Rheology and stability of water-in-oil-in-water multiple emulsions containing Span 83 and Tween 80

Multiple emulsions are often stabilized using a combination of hydrophilic and hydrophobic surfactants. The ratio of these surfactants is important in achieving stable multiple emulsions. The objective of this study was to evaluate the long-term stability of water-in-oil-in-water (W/O/W) multiple emulsions with respect to the concentrations of Span 83 and Tween 80. In addition, the effect of surfactant and electrolyte concentration on emulsion bulk rheological properties was investigated. Light microscopy, creaming volume, and rheological properties were used to assess emulsion stability. It was observed that the optimal surfactant concentrations for W/O/W emulsion long-term stability were 20% wt/vol Span 83 in the oil phase and 0.1% wt/vol Tween 80 in the continuous phase. Higher concentrations of Tween 80 had a destructive effect on W/O/W emulsion stability, which correlated with the observation that interfacial film strength at the oil/water interface decreased as the Tween 80 concentration increased. High Span 83 concentrations increased the storage modulus G′ (solidlike) values and hence enhanced multiple emulsion stability. However, when 30% wt/vol Span 83 was incorporated, the viscosity of the primary W/O emulsion increased considerably and the emulsion droplets lost their shape. Salt added to the inner aqueous phase exerted an osmotic pressure that caused diffusion of water into the inner aqueous phase and increased W/O/W emulsion viscosity through an increase in the volume fraction of the primary W/O emulsion. This type of viscosity increase imposed a destabilizing effect because of the likelihood of rupture of the inner and multiple droplets.     

Preparation of stable W/O/W type multiple emulsion containing water-soluble drugs and in vitro evaluation of its drug-releasing properties]

The stable water-in-oil-in-water (W/O/W) multiple emulsion was prepared by a two-step procedure for emulsification using glyceryl tricaprylate (Panasate-800) as the oil phase. The water-soluble drugs such as cefadroxil, cephradine, 4-aminoantipyrine, and antipyrine were selected and entrapped separately in the inner aqueous phase of W/O/W multiple emulsion. In consideration of parenteral administration, pH 7.4 phosphate buffered saline was used in both inner and outer aqueous phases. Moreover, these multiple emulsions could be significantly stable for a month at room temperature by the addition of hydrophilic polymer like gelatin and of amino acid like lysine to the inner aqueous phase.     

W/O/W型甘草酸单铵盐口服复乳的药物释放研究

Ｗ／Ｏ／Ｗ型甘草酸单铵盐口服复乳的药物释放研究高晓黎，孙殿甲，邱洪卓（新疆医学院药学系，乌鲁木齐８３００５４；天山制药工业有限公司，乌鲁木齐８３００００）甘草酸及其盐有广泛的药理作用，并在临床上用于病毒性肝炎的治疗。甘草酸单铵盐易溶于热水，冷后成凝胶...     

In vitro microbicidal activity of W/O/W multiple emulsion for vaginal administration

The microbicidal activity of a W/O/W multiple emulsion destined for vaginal application, containing lactic acid in the internal aqueous phase, octadecylamine (ODA) in the oily phase and benzalkonium chloride (CBZ) in the external aqueous phase was evaluated against three microbial strains: Escherichia coli, Staphylococcus aureus and Candida albicans. The results were different depending on the procedure used. Interpretable results were obtained if only a gentle agitation was used just after the introduction of the microbial suspension to the product. This suggested that vigorous agitation lead to a variable fraction of CBZ or ODA entrapped in the micelles of ethylene and propylene oxide copolymer (COE).     

Pharmacokinetics of Vancomycin after Intravenous Administration of a W/O/W Emulsion to Rats

A stable water-in-oil-in-water multiple emulsion (w/o/w emulsion) was prepared, and its potential for drug delivery was evaluated. W/o/w emulsions were prepared using a Lipiodol Ultra-Fluid(r) and isopropyl myristate oil mixture for the oily phase and vancomycin (VCM) for the entrapped drug. The surfactants, HCO-40 (5% [w/v]) and Pluronic F-88 were dissolved in the oily phase and the external aqueous phase, respectively. Resultant w/o/w emulsions were evaluated for entrapment efficiency, particle size, viscosity, drug release in vitro, and disposition kinetics of the drug and the w/o/w emulsion in vivo. The particle size of the w/o/w emulsion decreased with an increase in the concentration of F-88 in the external aqueous phase and stirring speed at the second emulsification stage (the smallest being 2.9 ± 1.5 μm). Entrapment efficiency of VCM in the w/o/w emulsion decreased with an increase in the concentration of F-88 (the maximum being 65.3 ± 5.4%). VCM release from the w/o/w emulsion was prolonged and tended to be slower with an increase in the particle size of the emulsion. After intravenous administration, significant differences in pharmacokinetic parameters, such as k₂₁, k_elβ, AUC₀-±, MRT₀-₆, and MRT₀-±, were observed between the VCM solution and the w/o/w emulsion-entrapped drug. When the w/o/w emulsion with Sudan II in the oily phase was administered intravenously, the emulsion accumulated in the lung at first (the highest value was observed just after administration) and then in the liver (the highest value was observed at 60 min). The w/o/w emulsion prepared in this study is expected to be a possible carrier for the prolonged release of water-soluble drugs after intravenous administration.     

内水相添加氯化钠对W/O/W型复乳性质的影响

目的探讨在内水相中添加氯化钠(NaCl)对W/O/W型复乳性质的影响。方法在前期试验优选出较佳W/O/W复乳处方的基础上,以1 g/L NaCl水溶液代替处方中的纯化水作为内水相,采用二步乳化法制备复乳,从显微结构、粒径分布、稳定性等方面比较复乳性质的变化。结果在内水相中添加NaCl(1 g/L)时,复乳主要为B型结构,外观较圆整,液滴大小较均匀,且乳滴不易聚集成一团,大部分粒子粒径在20～40μm之间,稳定性良好。结论在内水相中添加NaCl(1 g/L),有助于优化W/O/W型复乳物理化学性质,提高其稳定性。     

Self-emulsifying O/W formulations of paclitaxel prepared from mixed nonionic surfactants

Nonionic self-emulsifying oil-in-water (O/W) formulations free of Cremophore® were developed as drug delivery vehicles for paclitaxel. The surfactants used included phosphatidylcholine purified from egg yolk (EPC), Tween, and Span. Oils phases were either pure components or blends from benzyl alcohol, 2-phenylethanol benzyl benzoate, and tributyrin. Among these surfactants, mixtures of EPC and Tween-80 gave really stable emulsions in proper sizes ranging from 70 to 200 nm, mainly depends on the ratio of EPC to Tween-80 and amount of oils. Paclitaxel could be well preserved without any loss in oily stocks, namely mixtures of oils and paclitaxel as well as surfactants, stored at 4°C for more than 8 months. Only gentle mixing on oily stocks with aqueous diluents is enough to make paclitaxel-contained emulsions. The optimum formulation contains oils from 1 to 3 wt%, Tween-80 and EPC from 0.4 to 1.2 wt%, respectively. Consequently, near 500 ppm of paclitaxel can be contained in emulsions. Moreover, these paclitaxel-containing emulsions are compatible with commonly used injection fluids. No precipitation is observed upon preparation of emulsion from dilution of oily stocks. Negligible cytotoxicity on these emulsions assessed with NIH/3T3 cells implied their good biocompatibility and promising applications as drug delivery carriers. © 2009 Wiley-Liss, Inc. and the American Pharmacists Association J Pharm Sci 99: 2320–2332, 2010     

Process and formulation variables in the preparation of wax microparticles by a melt dispersion technique. II. W/O/W multiple emulsion technique for water-soluble drugs.

Pseudoephedrine HCl-carnauba wax microparticles were prepared by a multiple emulsion-melt dispersion technique. A heated aqueous drug solution was emulsified into the wax melt (W/O emulsion), followed by emulsification of this primary emulsion into a heated external aqueous phase (W/O/W emulsion). The drug-containing microparticles were formed after cooling and congealing of the wax phase. The encapsulation efficiencies were above 80 per cent and actual drug loadings close to 50 per cent were achieved. The surface of the microparticles had submicron pores and drug crystals were visible on cross-sections. The drug loading depended on the rate of cooling and the volume of the internal aqueous phase but was insensitive to the volume of the continuous phase. The drug release was much faster when compared to the release from polymeric microspheres.     

Release of 5-fluorouracil from intramuscular w/o/w multiple emulsions

Comparative in vivo studies of aqueous solution, multiple w/o/w, and w/o emulsions showed that formulating 5-fluorouracil in emulsion systems significantly sustained the release of the drug from intramuscular injection sites in the rat. Intramuscular injection of the drug in both w/o and w/o/w emulsion systems produced sustained blood concentrations with a later blood level peak than observed following intramuscular injection of aqueous solutions of the drug. The multiple w/o/w emulsion exhibited a more rapid release of drug from the injection site than the w/o emulsion because of partitioning of the drug to the external aqueous phase during secondary emulsification. The fate of the oil phase following intramuscular injection of a water/hexadecane/water multiple emulsion spiked with 1-14C-hexadecane has been studied in rats as a function of stabilizer concentrations. Increasing the lipophilic surfactant (Span 80) concentration facilitated the clearance of the oily vehicle from the injection site, by mechanisms which remain to be elucidated.     

Process and formulation variables in the preparation of wax microparticles by a melt dispersion technique. II. W/O/W multiple emulsion technique for water-soluble drugs

Abstract

Pseudoephedrine HCl-carnauba wax microparticles were prepared by a multiple emulsion-melt dispersion technique. A heated aqueous drug solution was emulsified into the wax melt (W/O emulsion), followed by emulsification of this primary emulsion into a heated external aqueous phase (W/O/W emulsion). The drug-containing microparticles were formed after cooling and congealing of the wax phase. The encapsulation efficiencies were above 80 per cent and actual drug loadings close to 50 per cent were achieved. The surface of the microparticles had submicron pores and drug crystals were visible on cross-sections. The drug loading depended on the rate of cooling and the volume of the internal aqueous phase but was insensitive to the volume of the continuous phase. The drug release was much faster when compared to the release from polymeric microspheres.     

W/O/W multiple emulsions with diclofenac sodium.

The disperse oil droplets of W/O/W multiple emulsions contain small water droplets, in which drugs could be incorporated, but the structure of these emulsions is also the reason for possible instability. Due to the middle oil phase which acts as a 'semipermeable' membrane the passage of water across the oil phase can take place. However, the emulsions have been produced in a two-step-production process so not only the leakage of encapsulated drug molecules out of the inner water phase during storage but also a production-induced reduction of the encapsulation rate should be considered. The aim of this study was to ascertain how far the production-induced reduction of the encapsulation rate relates to the size of inner water droplets and to evaluate the relevance of multiple emulsions as drug carrier for diclofenac sodium. Therefore multiple emulsions were produced according to a central composite design. During the second production step it was observed that the parameters pressure and temperature have an influence on the size of the oil droplets in the W/O/W multiple emulsions. Further experiments with different W/O emulsions resulted in W/O/W multiple emulsions with different encapsulation rates of diclofenac sodium, due to the different sizes of the inner water droplets, which were obtained in the first production step.     

W/O/W型薄荷油复乳的制备及其性质初步研究

目的制备薄荷油W/O/W型复乳,并对其性质进行初步研究。方法采用二步法制备薄荷油W/O/W型复乳,对其物理性质如:外观、显微形态、乳剂类型、粘度、表面张力、相变温度、物理稳定性等方面进行初步研究。结果薄荷油W/O/W型复乳外观呈白色、外相能被曙红指示液染色、室温下的粘度为15.2 mPa.S,表面张力为30×10-3N.m-1,相变温度为84℃。结论二步法制备薄荷油W/O/W型复乳物理稳定性较好。     

Preparation of solid lipid nanoparticles from W/O/W emulsions: preliminary studies on insulin encapsulation

A method to produce solid lipid nanoparticles (SLN) from W/O/W multiple emulsions was developed applying the solvent-in-water emulsion-diffusion technique. Insulin was chosen as hydrophilic peptide drug to be dissolved in the acidic inner aqueous phase of multiple emulsions and to be consequently carried in SLN. Several partially water-miscible solvents with low toxicity were screened in order to optimize emulsions and SLN composition, after assessing that insulin did not undergo any chemical modification in the presence of the different solvents and under the production process conditions. SLN of spherical shape and with mean diameters in the 600-1200 nm range were obtained by simple water dilution of the W/O/W emulsion. Best results, in terms of SLN mean diameter and encapsulation efficiencies, were obtained using glyceryl monostearate as lipid matrix, butyl lactate as a solvent, and soy lecithin and Pluronic F68 as surfactants. Encapsulation efficiencies up to 40% of the loaded amount were obtained, owing to the actual multiplicity of the system; the use of multiple emulsion-derived SLN can be considered a useful strategy to encapsulate a hydrophilic drug in a lipid matrix.     

Preparation of solid lipid nanoparticles from W/O/W emulsions: Preliminary studies on insulin encapsulation

Abstract

A method to produce solid lipid nanoparticles (SLN) from W/O/W multiple emulsions was developed applying the solvent-in-water emulsion-diffusion technique. Insulin was chosen as hydrophilic peptide drug to be dissolved in the acidic inner aqueous phase of multiple emulsions and to be consequently carried in SLN. Several partially water-miscible solvents with low toxicity were screened in order to optimize emulsions and SLN composition, after assessing that insulin did not undergo any chemical modification in the presence of the different solvents and under the production process conditions. SLN of spherical shape and with mean diameters in the 600–1200 nm range were obtained by simple water dilution of the W/O/W emulsion. Best results, in terms of SLN mean diameter and encapsulation efficiencies, were obtained using glyceryl monostearate as lipid matrix, butyl lactate as a solvent, and soy lecithin and Pluronic®F68 as surfactants. Encapsulation efficiencies up to 40% of the loaded amount were obtained, owing to the actual multiplicity of the system; the use of multiple emulsion-derived SLN can be considered a useful strategy to encapsulate a hydrophilic drug in a lipid matrix.     

Particle control of emulsion by membrane emulsification and its applications

Particle-size control of emulsion is very important for maintaining stability and giving emulsions new functional roles. Porous glass membrane, prepared by phase separation of a glass composition, is available as an emulsifying element, from which, one can obtain monodispersed emulsion with different particle sizes, and useful water/oil/water (W/O/W) emulsion in very high yield. The authors have called this new technology 'membrane emulsification'. Applications of membrane emulsification technology to drug delivery systems were carried out under cooperative research with Miyazaki Medical College. It was found that the clinical administration of a W/O/W drug emulsion that encapsulated an anticancer drug in its inner droplets was surprisingly effective for both terminal and multiple nodules of hepatocellular carcinoma when the drug was injected to damaged liver through a catheter inserted in the hepatic artery. Other applications have been tried and developed elsewhere.     

Preparation of microcapsules and control of their morphology

For the preparation of microcapsules using the W/O/W (water in oil in water) emulsion system, it is essential to control various factors such as the dispersed state of the organic phase in the W/O/W emulsion, the difference in the solute concentration between the inner and outer aqueous phases and the volume fraction of the dispersed phase. In this study, cross-linked microcapsules were prepared by the in-situ polymerization of styrene and divinylbenzene and biodegradable microcapsules were prepared by the solvent evaporation method. The effects of the preparation conditions on the capsule morphology and entrapment efficiency of water-soluble materials were investigated. The average diameter of the surface pores and internal hollows were controlled on a sub-micron order by changing the preparation conditions such as diluent concentration, volume fraction of the dispersed droplets in the W/O (water in oil) emulsion, surfactant concentration monomer ratio and salt concentration in the outer aqueous phase. Furthermore, the water-soluble materials were completely entrapped in the biodegradable microcapsule by changing the preparation conditions such as volume fraction of the dispersed droplets in the W/O emulsion, salt concentration in the inner and outer aqueous phases, polymer concentration and supersonic irradiation of the W/O droplets.     

Water-in-oil-in-water double emulsions loaded with chlorogenic acid: release mechanisms and oxidative stability

Abstract

Chlorogenic acid (CA) is a natural compound used as an antioxidant in the preparation of food, drugs, and cosmetics. Due to their low stability and bioavailability, many researchers have studied the encapsulation of CA in various delivery colloidal systems. The aim of this study was to evaluate the stability of water-in-oil-in-water (W/O/W) double emulsions loaded with CA and its antioxidant capacity. For this purpose, CA-W/O/W double emulsions were prepared using Span 80 and lecithin as lipophilic emulsifiers, and Tween 20 as a hydrophilic emulsifier. The influence of nature of lipophilic emulsifiers, the presence of chitosan (CH) in the internal and external aqueous phases, pH, temperature and the storage time of W/O/W double emulsions were also investigated. Depending on the preparation conditions, the W/O/W double emulsions showed the droplet size in the range 9.13?±?0.55?μm–38.21?±?1.87?μm, the creaming index 34%–78% and the efficiency encapsulation 79.45?±?1.5%–88.13?±?1.9%. Zeta potential values were negative for the W/O/W double emulsion without CH (?36.8?±?2.02mV; ?27.3?±?1.75mV) and positive for the W/O/W double emulsions with CH in the external aqueous phase (+6.5?±?0.42mV; 28.6?±?0.92mV). The study of the release of CA from W/O/W double emulsions has highlighted two mechanisms: one based on the coalescence between the water inner droplets or between the oil globules as well as a diffusion releasing mechanism. The oxidative stability parameters of the W/O/W double emulsions, such as the peroxide value (POV) and the conjugated diene content (CD) were measured.     

Slow release of chloroquine phosphate from multiple taste-masked W/O/W multiple emulsions

Abstract

The efficacy and safety of chloroquine as an antimalarial has contributed to the survival of millions in the past 50 years. Chloroquine is widely available, cheap, well tolerated and orally well absorbed. Therefore, it remains an important antimalarial drug. However, on oral administration, particularly to children, the unpleasant taste is a problem. This could be avoided by ‘taste-masked and controlled release’ formulations such as multiple emulsions. Although Plasmod-ium falciparum has developed resistance to many antimalarial drugs, including chloroquine, resistance may be attributed, among other factors, to subclinical dosage of chloroquine from administered pharmaceutical forms. This could also be relevant in the treatment of rheumatoid arthritis. Multiple W/O/W emulsions of chloroquine phosphate were prepared. Assessment of emulsion stability showed no significant change in the system. Prolonged storage (four months) of the emulsion resulted in negligible loss of chloroquine phosphate. The results suggest, therefore, that chloroquine phosphate releases due to diffusion of the drug from the internal globules and not as a consequence of instability of the W/O/W emulsion. These characteristics are in accordance with the requirements for controlled release Pharmaceuticals. Stability of multiple emulsions could have resulted from interfacial polymerization or complexion between molecules. Release assessments showed faster rates for W/O/W emulsions which had smaller internal aqueous globules and, therefore, an increased interfacial area. Furthermore, transport of high-diffusion coefficient micelles could have given a greater solute flux in these systems.     

The nature of the oil phase and the release of solutes from multiple (w/o/w) emulsions

The effect of the nature of the oil phase of w/o/w emulsions stabilized by interfacial complexation between span 80 (sorbitan mono-oleate) and albumin has been studied. The long-term stability of the systems has been assessed by photomicrography and by measuring the quantity of an internal marker (NaCl) remaining entrapped with time. The number of multiple oil drops and the diameters of the internal aqueous droplets were determined over 6 weeks, and the amounts of NaCl entrapped over the same period were followed. There were no significant changes in w/o/w emulsions prepared with a range of hydrocarbons (octane, dodecane, hexadecane, toluene and cyclohexane), indicating stable multiple emulsions. The release of NaCl and 5-fluorouracil (5-FU) separately entrapped in the internal aqueous phase of w/o/w emulsions was measured. Diffusion of the un-ionized species of 5-FU across the oil phase or through localized thin oil lamellae is the primary transport mechanism. In the presence of surface active agents, water is solubilized in inverse micelles which would possess the ability to solubilize other water-soluble components, such as NaCl and 5-FU. The mixed inverse micellar units of Span 80 and polysorbate (Tween) 80 therefore act as solute carriers across the liquid hydrocarbon membrane separating the two aqueous phases of the emulsions. The main factor in determining the differences in rates of release from the hydrocarbon emulsions appears to be the droplet size of the internal aqueous phase.     

Preparation of microcapsules and control of their morphology

For the preparation of microcapsules using the W/O/W (water in oil in water) emulsion system, it is essential to control various factors such as the dispersed state of the organic phase in the W/O/W emulsion, the difference in the solute concentration between the inner and outer aqueous phases and the volume fraction of the dispersed phase. In this study, cross-linked microcapsules were prepared by the in-situ polymerization of styrene and divinylbenzene and biodegradable microcapsules were prepared by the solvent evaporation method. The effects of the preparation conditions on the capsule morphology and entrapment efficiency of water-soluble materials were investigated. The average diameter of the surface pores and internal hollows were controlled on a sub-micron order by changing the preparation conditions such as diluent concentration, volume fraction of the dispersed droplets in the W/O (water in oil) emulsion, surfactant concentration monomer ratio and salt concentration in the outer aqueous phase. Furthermore, the water-soluble materials were completely entrapped in the biodegradable microcapsule by changing the preparation conditions such as volume fraction of the dispersed droplets in the W/O emulsion, salt concentration in the inner and outer aqueous phases, polymer concentration and supersonic irradiation of the W/O droplets.