Double Emulsions Stabilized by Food Biopolymers

Double emulsions of the water-in-oil-in-water (W/O/W) type have application in the formulation of reduced-fat food products and as vehicles for encapsulation and delivery of nutrients during food digestion. Progress in the development of stable double emulsions for food use is dependent on replacing small-molecule emulsifiers and synthetic polymeric stabilizing agents by food-grade ingredients. Of particular value for conferring the required functionality are food proteins and polysaccharides. This review describes how these biopolymers have been successfully incorporated into the internal and external aqueous phases of W/O/W emulsions to improve the stability and yield of model systems. Recent advances in the use of protein–polysaccharide conjugates and complexes for the stabilization of the outer droplets of W/O/W emulsions are highlighted.     

Legume Protein Isolates for Stable Acidic Emulsions Prepared by Premix Membrane Emulsification

Proteins originating from dry legumes are not that much used in food formulations, yet, they are interesting components from a sustainability point of view, and could have interesting functional properties, e.g. for emulsion preparation. Therefore, this work focuses on the potential of the water soluble part of pea, chickpea and lentil protein isolates under acidic emulsions (pH 3.0) using a novel mild technique: premix membrane emulsification. Pea proteins (PP) and chickpea proteins (CP) lower the interfacial tension in the same way as whey protein isolate (WPI), which suggests that they could facilitate emulsion droplet formation similarly as WPI, while lentil proteins (LP) are slightly less effective. It is possible to make oil-in-water (O/W) emulsions with an average droplet diameter (d _4,3 ) of ~5 μm after 5 cycles in the premix system. The droplet size distribution of the emulsions remained constant during one day of storage, indicating that legume proteins are able to form and kinetically stabilize O/W emulsions. CP and PP exhibited emulsifying properties comparable to those of WPI, whereas LP is slightly less efficient, therewith indicating the great potential and that pea and chickpea protein isolates hold as emulsifiers in acidic food formulations.     

Biosurfactants: Production and application prospects in the food industry

There has been considerable interest in the use of biosurfactants due to the diversity of structures and the possibility of production from a variety of substrates. The potential for industrial applications has been growing, as these natural compounds are tolerant to common processing methods and can compete with synthetic surfactants with regards to the capacity to reduce surface and interfacial tensions as well as stabilise emulsions while offering the advantages of biodegradability and low toxicity. Among biosurfactant-producing microorganisms, some yeasts present no risks of toxicity or pathogenicity, making them ideal for use in food formulations. Indeed, the use of these biomolecules in foods has attracted industrial interest due to their properties as emulsifiers and stabilizers of emulsions. Studies have also demonstrated other valuable properties, such as antioxidant and antimicrobial activity, enabling the aggregation of greater value to products and the avoidance of contamination both during and after processing. All these characteristics allow biosurfactants to be used as additives and versatile ingredients for the processing of foods. The present review discusses the potential application of biosurfactants as emulsifying agents in food formulations, such as salad dressing, bread, cakes, cookies, and ice cream. The antioxidant, antimicrobial and anti-adhesive properties of these biomolecules are also discussed, demonstrating the need for further studies to make the use of the natural compounds viable in this expanding sector.     

Effects of Modification of Encapsulant Materials on the Susceptibility of Fish Oil Microcapsules to Lipolysis

The aim of the study was to assess the effects of modification of encapsulant materials before emulsion formation on the viscosity and interfacial properties of the emulsions and their influence on the susceptibility of emulsions to in vitro lipolysis. Emulsions (oil/protein ratio 2:1) were prepared by homogenizing mixtures containing fish oil and non-heated or heated (100 °C/120 min) dispersions comprising (a) sodium caseinate (NaCas), (b) mixtures of NaCas and a high amylose-resistant starch (Hylon VII; 1:1 mass ratio), and (c) mixtures of NaCas and previously modified resistant starch (heat/microfluidized [MF] Hylon VII; 1:1 mass ratio), followed by freeze drying. Reconstituted emulsion containing heated mixture of NaCas and heat/MF Hylon VII was the most viscous. The extent of lipolysis was the same in all emulsions stabilized by non-heated NaCas or non-heated mixtures of NaCas with resistant starch. Heat treatment of NaCas increased lipolysis of emulsions stabilized with protein alone, but heating NaCas with Hylon VII or heat/MF Hylon VII before emulsion formation reduced lipolysis. The emulsion stabilized with the heated NaCas–heat/MF Hylon VII mixture was the most resistant to lipolysis. Overall, the resistance to lipolysis was considered to be primarily dependent on the interfacial properties of the microcapsules. These findings of in vitro lipolysis of NaCas-resistant starch formulated oil powders may be relevant to an understanding of in vivo digestibility of the oil powders. The insights may be used as a guide to formulate oil systems for altering the susceptibility to lipolysis of ingested oil emulsions. Delivery of Functionality in Complex Food Systems: Physically inspired Approaches from Nanoscale to Microscale, University of Massachusetts, Amherst, MA, USA, 8th–10th October 2007.     

Whey Protein/Polysaccharide-Stabilized Emulsions: Effect of Polymer Type and pH on Release and Topical Delivery of Salicylic Acid

Emulsions are widely used as topical formulations in the pharmaceutical and cosmetic industries. They are thermodynamically unstable and require emulsifiers for stabilization. Studies have indicated that emulsifiers could affect topical delivery of actives, and this study was therefore designed to investigate the effects of different polymers, applied as emulsifiers, as well as the effects of pH on the release and topical delivery of the active. O/w emulsions were prepared by the layer-by-layer technique, with whey protein forming the first layer around the oil droplets, while either chitosan or carrageenan was subsequently adsorbed to the protein at the interface. Additionally, the emulsions were prepared at three different pH values to introduce different charges to the polymers. The active ingredient, salicylic acid, was incorporated into the oil phase of the emulsions. Physical characterization of the resulting formulations, i.e., droplet size, zeta potential, stability, and turbidity in the water phase, was performed. Release studies were conducted, after which skin absorption studies were performed on the five most stable emulsions, by using Franz type diffusion cells and utilizing human, abdominal skin membranes. It was found that an increase in emulsion droplet charge could negatively affect the release of salicylic acid from these formulations. Contrary, positively charged emulsion droplets were found to enhance dermal and transdermal delivery of salicylic acid from emulsions. It was hypothesized that electrostatic complex formation between the emulsifier and salicylic acid could affect its release, whereas electrostatic interaction between the emulsion droplets and skin could influence dermal/transdermal delivery of the active.     

Emulsifier Dependent <Emphasis Type="Italic">in vitro</Emphasis> Digestion and Bioaccessibility of β-Carotene Loaded in Oil-in-Water Emulsions

This study was performed to examine the effect of emulsifiers used to coat emulsion droplets containing β-carotene on the behavior of lipid digestion and bioaccessibility. Different emulsifiers (whey protein isolate, soy protein isolate, sodium caseinate, Tween 20, and soy lecithin) were used to prepare emulsions with similar sized droplets (200–400 nm). Protein-stabilized emulsions showed a similar behavior of digestion, and morphological change in the simulated gastrointestinal conditions. Soy lecithin-stabilized emulsions showed the lowest rate and extent of lipid digestion probably due to the low emulsifying capability of soy lecithin, showing coalesced droplets occurring after exposure to the gastric phase. Tween 20-stabilized emulsions had a lower rate and extent of lipid digestion than that of protein-stabilized emulsions, even though Tween 20-stabilized emulsions had a more stable structure to resistant to aggregation in gastric phase. Even though the difference in the digestion rate and extent, β-carotene bioaccessibility was not significantly different among emulsions stabilized by different emulsifiers at p?<?0.05.     

Chemical modification of enzymes for enhanced functionality.

The explosion in commercial and synthetic applications of enzymes has stimulated much of the interest in enhancing enzyme functionality and stability. Covalent chemical modification, the original method available for altering protein properties, has now re-emerged as a powerful complementary approach to site-directed mutagenesis and directed evolution for tailoring proteins and enzymes. Glutaraldehyde crosslinking of enzyme crystals and polyethylene glycol (PEG) modification of enzyme surface amino groups are practical methods to enhance biocatalyst stability. Whereas crosslinking of enzyme crystals generates easily recoverable insoluble biocatalysts, PEGylation increases solubility in organic solvents. Chemical modification has been exploited for the incorporation of cofactors onto protein templates and for atom replacement in order to generate new functionality, such as the conversion of a hydrolase into a peroxidase. Despite the breadth of applicability of chemically modified enzymes, a difficulty that has previously impeded their implementation is the lack of chemo- or regio-specificity of chemical modifications, which can yield heterogeneous and irreproducible product mixtures. This challenge has recently been addressed by the introduction of a unique position for modification by a site-directed mutation that can subsequently be chemically modified to introduce an unnatural amino acid sidechain in a highly chemo- and regio-specific manner.     

Impact of Electrostatic Interactions on Lecithin-Stabilized Model O/W Emulsions

Natural emulsifiers, particularly those extracted from plants, are highly wanted by food industry to meet consumers demand for clean label food and beverage products. The potential utilization of soy lecithin as an emulsifier in model coffee creamer was investigated in this study. The model oil-in-water (O/W) emulsions consisted of 10 wt% medium chain triglyceride were stabilized using either 1% or 5% soy lecithin (pH 7.0). The O/W emulsions were of whitish milky color (L*?=?88–92) and were able to whiten black coffee solutions (L* from 5.5 for black coffee to 44–56 for white coffees). Model O/W emulsions with smaller mean droplet diameters (0.11 to 1.09 μm), higher surface potentials (ζ?=??62 to ?72 mV), and better stabilities in hot coffee were fabricated using higher lecithin levels because there was more emulsifier to coat the oil droplet surfaces. Alteration of the electrostatic interactions in the model O/W emulsions (5% lecithin) by pH adjustment or calcium addition led to droplet aggregation under certain conditions, which was attributed to charge reduction by protonation of lecithin head groups and electrostatic screening by counter-ion accumulation and ion-binding. In particular, phase separation of the model creamer occurred at pH value around 4.5 when the system was acidified at a slow rate. Overall, this study suggests that lecithin-stabilized O/W emulsions may become unstable in coffee solutions with high acidity or calcium levels. The information obtained from this study provides insights on the use of plant-based emulsifiers in commercial food and beverage systems.     

Partitioning Behavior and Interfacial Activity of Phenolic Acid Derivatives and their Impact on β-Lactoglobulin at the Oil-Water Interface

Food Biophysics - Proteins are able to stabilize dispersed food systems due to their amphiphilic nature, acting as emulsifiers. Their interfacial properties can be influenced by different methods,...     

Effect of Tween Emulsifiers on the Shear Stability of Partially Crystalline Oil-in-Water Emulsions Stabilized By Sodium Caseinate

We investigated the effects of Tween emulsifier fatty acid chain length on the shear stability and crystallization behavior of 35 wt% partially crystalline oil-in-water emulsions prepared with and without 1 wt% sodium caseinate. Emulsions containing sodium caseinate and Tween 20, 40, 60 or 80 varied in shear stability, degree of supercooling and crystallization behavior depending on the type and concentration of Tween as well as the presence of protein. Generally, emulsions containing the unsaturated emulsifier Tween 80 were the most shear sensitive followed by the saturated emulsifiers Tween 20, 40 and 60 in order of increasing fatty acid chain length. Long chain saturated Tween emulsifiers (40 and 60) improved shear stability regardless of whether sodium caseinate was present indicating that alone, these emulsifiers form more robust interfacial films compared to the saturated short chain length Tween 20 and Tween 80. In emulsions prepared with sodium caseinate, the degree of supercooling decreased and the crystallization rate diminished with increasing saturated fatty acid chain length but only negligible changes were found without sodium caseinate. Together, these findings indicate that long chain saturated Tween emulsifiers provide better emulsion stability regardless of the presence of sodium caseinate but with sodium caseinate, stability may also be affected by changes to fat crystallization. These novel findings provide guidance on how combinations of proteins and emulsifiers can be used to modify and control the stability of partially crystalline oil-in-water emulsions through their combined effects on the properties of the interfacial film and fat crystallization.     

Stability of the oil-in-water type triacylglycerol emulsions

Lipid emulsions with saturated triacylglycerols (TAGs) with 4 to 10 carbons in each acyl chain were prepared to study how the oil component alters the stability of the lipid emulsions when phosphatidylcholines were used as emulsifiers. The average droplet size of the emulsions became smaller as the chain length of the TAG increased. For a given oil, emulsion with smaller droplets was formed with an emulsifier having higher HLB value. The influence of HLB values on the droplet size was biggest for the tributyrin (C4) emulsions. For the tricaprylin (C8) emulsions, droplet size was identical at given emulsifier concentrations regardless of HLB values. The HLB value and the concentration of the emulsifiers also affect the droplet size of the emulsions. The emulsions with smaller average droplet size were more stable than with bigger size for 20 days. The oil and water (o/w) interfacial tension is inversely proportional to the initial droplet size of the emulsion.     

Apolipoprotein effects on the lipolysis of perfused triglyceride by heparin-immobilized milk lipase

Bovine milk lipase was noncovalently bound to a heparin-Sepharose support and a [3H]glycerol/[14C]triolein emulsion was circulated through it. This system, more closely simulating in vivo conditions than the standard lipoprotein lipase assay, was employed to determine the effect of human apo-E and apo-C-II on the lipolysis of the circulating substrate. Both apo-C-II and apo-E produced enhanced lipolysis in comparison to unsupplemented emulsions, at appropriate enzyme densities on the heparin-Sepharose. With high enzyme densities the stimulation produced by apo-E was lost but that of apo-C-II persisted. When apo-E and apo-C-II were added together they produced significantly more lipolysis than when either was added separately. The enhancement of lipolysis produced by apo-E was correlated with the increased binding of triglyceride to the heparin-Sepharose enzyme complex. The effect of additions of both apoproteins to rat intestinal chylomicrons resulted in data quite similar to the triglyceride emulsions. Heparin-Sepharose columns with high and low zones of enzyme density produced greater lipolysis than when the enzyme was distributed more uniformly throughout the column. Perfusions of substrate supplemented with sufficient apo-E to produce maximal binding and lipolysis resulted in a progressive elution of the triglyceride substrate from the column during the perfusion. Free fatty acid:albumin molar ratios greater than 2 resulted in desorption of substrate from the column. This suggests the possibility of regulation of the lipolytic process by the products of lipolysis.     

A Relationship between Papaincatalyzed Aminolysis of Ethyl Hippurate by Amino Acid Esters and Their Incorporation into Ovalbumin Hydrolysate during the Plastein Reaction

The effects of the colloidal properties of emulsion particles and the conformation of tryptic digests of soybean glycinin, the emulsifiers, on emulsion properties were investigated. The digests were separated into some fractions, and the properties of intact glycinin, two kinds of the best were examined. The diameter of the emulsion particles measured by spectroturbidimetry was not very different among the best emulsifiers and intact glycinin in spite of the difference in emulsifying ability; however, a new parameter, flocculation strength, which is the rigidity of the flocculated structure and is defined as the minimum detergent concentration for the dissociation of flocculation, closely and negatively related to the short term emulsion stability. The amount of adsorbed protein on the surface of the emulsion particles was also related to the long term emulsion stability. The two best emulsifiers were analyzed by gel filtration and circular dichroism. The emulsifiers contained large molecular components whose molecular weight and secondary structures were similar to intact glycinin. The conformational stability of the emulsifiers was evaluated by the change in emission maxima of the intrinsic fluorescence of the proteins against changing urea concentration, and the surface hydrophobicity of the proteins was estimated by the binding of l-anilino-8-naphthalene sulfonate (ANS). The emulsion stability increased with decreasing conformational stability and increasing surface hydrophobicity of the emulsifier proteins.     

The Influence of Emulsion Droplet Interactions on the Structural,Material and Functional Properties of a Model Mozzarella Cheese

We present findings on the influence of interfacial layer composition on the colloidal interactions and associated structural and material properties of oil-in-protein gel emulsions, as applied to a model Mozzarella cheese analogue. Model cheese samples were produced through thermal mixing of pre-prepared oil-in-water emulsions with a renneted casein gel. Sodium caseinate and Tween 20 were used as the emulsifiers. Microstructural analysis showed sodium caseinate stabilised droplets to be homogeneously dispersed within the cheese structure, whilst droplets stabilised by Tween 20 were phase concentrated into localised fat domains within the continuous protein network. Particle size measurements determined that, on chilled storage, the droplets in these localised regions underwent extensive partial coalescence, whilst the homogenously distributed caseinate droplets showed little change in droplet size. Small deformation rheology (4 to 80 °C) determined the sodium caseinate emulsion as providing a reinforcing effect on the protein network across the entire temperature range, while the Tween 20 emulsion was observed to mechanically strengthen the cheese structure at only at temperatures for which the fat phase was solid whilst serving to weaken the structure on transitioning to a molten state. Differences in droplet structure and stability were determined as influencing cheese melt and flow characteristics. During melting, no oiling-off observed for cheese samples comprising sodium caseinate stabilised droplets, compared to Tween 20 stabilised emulsions where extensive oiling-off was observed. Findings corroborate the hypothesis that caseinate coated droplets behave as active fillers within the protein network, whilst the Tween 20 stabilised emulsion are non-interactive.     

Formation and Stability of ω-3 Oil Emulsion-Based Delivery Systems Using Plant Proteins as Emulsifiers: Lentil,Pea, and Faba Bean Proteins

Many sectors of the food industry are interested in replacing synthetic or animal-based ingredients with plant-based alternatives to create products that are more natural, environmentally friendly, and sustainable. In this study, the ability of several plant protein concentrates to act as natural emulsifiers in oil-in-water emulsions fortified with omega-3 fatty acids was investigated. The impact of emulsifier type on the formation and stability of the emulsions was determined by measuring changes in droplet characteristics (size and charge) under different homogenization, pH, salt, and temperature conditions. Pea (Pisum sativum), lentil (Lens culinaris) and faba bean (Vicia faba) protein concentrates all proved to be effective emulsifiers for forming and stabilizing 10 wt% algae oil-in-water emulsions produced by high-pressure homogenization. The droplet size decreased with increasing emulsifier concentration, and relatively small oil droplets (d < 0.3 μm) could be formed at higher emulsifier levels (5% protein). Lentil protein-coated droplets were the most stable to environmental stresses such as pH, ionic strength and temperature changes. These results have important implications for the production of functional foods and beverages from natural plant-based ingredients.     

Phylogenetic characterization of bioemulsifier-producing bacteria

Bacteria able to produce biological emulsifiers were isolated from different environments using different isolation media with the aim of discovering the widest diversity. The phylogenetic diversity of the isolates was evaluated by 16S rRNA gene analysis. Among 190 isolated strains, 127 released extracellular emulsifiers able to stabilize oil-water emulsions when grown on low-cost substrates. Among these, the 35 isolates that showed the highest emulsifier production on different substrates were found to belong to 16 different bacterial genera. Overall, this is the first systematic study of the diversity of bioemulsifier-producing bacteria and of their ability to produce bioemulsifiers on low-cost substrates.     

Design and characterization of enzymosomes with surface-exposed superoxide dismutase

Superoxide dismutase (SOD) was chemically modified by covalent linkage of fatty acid chains to the accessible epsilon-amino groups of the enzyme. This acylation method gave rise to a different enzyme entity (Ac-SOD) as evidenced by different physicochemical properties such as octanol/water partition coefficient and isoelectric point (pI) as compared to SOD. Ac-SOD was incorporated in conventional and long-circulating liposomes (LCL) and characterized in terms of incorporation efficiency, protein to lipid ratio (Prot/Lip), enzymatic activity retention and zeta potential. The observation that Ac-SOD liposomes present enzymatic activity on their external surface indicates that these formulations can act independent of rate and extent of enzyme release as required in case of SOD liposomes. The decrease of superficial charge of liposomal formulations containing Ac-SOD, as compared to SOD liposomes, may be related to the negatively charged enzyme molecules localized on the liposome surface. The comparative characterization of Ac-SOD and SOD liposomal formulations evidenced that the two enzyme forms differ substantially regarding their intraliposomal location: SOD tends to be localized in the internal aqueous spaces, whereas Ac-SOD is expected to be localized in the lipid bilayers of the liposomes, partially buried into the outer surface and exposed to the external medium. These liposomal structures with surface-exposed SOD were designated as Ac-SOD enzymosomes. The properties of these enzymosomes may influence the therapeutic effect, as the release of the enzyme from extravasated vesicles is no longer a necessary requirement for achieving dismutating activity within the inflamed target site.     

Dielectric Properties of Water-liquid Paraffin Emulsion Systems at the Microwave Frequency of 9.4 GHz

The state of water contained in emulsions, particularly in o/w emulsions, was studied as a model of water orientation at the peripheries of biomembranes. Dielectric measurements made at microwave frequency on emulsions containing water and liquid paraffin in various ratios with emulsifiers revealed that the o/w emulsions possessed considerably reduced dielectric loss as compared with theoretical values obtained in accordance with the Maxwell-Wagner model, while the dielectric properties of w/o emulsion were in good agreement with the theoretically expected values. The observations seem to be explained by assuming changes in the state of water in the oil-water interfacial layer in o/w emulsions. The preparation of stable emulsions for use in this study is also discussed.