Pulmonary Delivery of Liposomal Drugs

Abstract

This overview will discuss our studies of liposomes aerosols to treat diseases of the lung and will entail (i) formulation and characterization of liposome aerosols, including dry liposome powder aerosols, (ii) modulation of the pharmacokinetic profile of liposomal drugs delivered by aerosol or intratracheal instillation, (iii) liposome-alveolar macrophage interactions in vitro and in vivo, and (iv) safety of liposome aerosols in vivo in mice, sheep and healthy human volunteers. Water-soluble agents can be retained in liposomes during aerosolization with air-pressure nebulizers within certain limitations of liposome composition, size, and operating conditions. Dry powder liposome aerosols have been formulated and deliver water-soluble encapsulated substances efficiently. Pharmacokinetic profiles of liposomal drugs delivered via intratracheal instillation exhibit typical slow release plasma profiles indicating that the carrier is the rate-limiting barrier for release. Accordingly, pulmonary mean residence times are significantly prolonged and systemic concentrations remain low. Liposomes do not inhibit the phagocytic activity of alveolar macrophages in vitro and in vivo, have no apparent histopathologic effects on lung architecture even after chronic administration, and do not alter dynamic compliance, lung resistance, p_aO₂ and p_aCO₂ in awake, unanesthetized sheep and in healthy human volunteers. In conclusion, liposomes are a promising innocuous aerosol delivery system for drugs to achieve prolonged localized drug concentrations in the lung or intracellular drug targeting to alveolar macrophages.     

Evaluation of Multi-Target and Single-Target Liposomal Drugs for the Treatment of Gastric Cancer

We studied the effects of multi- and single-target liposomal drugs on human gastric cancer cell AGS both in vitro and in vivo. The cytotoxic effect of dihydrotanshinone I was significantly enhanced by treatment with octreotide-polyethylene glycol(PEG)-liposome, Arg-Gly-Asp(RGD)-PEG-liposome, and RGD/octreotide-PEG-liposome encapsulated with 0.5 μg/ml of dihydrotanshinone I to AGS cell for 24 h, compared to control. Furthermore, the AGS cell survival rate for multi-target versus single target liposomal drugs was significantly suppressed. Microsocpic examination revealed that significant cell death occurred in the multi- and single-target liposomal encapsulated drug groups. Significant suppression of tumor growth in AGS cell xenograft nude mice given octreotide-PEG-liposome, RGD/octreotide-PEG-liposome encapsulated drug, versus those given a free drug was noted after 13 d of experimentation with the multi-targeted liposome: up to 60.75% and 41.2% reduction of tumor volume as compared to dimethylsulfoxide (DMSO) control and the free drug groups respectively. The treated animals showed no gross signs of toxicity. The results have potential clinical application.     

Cryptococcus neoformans: in vivo protection of mice by pretreatment with pyran copolymer

Synthetic polyanions have been shown to alter host resistance to infection. The anticryptococcal effect of pyran copolymer was assessed in vivo and in vitro. Pretreatment with pyran copolymer significantly extended mean survival in mice lethally infected with Cryptococcus neoformans when compared to untreated animals (p < 0.01). The anticryptococcal effect of peritoneal exudate cells (PEC) elicited by 10% thioglycollate or pyran copolymer (25 mg/kg) was assessed in vitro. Initial percent phagocytosis of both encapsulated and non-encapsulated isolates of C. neoformans was greatest in the pyran elicited PEC. Significant killing of C. neoformans in vitro was observed only in pyran-activated PEC cultures combined with non-encapsulated cells of C. neoformans, although pyran PEC did inhibit initial growth of phagocytized encapsulated yeast cells. The protection of pyran copolymer pretreated mice from infection with C. neoformans, but the absence of significant killing of encapsulated yeast in vitro suggest a complex mechanism of host defense which may involve an activation of the reticuloendothelial system by pyran copolymer.     

Liposomal Anticancer Drugs as Agents to be used in Combination with other Anticancer Agents: Studies on a Liposomal Formulation with two Encapsulated Drugs

Abstract

When considering the use of combination therapies with liposomal anticancer agents several approaches can be defined. One approach could rely on administration of one liposomal formulation with more than one entrapped cytotoxic drug. This study focuses on an assessment of a liposomal formulation containing vincristine and mitoxantrone. Distearoyl phosphatidylcholine (DSPC)/Cholesterol (Choi) (55:45 molar ratio) liposomes were loaded with vincristine using transmembrane pH gradients. These systems were subsequently incubated with mitoxantrone to effect uptake of the second drug. Retention of both drugs was determined in vitro and in vivo. In vitro drug release indicated >95% retention of mitoxantrone and approximately 75% retention of vincristine when liposomes were prepared with an initial interior pH of 2.0. In vivo results however, demonstrated that greater than 80% of the encapsulated vincristine was released within 1 hour following i.v. administration. The instability of a liposomal formulation containing two anticancer drugs following i.v. administration may be a consequence of a combination of factors including drug-loading induced collapse of the transmembrane pH gradient, loss due to osmotic effects and an associated insertion of serum proteins into the bilayer, as well as the presence of a large biological “sink” which can alter the transbilayer drug gradient in favor of drug release.     

Encapsulation of Vincristine in Liposomes Reduces its Toxicity and Improves its Anti-Tumor Efficacy

Abstract

Vincristine is a potent therapeutic agent with activity against a variety of tumor types. It is a cell-cycle specific agent which has exhibited enhanced anti-tumor activity when delivered in liposomal form. Vincristine can be encapsulated into large unilamellar vesicles in response to a transmembrane pH gradient with trapping efficiencies approaching 100%. The extent of vincristine encapsulation, and the subsequent retention of the drug within the liposomes, both in vitro and in vivo, are strongly dependent on the lipid composition of the liposome and on the magnitude of the transmembrane pH gradient. Liposomal formulations of vincristine have been optimized for both liposome circulation longevity, drug retention characteristics and in vivo antitumor activity. When compared to free vincristine, these formulations significantly increase the levels of vincristine remaining in the plasma after i.v. administration. These formulations also significantly increase the delivery of vincristine to tumor sites. As a consequence of the improved accumulation of vincristine at tumor sites, liposomal formulations of vincristine exhibit dramatically improved efficacy against a variety of ascitic and solid murine and human tumors than does free vincristine. Liposomal vincristine is expected to be of wide utility in a variety of human malignancies.     

The Delivery of Benzyl Penicillin to Staphylococcus aureus Biofilms by Use of Liposomes

The delivery of benzyl penicillin [penicillin G (pen‐G)] encapsulated in cationic liposomes to a pen‐G‐sensitive strain of Staphylococcus aureus immobilized in biofilms has been investigated. The cationic liposomes prepared by extrusion (VETs, diameter ～ 140 nm) were composed of dipalmitoylphosphatidylcholine (DPPC), cholesterol, and dimethylammonium ethane carbamoyl cholesterol (DC‐chol) at a molar ratio of 1.0 :0.49 :0.43. This composition containing 22 mole% of the cationic lipid DC‐chol has been found previously (Kim et al. Colloids Surfaces A 1999, 149, 561–570) to be optimum for adsorption of the liposomes on S. aureus biofilms. The effectiveness of the liposomes to deliver pen‐G to the biofilms immobilized on microtitre plates was assessed from the rate of growth of the cells after exposure to the liposomal drug carrier relative to free pen‐G at the same concentration. The time to reach maximum growth rate from biofilms was investigated as a function of overall drug concentration in a range 2.9 × 10^{? 3} mM to 1.09 mM and as a function of time of exposure to liposomal drug in a range 1.5 s to 2 h. Liposomal drug delivery was most effective relative to free drug at low overall drug concentrations and short times of exposure. The time to reach maximum growth rate from S. aureus biofilms could be extended by a factor of approximately 4 relative to free drug by the use of liposomally encapsulated pen‐G. The results were supported by direct measurements of the distribution of pen‐G between biofilm and supernatant which showed enhanced values relative to free drug and a transient preferential uptake of drug induced by the liposomes. The study demonstrates that for low drug concentrations and short exposure times liposomal drug delivery greatly enhances the effectiveness of pen‐G for inhibiting the growth of bacterial biofilms of the potentially pathogenic bacterium Staphylococcus aureus.     

Preparation,Relative Toxicity,Chemotherapeutic Activity,and Pharmacokinetics of Liposomal SJA-95: A New Polyene Macrolide Antibiotic

The research work was designed to compare the relative toxicity, chemotherapeutic activity, and pharmacokinetic parameters of liposomal incorporated SJA-95 with that of free SJA-95, with an objective to reduce toxicity and improve therapeutic activity in vivo. Liposomal-incorporated SJA-95 (Lip SJA-95), prepared using the proliposome method, was found to exhibit a higher LD₅₀ value in mice, and the relative toxicity was about 2.5 times lower than that of the free drug. Lip SJA-95 treatment in experimental mice model of Candidiasis showed increased survival and reduced fungal loads in various organs. The pharmacokinetic profile of the free and liposomal drug was evaluated by administration of free and Lip SJA-95 intravenously to healthy albino rabbits in a crossover fashion. Lip SJA-95 showed an initial fall in plasma levels and longer half-life. The improved microbial clearance following treatment with Lip SJA-95 could be attributed partly to an increased tissue uptake, which was reflected in a marked increase in volume of distribution (V_d) and longer half-life (T_1/2). The present results clearly indicated that Lip SJA-95 treatment led to prolonged survival time, effective microbiological clearance, and reduced toxicity in the mice model of Candidiasis.     

The Use of Transmembrane pH Gradient-Driven Drug Encapsulation in the Pharmacodynamic Evaluation of Liposomal Doxorubicin

Abstract

The toxicity and efficacy properties of doxorubicin entrapped inside liposomes are sensitive to the physical characteristics of the vesicle carrier system. Studies addressing such relationships must use preparation procedures with the ability to independently vary vesicle size, lipid composition and drug to lipid ratio while maintaining high trapping efficiencies. The transmembrane pH gradient-driven encapsulation technique allows such liposomal doxorubicin formulations to be prepared. Pharmacokinetic, toxicology and antitumour studies with these systems have revealed several important relationships between liposome physical properties and biological activity. The acute toxicity of liposomal doxorubicin is related primarily to the ability of the liposomes to retain doxorubicin after administration. Including cholesterol and increasing the degree of acyl chain saturation of the phospholipid component in the liposomes significantly decreases drug leakage in the blood, reduces cardiac tissue accumulation of doxorubicin and results in increased LD₅₀ values. In contrast, the efficacy of liposomal doxorubicin is most influenced by liposome size. Specifically, liposomes with a diameter of approximately 100 nm or less exhibit enhanced circulation lifetimes and antitumour activity. While these relationships appear to be rather straightforward, there exist anomalies which suggest that a more thorough evaluation of liposomal doxorubicin pharmacokinetics may be required in order to fully understand its mechanism of action. A key feature in this regard is the ability to differentiate between non-encapsulated and liposome encapsulated doxorubicin pools in the circulation as well as in tumours and normal tissues. This represents a major challenge that must be addressed if significant advances in the design of more effective liposomal doxorubicin formulations are to be achieved.     

In vitro response of encapsulated and non-encapsulated somatic embryos of Kinnow mandarin (Citrus nobilis Lour × C. deliciosa Tenora)

The aim of present investigation was to study the effect of storage conditions on percentage germination of encapsulated and non-encapsulated somatic embryos of Kinnow mandarin (Citrus nobilis Lour × C. deliciosa Tenora). Different batches of encapsulated and non-encapsulated embryos were preserved at room temperature, 4°C, in liquid nitrogen as such and by embedding in liquid paraffin. In the encapsulated somatic embryos stored at room temperature in sealed Petri plates, percentage of germination was 24.99%, but 5.55% in non-encapsulated embryos after 3 days of storage. Encapsulated embryos stored in vials containing liquid paraffin at room temperature were germinated at 18.05% after 60 days of storage, while it was 13.88% in non-encapsulated embryos after 45 days of storage. Encapsulated somatic embryos stored at 4°C in sealed Petri plates remained viable for up to 75 days with 6.94% germination, whereas non-encapsulated embryos remained viable for up to 45 days with 24.99% germination. Encapsulated embryos stored at 4°C in vials filled with paraffin germinated at 11.11% after 120 days of storage, but 5.55% in non-encapsulated embryos after 90 days of storage. Encapsulated and non-encapsulated embryos stored in liquid nitrogen showed 58.33 and 51.38% survival, respectively, after 7 months of storage. The plantlets developed from these embryos were transplanted after acclimatization and are growing normal.     

Relationship of Glycogen Synthase and Glycogen Phosphorylase to Protein Phosphatase 2C and cAMP-Dependent Protein Kinase in Liver of Obese Rhesus Monkeys

ORTMEYER HK. Relationship of glycogen synthase and glycogen phosphorylase to protein phosphatase 2C and cAMP-dependent protein kinase in liver of obese rhesus monkeys. The regulation of glycogen synthase (GS) and glycogen phosphorylase (GP) activity by phosphorylation/ dephosphorylation has been proposed to be via changes in activities of several different protein (serine/ threonine) phosphatases and kinases, including protein phosphatase (PP) 1/2A, PP2C, and cAMP-dependent protein kinase (PKA). In order to determine whether PP1/2A, PP2C, and/or PKA activities are related to GS and/or GP activities, these enzymes were measured in freeze-clamped liver biopsies obtained under basal fasting conditions from 16 obese monkeys. Four monkeys were normoglycemic and normoinsulinemic, five were hyperinsulinemic, and seven had type 2 diabetes (NIDDM). Liver glycogen and glucose 6-phosphate (G6P) contents were also determined. Basal enzyme activities and basal substrate concentrations were not significantly different between the three groups of obese monkeys; however, there were several significant linear relationships observed when the monkeys were treated as one group. Therefore, multiple regression was used to determine the correlation between key variables. GS fractional activity was correlated to GP fractional activity (p<0. 05) and to PP2C activity (p=0. 005) (adjusted R²,53%). GP independent activity was correlated to GS independent activity (p<0. 07) and to PKA fractional activity (p=0. 005) (adjusted R²,64%). PP2C activity was correlated to GS fractional activity (p<0. 0005) and to PP1/2A activity G7<0. 0001) (adjusted R²,83%). PKA fractional activity was correlated to GP total activity (p<0. 0005) and to age (p=0. 001) (adjusted R282%). G6P content was correlated to glycogen content (p<0. 05) and to PP2C activity (p=0. 0005) (adjusted R²,73%). In conclusion, PP2C and PKA are involved in the regulation of GS and GP activity in the basal state in liver of obese monkeys with a wide range of glucose tolerance.     

A Novel PEGylated Liposome-Encapsulated SANT75 Suppresses Tumor Growth through Inhibiting Hedgehog Signaling Pathway

The Hedgehog (Hh) pathway inhibitors have shown great promise in cancer therapeutics. SANT75, a novel compound we previously designed to specially inhibit the Smoothened (SMO) protein in the Hh pathway, has greater inhibitory potency than many of commonly used Hh inhibitors. However, preclinical studies of SANT75 revealed water insolubility and acute toxicity. To overcome these limitations, we developed a liposomal formulation of SANT75 and investigated its antitumor efficacy in vitro and in vivo. We encapsulated SANT75 into PEGylated liposome and the mean particle size distribution and zeta-potential (ZP) of liposomes were optimized. Using the Shh-light2 cell and Gli-GFP or Flk-GFP transgenic reporter zebrafish, we confirmed that liposome-encapsulated SANT75 inhibited Hh activity with similar potency as the original SANT75. SANT75 encapsulated into liposome exerted strong tumor growth-inhibiting effects in vitro and in vivo. In addition, the liposomal SANT75 therapy efficiently improved the survival time of tumor-bearing mice without obvious systemic toxicity. The pathological morphology and immunohistochemistry staining revealed that liposomal SANT75 induced tumor cell apoptosis, inhibited tumor angiogenesis as assessed by CD31 and down-regulated the expression of Hh target protein Gli-1 in tumor tissues. Our findings suggest that liposomal formulated SANT75 has improved solubility and bioavailability and should be further developed as a drug candidate for treating tumors with abnormally high Hh activity.     

Effect of Macrophage Elimination Using Liposome-Encapsulated Dichloromethylene Diphosphonate on Tissue Distribution of Liposomes

Abstract

Effect of macrophage elimination using liposomal dichloromethylene diphosphonate (C1₂MDP)1 on tissue distribution of different types of liposomes was examined in mice. Intravenously administration into mice with CI2MDP encapsulated in liposomes composed of phosphatidylcholine, cholesterol and phosphatidylserine exhibits a temporary blockade of liver and spleen function for liposome uptake. At a low dose of 90 (ig/mouse, the liposome uptake by the liver was significantly decreased. Such decrease was accompanied by an increase in liposome accumulation in either spleen or blood depending on liposome composition and size. Direct correlation between the administration dose of liposomal CI2MDP and the liposome circulation time in blood was also obtained even for liposomes with an average diameter of more than 500 nm. These results indicate that temporary elimination of macrophages of the liver and spleen using liposomal CI2MDP may prove to be useful to enhance the drug delivery efficiency of liposomes.     

Physicochemical characterization of stealth liposomes encapsulating an organophosphate hydrolyzing enzyme

The present studies were focused on the preparation and characterization of stericaly stabilized liposomes (SLs) encapsulating a recombinant organophosphorus hydrolyzing phosphotriesterase (OPH) enzyme for the antagonism of organophosphorus intoxication. Earlier results indicate that the liposomal carrier system provides an enhanced protective effect against the organophosphorus molecule paraoxon, presenting a more effective therapy with less toxicity than the most commonly used antidotes. Physicochemical characterization of the liposomal OPH delivery system is essential in order to get information on its in vitro stability and in vivo fate. Osmolarity, pH, viscosity, and encapsulation efficiency of the SL preparation and the surface potential of the vesicles were determined. The membrane rigidity and the impact of OPH enzyme on it was studied by electron-paramagnetic resonance spectroscopy, using spin probes. The in vitro stability of the liposomal preparations, the vesicle size distribution, and its alteration during a 3-week storage were followed by dynamic light-scattering measurements. Further, the stability of encapsulated and nonencapsulated OPH was compared in puffer and plasma.     

Method for evaluating metabolic functions of drugs in bioartificial liver

Lidocaine and galactose loading tests were performed on a bioartificial liver (BAL), an extracorporeal medical device incorporating living hepatocytes in a cartridge without a transport barrier across the membranes. The concentration changes were analyzed using pharmacokinetic equations to evaluate the efficacy and limitation of the proposed method. Lidocaine and galactose were found to be suitable drugs for a quantitative evaluation of the BAL functions, as they did not interact with the plasma proteins or blood vessels, making their concentrations easy to determine. The drug concentration changes after drug loading were easily analyzed using pharmacokinetic equations, and the BAL functions quantitatively expressed by pharmacokinetic parameters, such as the clearance (CL) and galactose elimination capacity (GEC). In addition, these two drugs have already been used in clinical tests to evaluate human liver functions over long periods, and lidocaineCL values andGEC values reported for a normal human liver. Thus, a comparison of theCL andGEC values for theBAL and a natural liver revealed what proportion of normal liver functions could be replaced by the BAL.     

Design and characterization of multifaceted lyophilized liposomal wafers with promising wound healing potential

Various dressings are available to heal chronic wounds which many times fail to achieve the expected results. To overcome some of their drawbacks, formulation of a novel dressing; lyophilized liposomal wafers having better wound healing potential has been proposed in the present study. The drug incorporated in the formulation is gatifloxacin (GTX) which is a fourth-generation fluoroquinolone antibiotic having in vitro activity against both Gram-negative and Gram-positive bacteria. The formulation was designed in three stages where at first liposomes were prepared, the liposomes were converted to gel using chitosan and lastly this gel was lyophilized to form liposomal wafers. Liposomes were prepared by varying the concentration of lipid and cholesterol and evaluated for particle size, entrapment efficiency, in vitro cumulative release, transmission electron microscopy (TEM) and scanning electron microscopy (SEM). Liposomes were converted to liposomal gel using chitosan and evaluated for texture, clarity, viscosity, spreadibility and in vitro drug release. Finally, this liposomal batch was subjected to lyophilization to convert it to liposomal wafers and subjected to SEM, differential scanning calorimetric, X-ray diffraction and drug release studies. The in vivo studies were carried out on Wistar rats where wound healing potential of the wafers was confirmed by histopathological evaluation.     

Enhancement of Bioavailability of Cefpodoxime Proxetil Using Different Polymeric Microparticles

Poorly water-soluble drugs such as cefpodoxime proxetil (400 μg/ml) offer a challenging problem in drug formulation as poor solubility is generally associated with poor dissolution characteristics and thus poor oral bioavailability. According to these characteristics, preparation of cefpodoxime proxetil microparticle has been achieved using high-speed homogenization. Polymers (methylcellulose, sodium alginate, and chitosan) were precipitated on the surface of cefpodoxime proxetil using sodium citrate and calcium chloride as salting-out agents. The pure drug and the prepared microparticles with different concentrations of polymer (0.05–1.0%) were characterized in terms of solubility, drug content, particle size, thermal behavior (differential scanning calorimeter), surface morphology (scanning electron microscopy), in vitro drug release, and stability studies. The in vivo performance was assessed by pharmacokinetic study. The dissolution studies demonstrate a marked increase in the dissolution rate in comparison with pure drug. The considerable improvement in the dissolution rate of cefpodoxime proxetil from optimized microparticle was attributed to the wetting effect of polymers, altered surface morphology, and micronization of drug particles. The optimized microparticles exhibited excellent stability on storage at accelerated condition. The in vivo studies revealed that the optimized formulations provided improved pharmacokinetic parameter in rats as compared with pure drug. The particle size of drug was drastically reduced during formulation process of microparticles.     

Cytochrome P450 Enzymes and Drug Metabolism—Basic Concepts and Methods of Assessment

1. The cytochrome P450 enzyme family is one of the major drug metabolizing systems in man.2. Factors such as age, gender, race, environment, and drug treatment may have considerable influence on the activity of these enzymes.3. There are now well-established in vitro techniques for assessing the role of specific cytochrome P450 enzymes in the metabolism of drugs, as well as the inhibitory or inducing effects of drugs on enzyme activity. In vitro data have been utilized to predict clinical outcomes (i.e., pharmacokinetic interactions), with close correlations between in vitro and in vivo data.4. This information can be of considerable practical assistance to clinicians, to help with rational prescribing or to prevent or minimize the potential for drug interactions.     

综述——新型纳米生物材料的研发：聚乙二醇化磷脂胶束的纳米结构与功能

梁伟等采用一步自组装法制备粒径在20 nm左右、具有核-壳结构的聚乙二醇化磷脂(PEG-PE)胶束,药物装载后对胶束的粒径无明显影响,但显著提高了胶束的体内外稳定性,被装载的药物主要分布在胶束的核-壳界面处．研究表明药物的理化性质决定了其与载体之间的组装机制及体外药物释放的特性．在不影响细胞膜的完整性及通透性的情况下,PEG-PE胶束通过插膜提高了细胞膜的流动性,进而促进小分子药物的翻转过膜,增加药物的入胞量．与游离药物相比,装载化疗药的胶束可增强药物对肿瘤组织的渗透能力,显著抑制动物皮下移植瘤的生长,延长动物的生存时间．PEG-PE胶束还通过增加药物在淋巴组织中的分布,降低了动物转移模型中的淋巴转移,相应地减少了肿瘤的肺部转移．PEG-PE为美国食品药品管理局(FDA)批准的可用于人体的药物载体材料,具有良好的生物相容性与安全性．因此,PEG-PE胶束作为药物载体具有广阔的发展前景．     

Quercetin-containing self-assemble proliposome preparation and evaluation

The purpose of this study was to develop a liquid self-assemble proliposome for quercetin oral delivery. This liquid proliposome was prepared by dissolving phospholipids, surfactants and drug in ethanol. There was only one step in the preparation process of this liquid self-assemble proliposome and no special devices were required. The mechanism about proliposome transformation was discussed. Quercetin proliposomes with different cremorphor RH40 concentrations (0%, 20%, 23%, 26%, 30%) were prepared. The particle size and polydispersity index decreased as cremorphor RH40 concentration increased. Meantime, the drug entrapped efficiency decreased slightly with an increase in cremorphor RH40 concentration. The in vitro drug release showed prolonged drug release in case of proliposome and the release of quercetin was slower when cremorphor RH40 concentration was higher. The absorption of quercetin and its in vivo bioavailability were significantly improved by proliposome, which was evidenced by the in situ intestinal absorption and pharmacokinetic study. Besides, the obtained quercetin proliposome was with good stability when stored at room temperature. In conclusion, quercetin liquid self-assemble proliposome was successfully prepared. It could transform into liposomal vesicle with satisfied particle size and polydispersity index instantly when cremorphor RH40 was added. Cremorphor RH40 concentration in the formulation should below 26% to get higher drug entrapped efficiency (>90%) and less irritation. The drug release was affected by the cremorphor RH40 concentration and the required drug release could be obtained by adjusting cremorphor RH40 content. The enhanced bioavailability showed liquid self-assemble proliposome could be a promising vehicle for the oral delivery of quercetin.