Estudo da encapsulação de fármacos antineoplásicos em sistemas nanoestruturados: Caracterização estrutural e efeito sinérgico de fármacos / Study of the encapsulation of antineoplastic drugs in nanostructured systems: Structured characterization and synergistic effect of drugs

Dentro da área da nanotecnologia, o sistema drug delivery vem sendo amplamente utilizado, cujo objetivo é proporcionar uma maior eficácia dos ativos farmacêuticos, podendo envolver desde uma distribuição mais seletiva dentro do organismo até a taxa que as moléculas serão liberadas e/ou a atenuação dos efeitos adversos provocados. Para isso, os ativos são encapsulados em nanoestruturas, podendo estas serem de natureza sintética ou natural. Dentre os nanocarreadores promissores encontram-se os cubossomos, que são nanoestruturas complexas capazes de encapsular ativos tanto hidrofílicos quanto hidrofóbicos. O objetivo deste projeto foi estudar a encapsulação de fármacos antineoplásicos em sistemas drug delivery contra linhagens celulares, investigando também as alterações estruturais sofridas pelos cubossomos e os efeitos sinérgicos dos fármacos, sendo eles: a doxorrubicina, a cisplatina, a vemurafenibe e a curcumina. As metodologias empregadas para elucidar o efeito das combinações dos fármacos, a estruturação da nanopartícula e sua citotoxicidade foram: os estudos de viabilidade celular pós-exposição, espalhamento dinâmico de luz, potencial zeta, análise de rastreamento de nanopartículas, espalhamento de raios-x a baixos ângulos, criomicroscopia eletrônica de transmissão, eficiência de encapsulação e ensaio de liberação. Inicialmente os fármacos foram testados isoladamente e em duplas, sendo utilizadas cinco linhagens celulares, afim de se promover um delineamento aos ensaios futuros. A partir destes resultados, foi-se optado por manter duas linhagens celulares, a HeLa, como representante de tecidos tumorais, e a HaCat, modelo de tecido saudável, devido a menor resistência apresentada por elas. Em relação as combinações entre as drogas, pode-se observar que todas as duplas formadas apresentaram resultados sinérgicos na linhagem tumoral, sendo mantida para os testes seguintes a combinação curcumina e vemurafenibe. Os cubossomos foram sintetizados eficientemente, sendo produzidos na ausência de fármacos bem como contendo curcumina e vemurafenibe. As nanopartículas apresentaram uma variação de diâmetro entre 189 ± 3 nm e 224 ± 2 nm, sendo o PDI entre 0,08 e 0,25. A conformação do cubossomo foi confirmada através da criomicroscopia eletrônica de transmissão e pelo espalhamento de raios-x a baixos ângulos, onde foi determinada uma estruturação característica de Pn3m. Para a eficiência de encapsulação os valores variaram entre 79% de encapsulação para a curcumina e 72% para a vemurafenibe, quando utilizadas isoladamente. No caso da encapsulação em dupla, os valores se converteram para 63% e 53% para a curcumina e vemurafenibe, respectivamente. A liberação das drogas do interior da nanopartícula oscilou entre 1500, 480 e 420 minutos para os cubossomos de curcumina, vemurafenibe e curcumina + vemunafenibe, respectivamente. Os testes de citotoxicidade demonstraram que as concentrações de 0,01 e 0,03 mg/mL foram capazes de promover uma viabilidade acima de 70%, porém, utilizando estas proporções não foi possível observar resultados significativos. Por fim, o sistema se mostrou estável e homogêneo, sendo capaz de promover a encapsulação dos fármacos tanto singularmente quanto em dupla e, apesar da quantidade de fármacos não ter sido suficiente para ocasionar alterações ao sistema celular, a execução deste trabalho abre portas para que novos estudos sejam realizados, podendo-se testar diferentes ativos bem como alterando a composição da nanopartícula afim de se reduzir a citotoxicidade

Within the area of nanotechnology, the drug delivery system has been widely used, whose objective is to provide greater effectiveness of pharmaceutical active ingredients, which may range from a more selective distribution within the organism to the rate at which the molecules will be released and/or the attenuation of adverse effects caused. To achieve this, the active ingredients are encapsulated in nanostructures, which may be synthetic or natural in nature. Among the promising nanocarriers are cubosomes, which are complex nanostructures capable of encapsulating both hydrophilic and hydrophobic active ingredients. The objective of this project was to study the encapsulation of antineoplastic drugs in drug delivery systems against cell lines, also investigating the structural changes undergone by the cubosomes and the synergistic effects ofthe drugs, namely: doxorubicin, cisplatin, vemurafenib and curcumin. The methodologies used to elucidate the effect of drug combinations, the structuring of the nanoparticle and its cytotoxicity were: post-exposure cell viability studies, dynamic light scattering, zeta potential, nanoparticle tracking analysis, small angle x-rays scattering, transmission electron cryomicroscopy, encapsulation efficiency and release assay. Initially, the drugs were tested alone and in pairs, using five cell lines, in order to promote a design for future trials. Based on these results, it was decided to maintain two cell lines, HeLa, as a representative oftumor tissues, and HaCat, a model ofhealthy tissue, due to their lower resistance. Regarding the combinations between the drugs, it can be observed that all the pairs formed presented synergistic results in the tumor lineage, with the combination of curcumin and vemurafenib being maintained for the following tests. Cubosomes were efficiently synthesized, being produced in the absence of drugs as well as containing curcumin and vemurafenib. The nanoparticles varied in diameter between 189 ± 3 nm and 224 ± 2 nm, with the PDI being between 0.08 and 0.25. The conformation ofthe cubosome was confirmed through transmission electron cryomicroscopy and small angle x-rays scattering, where a characteristic structure of Pn3m was determined. For encapsulation efficiency, values varied between 79% encapsulation for curcumin and 72% for vemurafenib, when used alone. ln the case of double encapsulation, the values converted to 63% and 53% for curcumin and vemurafenib, respectively. The release of drugs from the interior of the nanoparticle ranged between 1500, 480 and 420 minutes for the curcumin, vemurafenib and cubosomes with curcumin + vemunafenib, respectively. Cytotoxicity tests demonstrated that concentrations of 0.01 and 0.03 mg/mL were capable of promoting viability above 70%, however, using these proportions it was not possible to observe significant results. Finally, the system proved to be stable and homogeneous, being able to promote the encapsulation of drugs both singly and in pairs and, although the quantity of drugs was not enough to cause changes to the cellular system, the execution of this work opens doors for new studies are carried out, with the possibility oftesting different active ingredients as well as changing the composition of the nanoparticle in order to reduce cytotoxicity

Caracterização de cubossomos não-iônicos em presença de proteínas modelo: uma abordagem estrutural e funcional / Characterization of non-ionic cubosomes in the presence of model pro­teins: a structural and functional approach

Uma área de pesquisa que vem ganhando muita atenção nos últimos anos é a nanome­dicina, com especial atenção para os sistemas com entrega controlada de fármacos, ou drug delivery. Dentre as diversas nanopartículas utilizadas para este fim, destacam-se os sistemas formados por lipídeos e polímeros, como por exemplo os lipossomos e os cubossomos. Neste trabalho, é estudada a influência estrutural da lisozima e da curcumina, proteínas modelo. A lisozima é uma enzima antimicrobiana produzida por animais e que faz parte do sistema imunológico. Ela é uma hidrolase glicosídica que catalisa a hidrólise dos componentes da parede celular de bactérias gram-positivas. Esta hidrólise, por sua vez, compromete a integridade das paredes celulares, causando a lise (e como consequência a morte) das bactérias. Curcumina é um composto cristalino de cor amarelada brilhante, encontrada no caule da Curcuma longa (ou açafrão), que tem sido utilizada como corante ou até mesmo como aditivo alimentar. Este composto tem sido uma grande aposta no tratamento de doenças crônicas como inflamação, artrite, síndrome metabólica, doença hepática, obesidade, doenças neurodegenerativas e principalmente canceres, sendo também utilizada em estudos como potencial agente antibacteriano. O principal objetivo deste trabalho é construir sistemas nanoestruturados com potencial de atuarem como sistemas antimicrobianos, com a liberação controlada de ambos dos fármacos. Estes sistemas são compostos por cubossomos de fitantriol (PHY) em ausência e presença da lisozima, da curcumina e de suas combinações, a fim de analisar ação antimicrobiana conjunta da lisozima e da curcumina. As técnicas biofísicas utilizadas para caracterizar essas partículas são SAXS (espalhamento de raios-X em baixos ângulos), DLS (espalhamento dinâmico de luz), Cryo-TEM (criomicroscopia eletrônica de transmissão) e NTA (análise de rastreamento de nanopartículas). Foi possível verificar que as formulações lipídicas são eficazes na formação de estruturas cúbicas com estabilidade desejável. As nanopartículas cúbicas demonstraram alta capacidade de encapsulação da lisozima e da curcumina. A cinética de liberação desses medicamentos mostrou-se promissora, sugerindo que a encapsulação dos fármacos é eficaz, bem como a liberação controlada e direcionada. Duas linhagens de bactérias foram estudadas, sendo que a E. coli, não sofreu nenhum dano citotóxico, enquanto a Bacillus subtilis sim. Tal resultado indica o potencial antimicrobiano do sistema para alguns tipos de bactérias

An area of research that has gained significant attention in recent years is nanomedicine, with a particular focus on drug delivery systems. Among the various nanoparticles used for this purpose, lipid and polymer-based systems, such as liposomes and cubosomes stand out. This study investigate the structural influence of encapsulating lysozyme and curcumin, model compounds. Lysozyme is an antimicrobial enzyme produced by animals and is part of the immune system. It is a glycosidic hydrolase that catalyzes the hydrolysis of components in the cell walls of gram-positive bacteria. This hydrolysis compromises the integrity of cell walls, leading to the lysis (and consequently the death) of bacteria. Curcumin is a bright yellow crystalline compound found in the stem of Curcuma longa (or turmeric), commonly used as a dye or even as a food additive. It has been a significant focus in the treatment of chronic diseases such as inflammation, arthritis, metabolic syndrome, liver disease, obesity, neurodegenerative diseases, and especially cancers. It is also studied as a potential antibacterial agent. The main objective of this study is to construct nanostructured systems with the potential to act as antimicrobial agents, with controlled release of both drugs. These systems consist of phytantriol (PHY) cubosomes in the absence and presence of lysozyme, curcumin, and their combinations to analyze the joint antimicrobial action of lysozyme and curcumin. Biophysical techniques used for characterization include Small-Angle X-ray Scattering (SAXS), Dynamic Light Scattering (DLS), Cryo-Transmission Electron Microscopy (Cryo-TEM), and Nanoparticle Tracking Analysis (NTA). It was observed that lipid formulations are effective in forming cubic structures with desirable stability. Cubic nanoparticles have demonstrated a high encapsulation capacity for lysozyme and curcumin. The release kinetics of these drugs have shown promise, suggesting that drug encapsulation is effective, as well as their controlled and targeted release. Two bacterial strains were studied, with E. coli showing no cytotoxic damage, while Bacillus subtilis did. This result indicates the antimicrobial potential of the system against types of bacteria

Preparation of propranolol hydrochloride cubosomes by pH gradient method / 药学实践杂志

Objective To prepare propranolol hydrochloride loaded cubosomes (PPL-Cubs) with high entrapment efficiency. Methods PPL-Cubs was prepared by pH gradient method. Pressure and cycles of high pressure homogenization, dosage of glyceryl monooleate and poloxamer 407 were optimized to prepare blank cubosomes with particle size and polydispersity index as the indexes. The influences of various factors, including exterior pH values, internal pH values, the ratio of carrier to drug, particle size and polydispersity index of blank cubosomes, incubation temperature and time, and drug concentration on the entrapment efficiency were investigated. Results The blank cubosomes with small particle size and polydispersity index was prepared under homogenization conditions of 900 bar for 7 cycles, glyceryl monooleate dosage of 25%, and poloxamer 407 dosage of 5%. PPL-Cubs showed high entrapment efficiency with exterior pH value of 8.5, internal pH value of 3.0, ratio of carrier to drug of 6∶1, incubation temperature of 20 ℃, and incubation time of 15 min, and drug concentration of 1%. The particle size and polydispersity index of blank cubosomes showed no influence on entrapment efficiency. Conclusion PPL-Cubs with high entrapment efficiency could be prepared under the pH gradient method.

Recent advances in drug delivery applications of cubosomes, hexosomes, and solid lipid nanoparticles

The use of lipid nanocarriers for drug delivery applications is an active research area, and a great interest has particularly been shown in the past two decades. Among different lipid nanocarriers,

Estudo da eficácia de encapsulação da Cinarizina em cubossomos não-iônicos: caracterização estrutural e citotóxica / Study of the encapsulation efficacy of Cinnarizine in non-ionic cubosomes: structural and cytotoxic characterization

Os cubossomos são partículas nanoestruturadas em forma de bicamada lipídica, bicontínuas e altamente curvadas, as quais devem ser estabilizadas por um polímero não-iônico, neste caso o Pluronic® F-127. Podem ser compostos por alguns tipos de lipídios específicos que possuem a capacidade de se auto associar em estruturas cúbicas quando estão em excesso de água, como o fitantriol (PHY) e a monoleína (GMO). Devido a sua estrutura única, cubossomos possuem um grande potencial para serem considerados como sistemas drug delivery. Os sistemas drug delivery são amplamente utilizados na pesquisa farmacêutica e em contextos clínicos para aumentar a eficácia de compostos utilizados para diagnóstico e de fármacos. No caso da cinarizina (CNZ), fármaco já aprovado para o tratamento de náuseas, vômitos e vertigens causadas pela doença de Ménière, existem inúmeros efeitos colaterais associados a sua baixa solubilidade. Desta forma, a encapsulação em cubossomos se torna uma abordagem promissora para resolver os problemas de atividade farmacológica relacionados ao fármaco. Neste trabalho, realizamos uma caracterização biofísica da interação da CNZ em cubossomos (contendo PHY ou myverol, MYV, sendo este composto por 80% de GMO). As técnicas biofísicas utilizadas foram: espalhamento de raios-X em baixos ângulos (SAXS), espalhamento dinâmico de luz (DLS), microscopia eletrônica de transmissão (TEM), crio microscopia eletrônica de transmissão (Crio-TEM), análise de rastreamento de nanopartículas (NTA) e potencial zeta. A cromatografia líquida de alta eficiência (HPLC) foi realizada para verificar a porcentagem de eficiência de encapsulação (%EE) da CNZ nos cubossomos, enquanto que a citotoxicidade foi avaliada em eritrócitos através da análise da atividade hemolítica. Inicialmente, a influência de diferentes solventes (acetona, clorofórmio, etanol e octano) nas propriedades estruturais de cubossomos de PHY foi investigada, a fim de se minimizar os efeitos do solvente utilizados para a encapsulação da CNZ. Para amostras com acetona, descobriu-se que apenas altas concentrações tiveram influência na estrutura cristalográfica das nanopartículas, sendo o resultado foi totalmente reversível após 24h. O etanol fez com que o parâmetro de rede aumentasse de 10-15%. O clorofórmio e o octano tiveram efeitos diferentes sobre cubossomos de PHY em comparação com a acetona e o etanol; ambos induziram uma transição cúbico-hexagonal-micelar. Posteriormente, constatamos que as nanopartículas de PHY e MYV apresentaram diferentes estruturas cristalográficas, sendo elas Pn3m e Im3m, respectivamente. Devido a problemas com a baixa solubilidade de CNZ em PHY os estudos para esse lipídio foram suspensos. Nos testes para cubossomos de MYV ao incorporar a CNZ foi observado uma alteração da estrutura cúbica de Im3m para Pn3m e os valores dos parâmetros de rede se alteraram de acordo com a estrutura cristalina encontrada, porém os valores não apresentaram diferenças significativas de tamanho quando se trata da mesma estrutura, sugerindo que a CNZ não interferiu no parâmetro de rede. Os tamanhos das nanopartículas apresentaram uma população monodispersa com ~200 nm. DLS mostrou uma interferência da CNZ no tamanho dos cubossomos, variando de forma diretamente proporcional a concentração de CNZ na amostra, enquanto as técnicas de NTA e microscopia apresentaram nanopartículas de tamanhos bastante variados, mas independente da interferência da CNZ. A encapsulação de CNZ também foi dosada por HLPC em cubossomos de MYV, obtendo um limite superior de 0,6 mg/mL. A atividade citotóxica dos cubossomos foi testada em eritrócitos, revelando uma taxa de hemólise bastante inferior em cubossomos com CNZ em relação a cubossomos puros. Acreditamos que os cubossomos podem sim ser utilizados como sistemas carreadores de CNZ

Cubosomes are nanostructured particles in the form of a lipid bilayer, bicontinuous and highly curved, which must be stabilized by a non-ionic polymer, in this case Pluronic® F-127. They can be composed of some types of specific lipids that have the ability to self-associate in cubic structures when they are in excess of water, such as phytantriol (PHY) and monolein (GMO). Due to their unique structure, cubosomes have a great potential to be considered as drug delivery systems. Drug delivery systems are widely used in pharmaceutical research and clinical settings to increase the efficacy of compounds used for diagnostics and drugs. In the case of cinnarizine (CNZ), a drug already approved for the treatment of nausea, vomiting and vertigo caused by Ménière's disease, there are numerous side effects associated with its low solubility. Thus, cubosomal encapsulation becomes a promising approach to solve drug-related problems of pharmacological activity. In this work, we performed a biophysical characterization of the CNZ interaction in cubosomes (containing PHY or myverol, MYV, which is composed of 80% GMO). The biophysical techniques used were: low angle X-ray scattering (SAXS), dynamic light scattering (DLS), transmission electron microscopy (TEM), cryo transmission electron microscopy (Crio-TEM), nanoparticle tracking analysis (NTA) and zeta potential. High performance liquid chromatography (HPLC) was performed to verify the percentage of encapsulation efficiency (%EE) of CNZ in cubosomes, while cytotoxicity was evaluated in erythrocytes by analyzing the hemolytic activity. Initially, the influence of different solvents (acetone, chloroform, ethanol and octane) on the structural properties of PHY cubosomes was investigated in order to minimize the effects of the solvent used for the encapsulation of CNZ. For samples with acetone, it was found that only high concentrations had an influence on the crystallographic structure of the nanoparticles, with the result being fully reversible after 24h. Ethanol caused the network parameter to increase by 10-15%. Chloroform and octane had different effects on PHY cubosomes compared to acetone and ethanol; both induced a cubic-hexagonal-micellar transition. Later, we found that PHY and MYV nanoparticles presented different crystallographic structures, being Pn3m and Im3m, respectively. Due to problems with the low solubility of CNZ in PHY, studies for this lipid were suspended. In the tests for MYV cubosomes when incorporating CNZ, a change in the cubic structure from Im3m to Pn3m was observed and t he lattice parameters changed according to the crystal structure found, but the differences observed were not significant when it comes to the same structure, suggesting that the CNZ did not interfere with the network parameter. The nanoparticle sizes showed a monodisperse population with ~200 nm. DLS showed an interference of CNZ in the size of the cubosomes, varying directly proportionally to the concentration of CNZ in the sample, while NTA and microscopy techniques showed nanoparticles of widely varying sizes, but independent of CNZ interference. CNZ encapsulation was also dosed by HLPC in MYV cubosomes, obtaining an upper limit of 0.6 mg/ml. The cytotoxic activity of cubosomes was tested in erythrocytes, revealing a much lower rate of hemolysis in cubosomes with CNZ compared to pure cubosomes. We believe that cubosomes can indeed be used as CNZ carrier systems

Formulation and characterization of Liquid Crystalline Hydrogel of Agomelatin: In vitro and Ex vivo evaluation.

Objective: The aim of this investigation was the development and characterization of Agomelatin-loaded liquid crystalline (AM-LC) nanoparticles for improved topical application. Methods: AM-LC was formulated with the glyceryl monooleate (GMO) and poloxamer 407 as structure forming agent (lipid) and surfactant respectively, by using emulsification of GMO and poloxamer in water using a hydrotrope (Cubosomes) formation method. The obtained dispersion was characterized for particle size, PDI, zeta potential, entrapment efficiency, surface morphology, in vitro studies. Further, conversion optimised formulation in to cubic gel by incorporating 0.5% w/w of carbopol 934P. The prepared gel was characterized by rheological measurements, surface pH and ex vivo permeation studies through the rat skin. Results: The average particle size of formulations was ranging from 187.6±3.97nm to 225.8±7.54nm and ZP from -14.5±4.65 to -23.5±3.86mV. In vitro drug release from cubosomes exhibited sustained release profile and the optimized formulation (F2) showed cumulative drug release of 83.96±2.43% during 24h. Transmission electron microscopic photographs confirmed that the formed liquid crystalline nanoparticles were cubic in shape. Results suggested that cubic gel exhibited a retarded release rate (53.5 ± 3.21%) than the control gel (95.33 ± 2.28%) containing 0.1% drug solution. Conclusion: The obtained results indicated that cubic gel would be a promising carrier for topical delivery of agomelatin into and across the skin.

In vitro and in vivo evaluation of cubosomes containing 5-fluorouracil for liver targeting

The objective of this study was to prepare cubosomal nanoparticles containing a hydrophilic anticancer drug 5-fluorouracil (5-FU) for liver targeting. Cubosomal dispersions were prepared by disrupting a cubic gel phase of monoolein and water in the presence of Poloxamer 407 as a stabilizer. Cubosomes loaded with 5-FU were characterized in vitro and in vivo. In vitro, 5-FU-loaded cubosomes entrapped 31.21% drug and revealed nanometer-sized particles with a narrow particle size distribution. In vitro 5-FU release from cubosomes exhibited a phase of rapid release of about half of the entrapped drug during the first hour, followed by a relatively slower drug release as compared to 5-FU solution. In vivo biodistribution experiments indicated that the cubosomal formulation significantly (P<0.05) increased 5-FU liver concentration, a value approximately 5-fold greater than that observed with a 5-FU solution. However, serum serological results and histopathological findings revealed greater hepatocellular damage in rats treated with cubosomal formulation. These results demonstrate the successful development of cubosomal nanoparticles containing 5-FU for liver targeting. However, further studies are required to evaluate hepatotoxicity and in vivo antitumor activity of lower doses of 5-FU cubosomal formulation in treatment of liver cancer.

Cubosome: A novel approach for nanotechnology.

Cubosome dispersions are thermodinamically stable, bioadhesive and biocompatible.Because of their properties, cubosome are versatile systems, administrable by different ways such as orally, percutaneously and parenterally. The discovery of cubosomes is a unique story and spans the fields of food science, differential geometry, biological membranes, and digestive processes. Despite the early realization of their potential, the manufacture of cubosomes on a large scale embodied difficulty because of their complex phase behaviour and viscous properties. Contributions to cubosome research have come from the fields of biology, material science, medicine, and mathematics and much is known about their formation and properties. At the center of much of the discovery and innovation is the technique of cryo-transmission electron microscopy. Another cubosome advantage is related to the simple production procedure and the chemico-physical stability. With respect to liposome, cubosome possesses a larger ratio between the bilayer area and the particle volume and a larger breaking resistance. Cubosome structure by means of electron microscopy, “light scattering”, x-ray and “NMR”, nevertheless few researchers have been studying the potential of cubosome as “delivery systems”.

Cubosomes as drug delivery system: Recent advance / 第二军医大学学报

Cubosomes are self-assembled nanostructured particles formed by aqueous lipid and surfactant systems. Cubosomes are thermodynamically stable; they have a structure like "honeycombed" with bicontinuous domains of water and lipid in which surfactant assembles into bilayers and twisted into a three dimension, periodic, and minimal surface, forming a tightly packed structure. The properties of cubosomes, such as its unique bicontinuous cubic phase liquid crystals, its ability to solubilize hydrophobic, hydrophilic, and amphiphilic molecules at the same time, its biodegradability by simple enzyme action, its strong bioadhesion ability, and its simple preparation, make them a promising vehicle for drug delivery. Based on recent reports, this review introduces the structure, preparation, exosyndrome and drug delivery potential of cubosomes.

Ocular pharmacokinetics of dexamethasone cubosomes in rabbit aqueous humor / 中国药科大学学报

Aim: To prepare novel cubosome system for effective ocular drug delivery with dexamethasone(DEX) as model drug, and investigate its pharmacokinetic profile in rabbit aqueous humor. Methods: DEX cubosomes was prepared by the method of high-pressure homogenization, and its particle size was determined by the laser particle sizer, and the microstructure observed by cryo-TEM. In addition, Draize method was used to evaluate the ocular irritation of DEX cubosomes. Finally, aqueous humor microdialysis was utilized to evaluate its pharmacokinetics in rabbits. Results: Average diameter of DEX cubosomes was about 200 nm, and the cubic structure of the particles was evident under the cryo-TEM. It was indicated by Draize scores that this dosage form exhibited excellent ocular tolerance. Results of pharmacokinetic profiles in aqueous humor showed that AUC_(0→240) and c_(max) of the rabbit group administered with DEX cubosomes were significantly higher than those of the control group( DEX sodium phosphate eye drops), with AUC_(0→240) of the formulation Fl( 10% oil content) and F2(20% oil content) is being about 1. 8 and 2. 9 times higher than those of the control group, respectively( P <0. 05). Conclusion: The novel ocular drug delivery system of DEX cubosomes was capable of increasing significantly the drug concentration in aqueous humor, and improving the ocular bioavailability.