Preparation of a water-in-oil-in-water (W/O/W) type microcapsules by a single-droplet-drying method and change in encapsulation efficiency of a hydrophilic substance during storage

Microcapsules of a water-in-oil-in-water (W/O/W) emulsion, which contained a hydrophilic substance, 1,3,6,8-pyrenetetrasulfonic acid tetrasodium salt (PTSA), in its inner aqueous phase, was prepared by hot-air-drying or freeze-drying the emulsion using a single-droplet-drying method. Pullulan, maltodextrin, or gum arabic was used as a wall material, and the oily phase was tricaprylin, oleic acid, olive oil, or a mixture of tricaprylin and olive oil. An encapsulation efficiency higher than 0.95 was reached except for the microcapsules prepared using gum arabic and oleic acid. The hot-air-dried microcapsules were generally more stable than the freeze-dried microcapsules at 37 degrees C and various relative humidities. The stability was higher for the microcapsules with tricaprylin as the oily phase than for the microcapsules with oleic acid. The higher stability of the microcapsules with tricaprylin would be ascribed to the lower partition coefficient of PTSA to the oily phase. There was a tendency for the stability to be higher at lower relative humidity for both the hot-air- and freeze-dried microcapsules. The volumetric fraction of olive oil in its mixture with tricaprylin did not significantly affect either the encapsulation efficiency or the stability of the hot-air-dried microcapsules.     

Rapid exchange of pancreatic lipase between triacylglycerol droplets

Two types of experiments were performed to study the reversibility of interfacial adsorption of pancreatic lipase (PL) to fat droplets during lipolysis. Lipolysis was measured in olive oil/gum arabic emulsions containing radiolabeled triolein in the presence of bile salts and lecithin at rate-limiting concentrations of porcine PL (PPL) or human PL (HPL). The lipolysis rate in a labeled emulsion, i.e. release of [(14)C]oleic acid, was immediately reduced by around 50% upon dilution with an equal amount of an unlabeled emulsion. Further, lipolysis was rapidly and completely suppressed when a non-exchanging lipase inhibitor was present in the second emulsion. These results indicate hopping of lipase between emulsion droplets. Alternative explanations were excluded. Hopping of PL between triolein droplets stabilized with gum arabic at supramicellar bile salt concentrations was observed only in the presence, not in the absence, of lecithin. Displacement from a trioctanoin-water interface of active HPL by an inactive mutant (S152G) was studied in the presence of bile salts by measuring HPL distribution between the water phase and the oil-water interface. Colipase was limiting for HPL binding to the oil-water interface (colipase to lipase molar ratio: 0.5) and, thus, for lipolysis. Upon adding S152G, which has the same affinity for colipase, inactive and active HPL were found to compete for binding at the oil-water interface. When equal amounts of HPL and HPL S152G were used, the lipolysis rate dropped to half the maximum rate recorded with HPL alone, suggesting that half the active HPL was rapidly desorbed from the oil-water interface. Therefore, under various conditions, PL does not remain irreversibly adsorbed to the oil-water interface, but can exchange rapidly between oil droplets, via an equilibrium between soluble and lipid-bound PL.     

Use of combinations of gum arabic,maltodextrin and soybean protein to microencapsulate ginkgo leaf extracts and its inhibitory effect on skeletal muscle injury

In this study, ethanol extracts of ginkgo leaf were microencapsulated with maltodextrin, gum arabic or a soluble soybean protein by spray-drying. The results indicated that, for the microcapsules, the encapsulation efficiency of 81.3% was achieved when air inlet temperature was 181 °C. The oxidation of ginkgo leaf polyphenol under the conditions was retarded by its microencapsulation with gum arabic, maltodextrin or the soybean protein. Thus, microencapsulation of ethanol extracts of ginkgo leaf significantly improved its oxidative stability. Pharmacological experiment showed that ethanol extracts of ginkgo leaf could enhance ALP activities and collagen I in mouse osteoblast MC3T3-E1 cells. Rabbits pretreated with microcapsules of ethanol extracts of ginkgo leaf significantly inhibited ischemia/reperfusion-induced oxidative injury in rabbits’ skeletal muscle.     

Microencapsulation of β-Carotene Based on Casein/Guar Gum Blend Using Zeta Potential-Yield Stress Phenomenon: an Approach to Enhance Photo-stability and Retention of Functionality

β-Carotene, abundant majorly in carrot, pink guava yams, spinach, kale, sweet potato, and palm oil, is an important nutrient for human health due to its scavenging action upon reactive free radicals wherever produced in the body. Inclusion of liposoluble β-carotene in foods and food ingredients is a challenging aspect due to its labile nature and low absorption from natural sources. This fact has led to the application of encapsulation of β-carotene to improve stability and bioavailability. The present work was aimed to fabricate microcapsules (MCs) of β-carotene oily dispersion using the complex coacervation technique with casein (CA) and guar gum (GG) blend. The ratio of CA:GG was found to be 1:0.5 (w/v) when optimized on the basis of zeta potential-yield stress phenomenon. These possessed a higher percentage yield (71.34 ± 0.55%), lower particle size (176.47 ± 4.65 μm), higher encapsulation efficiency (65.95 ± 5.33%), and in general, a uniform surface morphology was observed with particles showing optimized release behavior. Prepared MCs manifested effective and controlled release (up to 98%) following zero-order kinetics which was adequately explained by the Korseymer-Peppas model. The stability of the freeze-dried MCs was established in simulated gastrointestinal fluids (SGF, SIF) for 8 h. Antioxidant activity of the MCs was studied and revealed the retention of the functional architecture of β-carotene in freeze-dried MCs. Minimal photolytic degradation upon encapsulation of β-carotene addressed the challenge regarding photo-stability of β-carotene as confirmed via mass spectroscopy.     

Interaction of gum arabic, maltodextrin and pullulan with lipids in emulsions

The interaction of gum arabic, maltodextrin and pullulan with lipids in emulsion systems was investigated. Interfacial tension and interfacial viscosity measurements revealed that only gum arabic could adsorb and form a viscoelastic film at the oil-water interface. Good emulsifying activity was demonstrated for gum arabic, whereas fine emulsions could not be produced from the other polysaccharide solutions and oil. Frequency-dependent increases in the storage and loss moduli were observed for all the polysaccharide solutions. Such rheological behavior did not substantially change when maltodextrin and pullulan were mixed with oil to form emulsions. However, the frequency-dependence of the dynamic moduli disappeared in the gum arabic-stabilized emulsion, suggesting the formation of a network structure in which oil droplets could form junctions with gum arabic chains. The results on the inhibition of lipid oxidation by polysaccharides suggest that gum arabic protected lipids from the attack of lipoxygenase and free radicals by adsorbing at the oil droplet surface.     

Stability of cumin oleoresin microencapsulated in different combination of gum arabic, maltodextrin and modified starch

Microencapsulations of cumin oleoresin by spray drying using gum arabic, maltodextrin, and modified starch (HiCap^® 100) and their ternary blends as wall materials were studied for its encapsulation efficiency and stability under storage. The microcapsules were evaluated for the content and stability of volatiles, and total cuminaldehyde, γ-terpinene and p-cymene content for six weeks. Gum arabic offered greater protection than maltodextrin and modified starch, in general, although the order of protection offered was volatiles > cuminaldehyde > p-cymene > γ-terpinene. A 4/6:1/6:1/6 blend of gum arabic/maltodextrin/modified starch offered a protection, better than gum arabic as seen from the t_1/2, i.e. time required for a constituent to reduce to 50% of its initial value. However protective effect of ternary blend was not similar for the all the constituents, and followed an order of volatiles > p-cymene > cuminaldehyde > γ-terpinene.     

Emulsifying behaviour of gum arabic. Part 2: Effect of the gum molecular weight on the emulsion droplet-size distribution

The effect of the molecular weight of the gum arabic sample on droplet-size distributions of n-hexadecane-in-water emulsions (1% wt gum, 10% vol. oil) has been investigated at neutral pH. A high-molecular-weight fraction (0·87% nitrogen) corresponding to 10% of a natural gum (0·38% N) gives initially slightly larger droplets but better emulsion stability than the low-molecular-weight fraction (0·35% N) corresponding to the residual 90% of the original gum. Samples of a different gum arabic (0·35% N) subjected to different degrees of controlled degradation give decreasing emulsion stability with reduction in weight-average molecular weight from 3·1 × 10⁵ to 2·2 × 10⁵Da.     

Design and Evaluation of the Release Characteristics of Caffeine-Loaded Microcapsules in a Medicated Chewing Gum Formulation

The aim of this study was to microencapsulate caffeine by the emulsion technique, trying to control its release from a medicated chewing gum. Three formulations were prepared using alginate, alginate-starch, and alginate-starch with chitosan coating as the wall materials. These microcapsules were characterized with regard to the morphology studied by using an optical microscope and scanning electron microscopy (SEM), particle size, and encapsulation efficiency. The microcapsules were then incorporated into the chewing gums. The chewing gums were characterized by thermal behavior (by differential scanning calorimetry [DSC]), texture profile analysis [TPA], and sensory evaluation. Furthermore, the release of caffeine from the chewing gum was studied in vitro using the masticatory simulator and in vivo by a chew-out study. The microcapsules revealed a spherical form and high encapsulation efficiency, representing the success of the technique. The outcomes indicated that it is possible to encapsulate caffeine with the techniques employed and the microcapsules prolonged the release of caffeine throughout mastication. The chewing gum containing alginate-starch with chitosan-coated microcapsules showed the great potential of the microcapsule in controlling the release of the caffeine from the chewing gum, thereby delaying its bitterness.     

Reducing the microcapsule diameter by micro-emulsion to improve the insecticidal activity of Bacillus thuringiensis encapsulated formulations

The emulsion/internal gelation method is highly effective to produce microcapsules of Bacillus thuringiensis (Bt) in a short time; however, it has the limitation to produce microcapsules within a wide range of diameters (1–1000?µm). The aim of this study was to reduce the range of small microcapsule diameters by using a water/corn-oil (W/CO) micro-emulsion as the dispersing medium and the mixture Tween 80–Span 80 as the surfactant. It involved the development of the W/CO micro-emulsion and the determination of the suitable agitation time to disperse the gelling medium (sodium alginate) through the micro-emulsion. A micro-emulsion formulation that allowed reduction of the microcapsule diameter was composed of 82% corn oil, 12% alginate solution and 6% surfactant mixture Tween80–Span80 (31:69). Evaluation of four dispersing times showed that 45 min was suitable to produce 75% of microcapsules of an average diameter of 3.1?±?1?µm containing the spore–protein complex (SPC) produced by Bt. Bioassays carried out at low concentrations of microencapsulated formulations of cry proteins allowed determination of how its insecticidal effect increased if the range of microcapsule diameters was reduced in the range 1–9?µm. Furthermore, the SPC formulation in alginate microcapsules showed high resistance to extreme irradiation (2.9?±?0.5?×?10⁸ erg) of a long wavelength (365?nm), which made the microencapsulated formulation profitable and of high yield since repeated applications of the biopesticide during the same harvest period may not be necessary.     

Oxidation of linoleic acid encapsulated with soluble soybean polysaccharide by spray-drying

Linoleic acid was encapsulated with a soluble soybean polysaccharide, gum arabic, or a mixture of both together with maltodextrin, and the oxidation process of the encapsulated acid was measured at 37 degrees C and at a relative humidity of 12%. The soybean polysaccharide was more effective for encapsulating the acid and suppressing the oxidation of the encapsulated acid than gum arabic. A mixture of the soybean polysaccharide and maltodextrin was also effective for this purpose when the weight fraction of the polysaccharide was equal to or greater than 0.75.     

Emulsification using environmental compatible emulsifiers and de-emulsification using D.C. field and immobilized Nocardia amarae

As environmental compatible emulsifiers, various polysaccharides were investigated and de-emulsification methods were studied using filtration, direct current (D.C.) field, and also Nocardia amarae. 0.01% (v/v) of alginic acid, arabic gum, chitosan, and curdlan showed more than about 2 h of emulsion stability in the half-life of emulsion layer by a homogenizer and showed about twice synergic effects with other polysaccharides in emulsification activity at the ratio of 9:1 (v/v). De-emulsification by 110V D.C. field took about 1 h for the separation of oils from 1 l of oil-in-water emulsion in case of 0.01% arabic gum. Oil-water separator was designed using non-woven fabrics in filtration system and Nocardia amarae grown in n-hexadecane or kerosene was immobilized in the non-woven fabrics.     

Dispersion and oxidative stability of O/W emulsions and oxidation of microencapsulated oil

Oil-in-water (O/W) emulsions are among the dispersion systems commonly used in food, and these emulsions are in thermodynamically unstable or metastable states. In this paper, various methods for preparing O/W emulsions are outlined. Since the commodity value of food is impaired by the destabilization of O/W emulsions, experimental and theoretical approaches to assess the stability of O/W emulsions are overviewed, and factors affecting the dispersion stability of emulsions are discussed based on the DLVO theory and the concept of the stability factor. The oxidation of lipids in O/W emulsions is unhealthy and gives rise to unpleasant odors. Factors affecting the autoxidation of lipids are discussed, and theoretical models are used to demonstrate that a reduction of the oil droplet size suppresses or retards autoxidation. Microencapsulated lipids or oils exhibit distinct features in the oxidation process. Models that explain these features are described. It is demonstrated that a reduction in the oil droplet size is also effective for suppressing or retarding the oxidation of microencapsulated oils.     

Encapsulation of Biologically Active Proteins in a Multiple Emulsion

To improve the stability of IgY antibody in oral administration, encapsulation of IgY in a W/O/W emulsion was attempted. A stable W/O/W emulsion containing 1% IgY was prepared by using polyglyceryl condensed ricinolate (PGCR) and dextran-casein conjugate as the primary and secondary emulsifier, respectively. However, the activity of IgY antibody was reduced to less than 20% by encapsulation, suggesting that denaturation/inactivation of IgY had occurred at the oil/water interface. Adsorption of IgY to the inner water droplet surface was observed by electron microscopy. Rabbit IgG, α-amylase, and lysozyme also lost their activity after being encapsulated, although the rate of inactivation was lower than that of IgY. Molecular characterization of these proteins suggested that the rate of inactivation after encapsulation is likely to be dependent on the surface hydrophobicity and molecular stability of each protein.     

Stability of CoQ10-Loaded Oil-in-Water (O/W) Emulsion: Effect of Carrier Oil and Emulsifier Type

Co-enzyme Q10 (CoQ10), a lipophilic compound that widely used in the food and pharmaceutical products was formulated in a κ-carrageenan coated oil-in-water (O/W) emulsion. In this work, we examined the solubility of CoQ10 in different carrier oils and effects of emulsifier type on the formation and stability of CoQ10-loaded O/W emulsion. Nine vegetable oils and four types of emulsifiers were used. CoQ10 was found significantly (p?<?0.05) more soluble in medium chain oils (coconut oil and palm kernel oil) as compared to other vegetable oils. The O/W emulsions were then prepared with 10 % (w/w) coconut oil and palm kernel oil containing 200 g CoQ10/L oil stabilized by 1 % (w/v) emulsifiers (sucrose laurate (SEL), sodium stearoyl lactate (SSL), polyglycerol ester (PE), or Tween 80 (Tw 80)) in 1 % (w/v) κ-carrageenan aqueous solution. Particle size distribution and physical stability of the emulsions were monitored. The droplet sizes (surface weighted mean diameter, D[3,2]) of fresh O/W emulsion in the range of 2.79 to 5.83 μm were observed. Irrespective of the oil used, results indicated that complexes of SSL/κ-carrageenan provided the most stable CoQ10-loaded O/W emulsion with smaller and narrower particle size distribution. Both macroscopic and microscopic observations showed that O/W emulsion stabilized by SSL/κ-carrageenan is the only emulsion that exhibited no sign of coalescence, flocculation, and phase separation throughout the storage period observed.     

Lipid composition of liver microsomes in rats fed a high monounsaturated fatty acid diet

The fatty acid and cholesterol contents of tissue membranes are the determinants of membrane stability and functionality. This study was designed to evaluate the influence of a high monounsaturated fatty acid diet on the fatty acid composition of rat liver microsomes and on their cholesterol and lipid phosphorus content. Weanling animals were fed for 5 weeks with high fat diets containing olive oil or corn oil. Saturated fatty acids were increased and oleic acid decreased in microsomal total phospholipids and in the three major phosphoglycerides, phosphatidylcholine (PC), phosphatidylethanolamine (PE) and phosphatidylinositol (PI), of rats fed corn oil as compared to the olive oil group. The percentage of linoleic acid was higher in the corn oil group, but only for total phospholipids and PC. Linoleic and alpha-linolenic metabolites were significantly increased in total phospholipids of olive oil-fed animals with respect to those fed corn oil. These changes were responsible for the low unsaturation index found in microsomal phospholipids of the corn oil group. The diet did not affect the microsome cholesterol or the lipid phosphorus content. These results show that, in olive oil-fed rats, the cholesterol content and the degree of unsaturation of liver microsomes was similar to that observed in weanling animals; this probably suggests an adequate maintenance of functionality of membranes in olive oil-fed animals.     

Identification of Intestinal Bacteria Responsible for Fermentation of Gum Arabic in Pig Model

Acacia spp. produce gum exudates, traditionally called gum arabic or gum acacia, which are widely used in the food industry such as emulsifiers, adhesives, and stabilizers. The traditional gum arabic is highly variable with average molecular weights varying from 300,000–800,000. For this reason a standardized sample was used for the present experiments, based on a specific species of gum arabic (Acacia(sen)SUPER GUM^TM EM2). The literature indicates that gum arabic can be fermented by the intestinal bacteria to short chain fatty acid, particularly propionate. However, the bacteria responsible for the fermentation have not been determined. In this study, we used enrichment culture of pig cecal bacteria from the selected high molecular weight specific gum arabic of (M_W 1.77 × 10⁶). We found Prevotella ruminicola-like bacterium as a predominant bacterium that is most likely to be responsible for fermentation of the gum arabic used to propionate.     

Effects of carbon sources on extracellular lipase production and lipA transcription in Acinetobacter calcoaceticus

  The effects of lactic acid, oleic acid, gum arabic and their mutual interactions, on the production of extracellular lipase and the regulation of the expression of the lipase encoding gene (lipA) in Acinetobacter calcoaceticus were investigated. Formation of extracellular lipase was measured in culture supernatants of wild-type strain BD413 and expression of the lipA gene was monitored in vivo with a chromosomal fusion of lipA to lacZ. At the level of lipA expression only oleic acid had a significant effect; it lowered expression. Neither gum arabic nor lactic acid had any effect on lipA expression. On the other hand, the yield of extracellular lipase increased 2–5 times by the addition of gum arabic, possibly due to the release of cell surface-bound lipase. An interaction between oleic acid and lactic acid was also detected. Journal of Industrial Microbiology & Biotechnology (2000) 24, 25–30. Received 03 May 1999/ Accepted in revised form 04 September 1999     

Effect of olive oil on brain's lipid and calcium content after partial hepatectomy in mice

The aim of this study was to investigate the influence of olive oil (00) enriched diet on the lipid content of mice brain during the early phase of liver regeneration and to test a relationship of these changes with calcium content. C57BI mice were fed over 21 days with diet enriched with olive oil, containing predominantly oleic acid (18:1n-9). The animals were one-third partially hepatectomised (pHx) under aether anaesthesia. Total lipids were extracted from tissue samples with a chloroform-methanol (2:1, v/v) mixture according to Folch et al. Mineral concentration was determined by inductively coupled plasma atomic emission spectroscopy (ICP-AES) after microwave brain tissue digestion. The diet containing 00 increased both total lipid content and the calcium concentration in brain during the early phase of liver regeneration (12hrs post pHx), suggesting that monounsaturated oleic acid might interact with some metal-dependent activities that control changes in the brain during liver regeneration.     

Lipase-catalyzed hydrolysis of olive oil in chemically-modified AOT/isooctane reverse micelles in a hollow fiber membrane reactor

The hydrolysis of olive oil catalyzed by Candida rugosa lipase in sodium bis(2-ethylhexyl)sulfosuccinate (AOT)/isooctane and the synthetic sodium bis(2-ethylhexyl polyoxyethylene)sulfosuccinate (MAOT)/isooctane reverse micellar systems was investigated in a polysulfone hollow fiber membrane reactor with recycle of the reaction mixture. Lipase was completely retained by the membrane while olive oil and oleic acid freely passed through. The retention of reverse micelles depended on W ₀ (molar ratio of water to surfactant). At an olive oil concentration of 0.23 mol l^–1 the final substrate conversion in the MAOT micellar system was about 1.4 times of that in the AOT micellar system.     

Emulsifying behaviour of gum arabic. Part 1: Effect of the nature of the oil phase on the emulsion droplet-size distribution

The influence of the nature of the oil phase on the emulsifying behaviour of gum arabic has been investigated at neutral pH. Time-dependent droplet-size distributions are reported for oil-in-water emulsions (1% wt gum, 10% vol. oil) made with n-hexadecane, -limonene and orange oil. Three different gum samples of known analytical composition have been compared, and it is found that the gum giving the most rapid lowering of the tension at the n-hexadecane-water interface also gives the most stable n-hexadecane-in-water emulsions as well as the smallest droplets with all three oils. On the other hand, the same gum gives the poorest stability of the -limonene-in-water and orange oil-in-water emulsions.