳化制剂大鼠体内药动学的初步研究

目的：研究阿德福韦酯自乳化制剂在大鼠体内的药动学过程。方法：以随机分组组间对照实验设计方法,通过高效液相色谱法测定6只SD大鼠（两组）体内单剂量灌胃服用阿德福韦酯自乳化制剂和片剂100mg／kg后不同时间点的血药浓度,并计算其药动学参数。结果：自乳化制剂组大鼠的Cmax为2．5094μg／mL,AUC为277．2911μg·min／mL）;片剂组大鼠的Cmax为1．7258μg／mL,AUC为215．9196μg·min／mL）。结论：阿德福韦酯自乳化制剂的口服生物利用度优于片剂。     

阿德福韦酯自乳化制剂的研究

目的：研究阿德福韦酯自乳化制剂,探求其最佳处方配比。方法：通过对油相、水、乳化剂的选择和配比优化,成功地将阿德福韦包埋在乳液中,由三元相图得到相应的自乳化区域,并结合自乳化速率、粒径测定、及溶解度试验的考察筛选处方,寻找出最佳的搭配和处方配比。结果：优选的阿德福韦酯自乳化制剂处方中油相为辛酸甘油三酯,表面活性剂为聚氧乙烯（35）蓖麻油。最终确立阿德福韦酯自乳化制剂的最优配方比为：辛酸甘油三酯：聚氧乙烯（35）蓖麻油（7：3）。结论：初步成功地制备了阿德福韦酯自乳化制剂。     

Susceptibility to Lipase-Mediated Digestion Reduces the Oral Bioavailability of Danazol After Administration as a Medium-Chain Lipid-Based Microemulsion Formulation

PURPOSE: To investigate the impact of lipidic formulation type on in vitro dispersion and digestion properties and the relationship to oral bioavailability, using danazol as a model lipophilic poorly water-soluble drug. METHODS: Three lipid-based danazol formulations [a long-chain triglyceride solution (LCT-solution) and self-microemulsifying drug delivery systems (SMEDDS) based on long-chain (C18) lipids (LC-SMEDDS) and medium-chain (C8-C10) lipids (MC-SMEDDS)] were administered to fasted beagle dogs and compared with a micronized danazol formulation administered postprandially and in the fasted state. In vitro dispersion and particle size data for the two SMEDDS were compared, and the distribution/solubilization patterns of danazol across the various phases produced during in vitro digestion quantified. RESULTS: The LCT-solution and LC-SMEDDS formulations significantly enhanced the oral bioavailability of danazol when compared to fasted administration of the powder formulation. In contrast, and despite displaying excellent dispersion properties, the MC-SMEDDS resulted in little enhancement in danazol bioavailability. In support of the in vivo findings, in vitro digestion of the medium-chain formulation resulted in significant drug precipitation when compared with the long-chain lipid formulations. CONCLUSIONS: Digestion of microemulsion preconcentrate formulations based on medium-chain lipids may limit in vivo utility when compared with similar formulations based on long chain lipids.     

Increasing the Proportional Content of Surfactant (Cremophor EL) Relative to Lipid in Self-emulsifying Lipid-based Formulations of Danazol Reduces Oral Bioavailability in Beagle Dogs

Purpose To investigate the impact of a change in the proportions of lipid, surfactant and co-solvent on the solubilisation capacity of self-emulsifying formulations of danazol during in vitro dispersion and digestion studies and correlation with in vivo bioavailability in beagle dogs. Methods Formulations from within the phase diagram of the pseudo-ternary system composed of soybean oil:maisine 35-1 (1:1 w/w), Cremophor EL and ethanol were assessed in vitro on dispersion and digestion. The relative bioavailability of danazol after administration of a series of these formulations was also determined. Results All formulations formed microemulsions in the presence of water and no drug precipitation was observed on dispersion. In contrast, drug solubilisation was markedly affected by lipase-mediated digestion and a reduction in lipid (and increase in surfactant) content resulted in increased drug precipitation. Consistent with these data, the bioavailability of danazol decreased significantly when the lipid content in the formulations was reduced. Conclusion A rank-order correlation was observed between the patterns of solubilisation obtained during in vitro digestion and the in vivo performance of self-emulsifying formulations of danazol. In general a decrease in the lipid content and an increase in the proportions of surfactant and co-solvent resulted in reduced danazol bioavailability.