Preparation and evaluation of multiple emulsions water-in-oil-in-water (w/o/w) as delivery system for influenza virus antigens

In this study, investigations have been carried out to prepare adjuvant active delivery systems; multiple water-in-oil-in-water (w/o/w) emulsion formulations, containing influenza virus surface antigen Hemagglutinin (HA). A modified two-stage emulsification method has been used to prepare multiple emulsions. After improving multiple (w/o/w) emulsion formulations; F1: purified antigen solution (PAS)/soybean oil, HCO-40 and span 80/pluronic F-68, F2: PAS and HPbetaCD/soybean oil, HCO-40 and span 80/pluronic F-68, F3: PAS/squalane, HCO-40 and span 80/pluronic F-68, formulations were selected for the stability study that continued for a 3 month duration. To evaluate the stability of these formulations, microscopic observation, osmolarities of the internal and external aqueous phases, pH, globule size and viscosity were determined. SDS-PAGE (silver staining) was used to evaluate HA and the micro-bicinchoninic acid (mBCA) assay was used to determine the in vitro release of antigen from formulations. Immune responses of formulations were investigated in Wistar Albino rats and compared with the immune response raised against the conventional vaccine. These responses were detected with Hemagglutination Inhibition (HAI) assay. The results of this study demonstrated that HA was well entrapped in the multiple (w/o/w) emulsion formulations. Molecular weight and antigenicity of the entrapped HA were not affected by the emulsification procedure. These results suggest that multiple emulsion formulations entrapping influenza antigen may have potential for immunization studies as one of the vaccine delivery system with adjuvant properties.     

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.     

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.     

Comparison of biodegradable nanoparticles and multiple emulsions (water-in-oil-in-water) containing influenza virus antigen on the in vivo immune response in rats

Multiple water-in-oil-water (w/o/w) emulsion and polymeric nanoparticle formulations containing influenza virus surface antigen hemagglutinin (HA) are thought to be suitable carriers for a vaccine delivery system. The multiple emulsion technique leads to high entrapment of HA, while the solvent evaporation technique encapsulates and adsorbs HA within the nanoparticle. Immune responses of these formulations were investigated in rats and compared with the immune response raised against the conventional vaccine. The responses were detected with the hemagglutinin inhibition (HAI) assay. A single administration of multiple emulsion (F1, F2, F3) and nanoparticle (F4) formulations proved to stimulate a more effective immune response in rats than conventional vaccine.     

In vitro release, pharmacokinetic and tissue distribution studies of doxorubicin hydrochloride (Adriamycin HCl) encapsulated in lipiodolized w/o emulsions and w/o/w multiple emulsions.

The lipiodolized w/o emulsion or w/o/w multiple emulsion containing Doxorubicin hydrochloride (1; Adriamycin HCl) with different emulsifiers was prepared to evaluate in vitro sustained-release behavior, pharmacokinetic and tissue distribution function in Sprague Dawley (SD) rats. The results of dissolution indicate that the release of 1 was significantly sustained for both emulsions when HCO-60 (polyoxyethylene (60) hydrogenated castor oil) was used as an emulsifier. The serum concentration of 1 was reduced and prolonged for both emulsions with the increase of HCO-60. The C(max) level was lowered and T(max) value was delayed after administration of w/o emulsions with higher HCO-60 concentration. The apparent terminal half-life for 1 released from some emulsions with higher concentration of HCO-60 was 3-folds higher than that of the 1 solution. The clearance of some w/o or w/o/w ADR emulsions also decreased with the increase of HCO-60. Not only the concentration of 1 in heart and kidney decreased significantly after the administration of w/o emulsions with the higher concentration of HCO-60, but also the hepatic concentration of 1 was higher and increased with HCO-60 concentration. The hepatic 1 level became lower after administration of w/o/w multiple emulsions with the increase of HCO-60; however, the concentration of 1 in heart, lung and spleen increased somewhat. The results indicate that lipiodol and HCO-60 seemed to play an important role in the prolongation and selective retention of w/o emulsion or w/o/w multiple emulsion, in vitro and in vivo.     

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.     

Basic study for stabilization of w/o/w emulsion and its application to transcatheter arterial embolization therapy

Stabilization of w/o/w emulsion and its application to transcatheter arterial embolization (TAE) therapy are reviewed. W/o/w emulsion was stabilized by making inner aqueous phase hypertonic, addition of chitosan in inner phase, and techniques of phase-inversion with porous membrane. Lipiodol w/o/w emulsion for TAE therapy was prepared by using a two-step pumping emulsification procedure. The procedure is so easy that the emulsion could be prepared even during the surgical operation. The deposition after hepatic arterial administration of the emulsion was detected by an X-ray CT scanner. The concentration of epirubicin hydrochloride (EPI) in liver was increased and its residence was prolonged by encapsulating it in the w/o/w emulsion. The toxic effects of EPI and lipiodol on the normal hepatic cells were reduced. The w/o/w emulsion prepared by us is a suitable formulation for the TAE therapy.     

Preparation and evaluation of w/o/w type emulsions containing vancomycin

The objective of this contribution is to summarize the preparation and application of water-in-oil-in-water type multiple emulsions (w/o/w emulsions) entrapping vancomycin (VCM). Formulations of the emulsions (the composition of an oily phase or the type and concentrations of surfactants) and emulsification methods (a stirring method and a membrane method) or conditions (rotation rates, pore sizes of membrane or operation pressures) were evaluated in order to prepare stable w/o/w emulsions. The pharmaceutical properties of the w/o/w emulsions - particle sizes, viscosity, phase separation and drug entrapment efficiency were measured and evaluated. We prepared stable w/o/w emulsions with a particle size of about 3 micrometer and an entrapment efficiency of VCM of about 70%. When this emulsion was administered intravenously to rats, plasma concentrations of VCM were prolonged compared to the VCM solution alone. The results of this study show the potential of the w/o/w emulsions for several clinical applications as one of the drug delivery systems.     

In vitro percutaneous absorption of metronidazole and glucose: Comparison of o/w,w/o/w and w/o systems

The percutaneous absorption of model hydrophilic drugs with intermediate and high polarity, metronidazole and glucose, respectively, from three emulsion types (o/w, w/o/w and w/o) has been studied. All the emulsions were prepared with exactly the same composition in order to avoid the influence of the formulation and to study the role of the emulsion type alone. The yield of the w/o/w emulsion containing glucose was high (95.8%), while that of the w/o/w emulsion containing metronidazole was lower (77.6%), although the multiple character of the emulsion was not in question. Absorption of metronidazole across hairless rat skin over 24 h ranged from 55 to 69% of the applied dose and was similar for the three emulsions studied. Absorption of glucose ranged from 1 to 4% and was found to be greater from the o/w emulsion than that observed from the w/o/w or w/o emulsions. The amount of glucose found in the dermis seems to be dependent on the emulsion type: o/w > w/o/w ≅ w/o. The differences between the emulsions cannot be attributed only to the evaporation rate of water alone. X-ray diffraction patterns obtained after treatment of the stratum corneum with the three emulsions did not display any difference, but were somewhat different from that observed with untreated stratum corneum.     

Insulin in w/o/w multiple emulsions: Biological activity after oral administration in normal and diabetic rats

Abstract

In this work the biological effects of two w/o/w multiple emulsions composed of the soybean oil (EHS) or medium-chain triglycerides (ETCM), containing insulin, were studied. The release mechanism of insulin from multiple emulsions proposed in our previous in-vitro investigations was confirmed by subcutaneous administration. This mechanism is the swelling-breakdown phenomenon which occurs when the emulsions are diluted under hypo-osmotic condition. The biological effect after oral administration, evaluated in two experimental protocols, single administration in normal and diabetic rats and short-term treatment in diabetic rats, shows that in diabetic rats small amounts of biologically active insulin were absorbed from these emulsions. In these experiments no significant difference between EHS and ETCM was found.     

Inverse targeting of diclofenac sodium to reticuloendothelial system-rich organs by sphere-in-oil-in-water (s/o/w) multiple emulsion containing poloxamer 403

Sphere-in-oil-in-water (s/o/w) multiple emulsions containing diclofenac sodium were prepared by gelatinization of inner aqueous phase. A further modified version (s/o/wp) of s/o/w was formulated by adding 5.0% w/v poloxamer 403 to the external aqueous phase during the second step of emulsification in order to affect the adsorptive coating on the surface (s/o/wp). The inverse targeting of reticuloendothelial system (RES) rich organs was compared with a non reticuloendothelial system after intravenous administration of s/o/w multiple emulsion (treatment I) and poloxamer containing s/o/wp multiple emulsion (treatment II). The amount of diclofenac sodium in the plasma and various organs was measured to elucidate the effect of inverse targeting to RES and targeting to other tissues in terms of the incorporated drug. After i.v. administration, the half life (34.65 vs.16.26 h) and apparent volume of distribution of diclofenac sodium (2815 vs. 1671.5 ml/kg) were significantly higher in treatment II than in treatment I. It is concluded that the amount of drug in RES rich organs (spleen, liver) were significantly lower than the values in non-RES organs such as lungs, inflammatory tissue (synovial fluid) in treatment II than in treatment I.     

Inverse targeting of diclofenac sodium to reticuloendothelial system-rich organs by sphere-in-oil-in-water (s/o/w) multiple emulsion containing poloxamer 403

Sphere-in-oil-in-water (s/o/w) multiple emulsions containing diclofenac sodium were prepared by gelatinization of inner aqueous phase. A further modified version (s/o/wp) of s/o/w was formulated by adding 5.0% w/v poloxamer 403 to the external aqueous phase during the second step of emulsification in order to affect the adsorptive coating on the surface (s/o/wp). The inverse targeting of reticuloendothelial system (RES) rich organs was compared with a non reticuloendothelial system after intravenous administration of s/o/w multiple emulsion (treatment I) and poloxamer containing s/o/wp multiple emulsion (treatment II). The amount of diclofenac sodium in the plasma and various organs was measured to elucidate the effect of inverse targeting to RES and targeting to other tissues in terms of the incorporated drug. After i.v. administration, the half life (34.65 vs.16.26 h) and apparent volume of distribution of diclofenac sodium (2815 vs. 1671.5 ml/kg) were significantly higher in treatment II than in treatment I. It is concluded that the amount of drug in RES rich organs (spleen, liver) were significantly lower than the values in non-RES organs such as lungs, inflammatory tissue (synovial fluid) in treatment II than in treatment I.     

Development and characterization of thermosensitive pluronic-based metronidazole in situ gelling formulations for vaginal application

The purpose of this study was to develop pluronic-based in situ gelling formulations of metronidazole (MTZ) for treatment of bacterial vaginosis, aimed at prolonging the residence time, controlling drug release, enhancing efficacy, decreasing recurrence, and increasing patient compliance. The in situ gel formulations were prepared using different concentrations of pluronic F-127 (PF-127) alone and in combination with pluronic F-68 (PF-68). The prepared formulations were evaluated for their gelation temperature (T(gel)), in vitro drug release, rheological properties, mucoadhesion properties and tolerability by vaginal mucosa in tissue levels. The T(gel) decreased with increasing PF-127 concentration. The T(gel) was modulated by addition of PF-68 to be within the acceptable range of 25-37 °C. With increasing pluronic concentration, the in vitro drug release decreased, viscosity and mucoadhesive force increased. Histopathological examination of rabbit vaginas from the control and treated groups revealed normal histology of the vagina and cervix. Based on the in vitro evaluation of prepared formulations, the in situ gelling liquid formulated with PF-127/PF-68 (20/10 %, m/m) was selected for further clinical evaluation.     

The role of microsphere fabrication methods on the stability and release kinetics of ovalbumin encapsulated in polyanhydride microspheres

The effect of microsphere fabrication methods on the stability and release kinetics of ovalbumin encapsulated in polyanhydride microspheres was investigated. The polyanhydrides used were poly(sebacic anhydride) (poly(SA)) and a 20:80 random copolymer of poly[1,6-bis(p-carboxyphenoxy)hexane] (poly(CPH)) and poly(SA). Microspheres were fabricated using three double emulsion methods (water/oil/water, water/oil/oil and solid/oil/oil) and cryogenic atomization. The encapsulation efficiency was highest for cryogenic atomization and lowest when the w/o/w technique was used. Microspheres fabricated by the s/o/o method had the largest initial burst of released protein. All the methods resulted in zero-order release of the protein after the burst. The release of ovalbumin from poly(SA) and 20:80 (CPH:SA) microspheres lasted ～3 and ～6 weeks, respectively. For all fabrication methods the primary structure of released ovalbumin was conserved as determined by gel electrophoresis. The secondary structure of ovalbumin encapsulated in 20:80 (CPH:SA) w/o/w microspheres was not conserved.     

Sorbitan monostearate/polysorbate 20 organogels containing niosomes: a delivery vehicle for antigens?

Multi-component organogels formed using the non-ionic surfactant sorbitan monostearate as gelator have been formulated to contain niosomes. The purpose of this study was to evaluate the potential of these vesicle-in-water-in-oil (v/w/o) gels as delivery vehicles for vaccines. Bovine serum albumin (BSA) and haemagglutinin (HA) were used as model antigens in depot and immunogenicity studies respectively. The complex gels were prepared by the addition of a hot (60 degrees C) aqueous niosome suspension (v/w) to the sol phase (o, an organic solution of the gelator); a vesicle-in-water-in-oil (v/w/o) emulsion was produced which cools to an opaque, semi-solid, thermoreversible v/w/o gel. Light microscopy of the organogel revealed that the microstructure consists of a tubular network of surfactant aggregates in the organic medium, the niosome suspension being dispersed in these surfactant tubules. Therefore, in such gels, the vaccine is thought to be entrapped in the niosomes, themselves located within the sorbitan monostearate tubular network in the organic medium. In vivo, a depot effect was observed following intramuscular administration of the gel containing the entrapped bovine serum albumin, cleared from the injection site over a period of days. The relatively short-lived nature of the depot was thought to arise due to interactions between the gel and the local interstitial fluid which results in gel disintegration in situ. Thus, the niosomes containing antigens are believed to be released from the organic gel. Immunogenicity studies showed that the v/w/o gel as well as one of the controls, the water-in-oil (w/o) gel, possess immunoadjuvant properties and enhance the primary and secondary antibody titres (of total IgG, IgG1, IgG2a and IgG2b) to haemagglutinin antigen. As far as humoral immunity is concerned, the w/o gel showed stronger immunoadjuvant properties compared to the v/w/o gel, being effective at a lower antigen dose i.e 0.1 microg HA.     

Effects of polymer,organic solvent and mixing strength on integrity of proteins and liposomes encapsulated in polymeric microspheres fabricated by the double emulsion process

The double emulsion process has commonly been applied to encapsulate water-soluble bioactive agents into polymeric microspheres. However, the integrity of many of these agents may be destroyed by the highly energetic procedures such as sonication that are routinely used to produce stable water-in-oil (w/o) emulsion. The aim of this research was to pursue the possibility of replacing the sonication by a mild emulsification procedure such as vortex mixing, with the use of certain materials to help to obtain stable w/o emulsion. The following materials were examined: poly(lactide-co-ethylene glycol) (PELA) as the polymer, ethyl acetate and acetone as the solvents, poly(vinyl alcohol) (PVA) and d-α tocopheryl polyethylene glycol 1000 succinate (Vitamin E TPGS) as the emulsifiers in w/o emulsion. The experimental results, with human serum albumin (HSA) as the encapsulated agent, showed that, when vortex mixing was used, these materials could significantly improve w/o emulsion stability and help to obtain satisfactory encapsulation effects, i.e. high encapsulation efficiency (EE) and low initial release burst. A delicate structure, i.e. liposomes, which is very sensitive to sonication, was then incorporated into microspheres by the ‘modified double emulsion process’. It was found that the liposomes were intact and the encapsulation effects were good. Therefore, it can be concluded that the modified double emulsion process could be advantageous for the encapsulation of delicate substances.     

Releasing properties of water soluble drug in internal water phase of W/O/W multiple emulsions]

A stable water/liquid paraffin system water-in-oil-in-water (W/O/W) multiple emulsion was prepared by the two-step procedure of emulsification using a variety of nonionic emulsifying agents, such as Span 80 and Tween 20. After comparison of the releasing properties of such water soluble drugs as cefadroxil, cephradine, 4-aminoantipyrine and antipyrine which were entrapped separately in the inner aqueous phase of the W/O/W multiple emulsion, a large difference was observed. It was ascertained that the difference in these releasing properties was due to no physical rupture by the microscopic observation and the results of the release test of W/O/W multiple emulsion with two kinds of drugs entrapped simultaneously in an inner aqueous phase. This reason was presumed to be dependent on permeation in the oily phase of the drug itself. It was proved that the differences of releasing properties tended to depend on the molecular weight and were closely related to the drug concentration of outer aqueous phase of W/O/W multiple emulsion containing the drug in both aqueous phases prepared as an experimental model. Therefore, two possible mechanisms for the releasing of drugs in W/O/W multiple emulsion may be interpreted as follows: the first is that the mixed and inversed micelles formed by Span 80 and Tween 20 agents in the oily phase act as a carrier of drugs, and the second is that drug molecules diffuse through small pore existing in very thin lamella of the emulsifying agents partially formed in the oil layer owing to the fluctuation of the thickness.     

Organic solvent-free polymeric microspheres prepared from aqueous colloidal polymer dispersions by a w/o-emulsion technique

Polymeric microspheres were prepared from water-insoluble polymers by a novel technique without the use of organic solvents. Aqueous colloidal polymer dispersions (latexes or pseudolatexes) were emulsified into a heated external oil phase to form a w/o emulsion. The colloidal polymer particles fused (coalesced) into homogeneous polymeric microspheres at temperatures above the minimum film formation temperature upon removal of water. The formation of the microspheres was affected by the glass transition temperature of the polymer, the type of oil and surfactant, the heating temperature and time, and the addition of plasticizers. Plasticizers had to be added to colloidal dispersions with high minimum film formation temperatures. The resulting microspheres were spherical with a smooth surface and non-agglomerated. The particle size could be varied between 5 and 250 μm. Water-soluble compounds such as propranolol HC1 could be entrapped with drug loadings up to 40% within the microspheres by dissolving the drug in the aqueous polymer dispersion prior to the emulsification step. The drug release was sustained over a 6-h period with microspheres prepared with the acrylic pseudolatex, Eudragit RS 30D.     

Comparison of post-emulsification freeze drying or spray drying processes for the microencapsulation of plasmid DNA

In this work, methods used to microencapsulate plasmid DNA in a biodegradable polymer were compared for their effects on the physicochemical characteristics of DNA-loaded microparticles and on the release and integrity of encapsulated DNA. Microparticles were formulated by either w/o/w emulsification and freeze-drying (EFD) or by w/o/w emulsification and spray-drying (ESD). The influence of both manufacturing processes on particle morphology, charge, release characteristics and biological activity of encapsulated DNA was evaluated. Particles produced by emulsification/spray-drying exhibited more diversity in shape and size than those produced by emulsification/freeze-drying. These particles also exhibited higher plasmid DNA encapsulation efficiency than particles produced by emulsification/freeze-drying. The fractional DNA release rates were similar over the first 25 days for both formulations, release rate declining more rapidly at later times for the ESD product. Mammalian cell transfection assays confirmed the biological activity of encapsulated DNA extracted from both types of particles, with significantly higher transfection levels being observed for ESD particles. Application of a double emulsion (w/o/w) before spray drying resulted in higher encapsulation levels (> 90%) relative to previous literature values, which used single (w/o) emulsions before spray drying. The emulsification/spray-drying technique described here appears to be a rapid and efficient method for the preparation of PLGA microparticles loaded with plasmid DNA.     

Rheological study of w/o/w emulsion by a cone-and-plate viscometer: Negative thixotropy and shear-induced phase inversion

The rheological behaviour of a w/o/w emulsion was examined by a cone-and-plate viscometer. Negative thixotropic flow patterns were observed at lower shear rates. This negative thixotropic behavior was more pronounced and the apparent viscosity increased under increased shear rate, prolonged shearing time, or repeated shear. Further shearing, by raising the shear rate or prolonging the shearing time, rapidly increased the shear stress of the emulsion and induced phase inversion. This phase-inverted emulsion was of the w/o type and in a semi-solid state. The energy dissipated by the flow of the emulsion until the occurrence of phase inversion, the kinetic energy of the emulsion at the phase-inversion point, and the impulse applied to the emulsion by the cone of the viscometer were calculated in order to determine the hydrodynamic parameter determining the phase inversion. The impulse applied by the rotating cone was the parameter determining the phase inversion of the emulsion from a w/o/w to a w/o type characterized by being in the semi-solid state. The negative thixotropic flow and the phase inversion of the w/o/w emulsion to the w/o type induced by shearing were explained as being due to the increase in the volume fraction of the oil droplets by entrapment of water molecules and by coalescence of the oil droplets.