Surface and interfacial properties of water-soluble wheat proteins

Surface and interfacial properties of water-soluble wheat proteins were investigated and compared with six reference proteins (bovine serum albumin, ovalbumin, β-lactoglobulin, trypsin, cytochrom C and β-amylase). Albumins extracted from wheat flour were separated by the free solution isoelectric focusing. The surface activity at the air/water, dodecane/water interfaces and dilatational rheological behaviour of the adsorbed layers was determined by pendant drop technique. Considerably high surface activity of wheat proteins was found at both interfaces exceeding the corresponding values of most of the reference proteins. Exceptionally, low dilatational moduli (typically  < 10 mN/m) were obtained for wheat fractions in the continuous and the stepwise compression experiments with no age effect (1–20 min) and almost no relaxation. Surface/interfacial activity and rheological properties observed imply that water-soluble wheat proteins are generally characterized by strong hydrophobicity and more flexible molecular structure than the reference proteins.     

Effect of protein aggregates on foaming properties of β-lactoglobulin

Our paper aims at determining the respective part of protein aggregates and non-aggregated proteins in the foam formation and stability of β-lactoglobulin. We report results on fractal aggregates formed at neutral pH and strong ionic strength (aggregates size from 30 to 190 nm). Pure aggregates and mixtures of non-aggregated/aggregated proteins at varying ratios were used. The capacity of aggregates to form and stabilize foams has been studied in relation with their ability to absorb at air/water interfaces. Our results show that protein aggregates are not able by themselves to improve the foaming properties but participate to a better foam stabilization in the presence of non-aggregated proteins. Non-aggregated proteins appear to be necessary to produce stable foams. We have shown that the amount and the size of aggregates had an influence on the drainage rate.     

Surface adsorption behaviour of milk whey protein and pectin mixtures under conditions of air-water interface saturation

Milk whey proteins (MWP) and pectins (Ps) are biopolymer ingredients commonly used in the manufacture of colloidal food products. Therefore, knowledge of the interfacial characteristics of these biopolymers and their mixtures is very important for the design of food dispersion formulations (foams and/or emulsions). In this paper, we examine the adsorption and surface dilatational behaviour of MWP/Ps systems under conditions in which biopolymers can saturate the air-water interface on their own. Experiments were performed at constant temperature (20 °C), pH 7 and ionic strength 0.05 M. Two MWP samples, β-lactoglobulin (β-LG) and whey protein concentrate (WPC), and two Ps samples, low-methoxyl pectin (LMP) and high-methoxyl pectin (HMP) were evaluated. The contribution of biopolymers (MWP and Ps) to the interfacial properties of mixed systems was evaluated on the basis of their individual surface molecular characteristics. Biopolymer bulk concentration capable of saturating the air-water interface was estimated from surface pressure isotherms. Under conditions of interfacial saturation, dynamic adsorption behaviour (surface pressure and dilatational rheological characteristics) of MWP/Ps systems was discussed from a kinetic point of view, in terms of molecular diffusion, penetration and configurational rearrangement at the air-water interface. The main adsorption mechanism in MWP/LMP mixtures might be the MWP interfacial segregation due to the thermodynamic incompatibility between MWP and LMP (synergistic mechanism); while the interfacial adsorption in MWP/HMP mixtures could be characterized by a competitive mechanism between MWP and HMP at the air-water interface (antagonistic mechanism). The magnitude of these phenomena could be closely related to differences in molecular composition and/or aggregation state of MWP (β-LG and WPC).     

Competitive adsorption between egg yolk lipoproteins and whey proteins on oil-in-water interfaces

Adsorption characteristics of mixtures of egg yolk lipoproteins and whey protein isolate (WPI) were studied in emulsions (20% oil, v/v 0.5% protein, w/v pH 7.0) made with pure triolein or n-tetradecane. Emulsions stabilized by granule lipoproteins (GLP) or low-density lipoproteins (LDL) had smaller particle sizes than emulsions stabilized by WPI. In protein mixtures containing egg yolk lipoproteins and WPI, there was a decrease in particle size with increased concentration of the yolk lipoproteins. The reduction in particle size of emulsions was greater when WPI was mixed with LDL than with GLP, for both n-tetradecane and triolein. Emulsions made with triolein had smaller particle sizes than those made with n-tetradecane, irrespective of the type or ratio of lipoproteins used. Therefore, the protein concentration per unit area of the interface was greater for emulsions containing n-tetradecane than for triolein. In displacement experiments, emulsions made with only WPI were mixed with 0.1 and 0.5% GLP or LDL for a given period of time and the relative concentrations of β-lactoglobulin and -lactalbumin determined. Displacement of β-lactoglobulin by LDL increased with time and was greater in emulsions made with n-tetradecane than with triolein. However, displacement of β-lactoglobulin by GLP was greater in emulsions made with triolein than with n-tetradecane. -lactalbumin was completely displaced from the interface within 1 min of addition of either 0.5% GLP or LDL, whereas addition of 0.1% GLP or LDL resulted only in a partial displacement. The results suggest that egg yolk lipoproteins are more surface active than WPI and that LDL penetrates the n-tetradecane–water interface more than GLP, while GLP penetrates the triolein–water interface more than LDL.     

Mechanical properties of protein adsorption layers at the air/water and oil/water interface: A comparison in light of the thermodynamical stability of proteins

Over the last decades numerous studies on the interfacial rheological response of protein adsorption layers have been published. The comparison of these studies and the retrieval of a common parameter to compare protein interfacial activity are hampered by the fact that different boundary conditions (e.g. physico-chemical, instrumental, interfacial) were used. In the present work we review previous studies and attempt a unifying approach for the comparison between bulk protein properties and their adsorption films. Among many common food grade proteins we chose bovine serum albumin, β-lactoglobulin and lysozyme for their difference in thermodynamic stability and studied their adsorption at the air/water and limonene/water interface. In order to achieve this we have i) systematically analyzed protein adsorption kinetics in terms of surface pressure rise using a drop profile analysis tensiometer and ii) we addressed the interfacial layer properties under shear stress using an interfacial shear rheometer under the same experimental conditions. We could show that thermodynamically less stable proteins adsorb generally faster and yield films with higher shear rheological properties at air/water interface. The same proteins showed an analog behavior when adsorbing at the limonene/water interface but at slower rates.     

The influence of the pore size, the foaming temperature and the viscosity of the continuous phase on the properties of foams produced by membrane foaming

Membrane foaming is a new method of foaming. To enlarge the knowledge about the influencing factors and to know how to vary the structure of the resulting foam, different factors were evaluated. A whey protein solution with 10% protein was foamed as a model solution by means of a tubular cross-flow filtration membrane. The pore size of the membrane was varied. The smaller the pore size, the smaller the bubbles produced. As a result, the foam firmness increases and less drainage was observed when smaller pore sizes were applied.

An important factor is that the added amount of gas must be stabilised as completely as possible in the foam. In order to achieve this, both the process and the product parameters were varied. Raising the foaming temperature increased the quantity of stabilised gas. The whey proteins then diffuse faster to the bubble surfaces and stabilise these by unfolding and networking reactions to prevent the coalescence of the bubbles.

The product parameter viscosity was found to influence the foaming result in such a way that up to a viscosity of 40 mPa s the incorporated gas bubbles are stabilised by the higher viscosity. At viscosities higher than 40 mPa s it is difficult to incorporate in the bubbles, and the foam structure becomes coarser due to increased coalescence at the pores of the membrane. The foam stability is enhanced with higher viscosities.     

Structure and physiochemical characteristics of whey protein isolate conjugated with xylose through Maillard reaction at different degrees

The purpose of this study is to prepare Maillard reaction products (MRPs) with both good emulsification and antioxidant activity, and the relationship between the Maillard reaction degree and structural changes of whey protein isolate (WPI) conjugated with xylose through wet-heating was explored. Browning intensity didn’t change while the free amino groups reduced significantly at the initial stage of Maillard reaction (MR). Amino acid analysis indicated that the lysine and arginine reduced significantly. The antioxidant property of the MRPs was significantly improved. The best emulsifying properties could be obtained in the middle degree of MR. The sodium dodecyl sulphate-polyacrylamide gel electrophoresis analysis illustrated that WPI and xylose formed high molecular weight conjugates. The circular dichroism spectra suggested that α-helix and random coil were increased while the β-sheet and β-turns were decreased after the MR. All of the MRPs exhibited a marked red shift in the maximum fluorescence intensity, indicating that the hydrophilicity of MRPs was enhanced.     

A comparative study of exogenous surfactant preparations and tracheal aspirate: interfacial tensiometry and properties of foam films

Surfactant replacement therapy has a vital role in the management of respiratory distress syndrome (RDS). Several techniques and models have been largely used to investigate interfacial physico-chemical properties in vitro and to assist clinical efficiency of exogenous surfactant preparations (ESPs) in vivo. Among them are interfacial tensiometry (Langmuir balance coupled with Wilhelmy plate method for surface tension measurement) and black foam film (BFF) method for measuring the capability of ESPs for bilayer foam film formation.

Here, we report some freshly established data from a comparative study of Exosurf, Survanta, Curosurf, Alveofact and clinical samples of tracheal aspirate (TA) of newborns with RDS treated with Curosurf. New observations concerning the properties of foam films of ESPs are also reported and discussed.

Measured interfacial physico-chemical parameters prove “better” properties in vitro of the SP-B and -C containing preparations Curosurf and Alveofact. Their properties are similar, Alveofact showing a higher surface tension lowering capacity under dynamic conditions.

A comparison with measured interfacial parameters of clinical samples shows that after treatment with Curosurf the phospholipid concentration in tracheal aspirates (367 μg/ml) is higher than the minimum phospholipid concentration for stable black film formation (C_t) of all four ESPs studied, while before treatment this concentration (63 μg/ml) is lower than C_t.

Values of measured “dynamic” parameters of clinical samples after treatment with Curosurf approach those of the exogenous surfactant preparation itself.     

Effect of alkaline materials on interfacial rheological properties of oil-water systems

Interfacial rheological properties of a model crude oil-water system were studied in the presence of sodium hydroxide. The interfacial viscosity, the non-Newtonian flow behavior and the activation energy of viscous flow were determined as a function of shear rate, alkali concentration and aging time. The fundamental conclusion of the experimental results is that the interfacial viscosity drastically decreases in the presence of alkaline materials and the change under favorable conditions may exceed 3 or 4 orders of magnitude. Simultaneously, the sodium hydroxide effectively suppresses the non-Newtonian flow behavior of the interfacial layer. The experimental observations are explained by simultaneous chemical processes taking place in the boundary layer. The present data may help to elucidate the formation, stability and breaking of alkali-containing oil-water emulsions and they provide additional information for better understanding of the displacement mechanism and for the formulation of alkaline flooding as a potential chemically enhanced oil-recovery method. Received: 6 April 1998 Accepted: 18 August 1998     

Implications of interfacial characteristics of food foaming agents in foam formulations

The manufacture of food dispersions (emulsions and foams) with specific quality attributes depends on the selection of the most appropriate raw materials and processing conditions. These dispersions being thermodynamically unstable require the use of emulsifiers (proteins, lipids, phospholipids, surfactants etc.). Emulsifiers typically coexist in the interfacial layer with specific functions in the processing and properties of the final product. The optimum use of emulsifiers depends on our knowledge of their interfacial physico-chemical characteristics - such as surface activity, amount adsorbed, structure, thickness, topography, ability to desorb (stability), lateral mobility, interactions between adsorbed molecules, ability to change conformation, interfacial rheological properties, etc. -, the kinetics of film formation and other associated physico-chemical properties at fluid interfaces. These monolayers constitute well defined systems for the analysis of food colloids at the micro- and nano-scale level, with several advantages for fundamental studies. In the present review we are concerned with the analysis of physico-chemical properties of emulsifier films at fluid interfaces in relation to foaming. Information about the above properties would be very helpful in the prediction of optimised formulations for food foams. We concluded that at surface pressures lower than that of monolayer saturation the foaming capacity is low, or even zero. A close relationship was observed between foaming capacity and the rate of diffusion of the foaming agent to the air-water interface. However, the foam stability correlates with the properties of the film at long-term adsorption.     

The rheology of lupin seed (Lupinus albus ssp. graecus) protein isolate films at the corn oil–water interface

Lupin seed protein isolates adsorbed at the corn oil–water interface formed, after long ageing times, interfacial films with viscoelastic properties. The viscoelastic parameters of the films, derived by analysis of creep compliance–time curves, were markedly influenced by the aqueous phase protein concentrations, pH, ageing time and isolate preparation methods. Instantaneous elastic modulus, E₀(s), showed maxima at a certain concentration which probably corresponded to monolayer saturation coverage and at pH 5.5, i.e. near to its isoelectric point, where the protein molecules are in a more compact form than at other pH values. The full fat lupin seed protein fractions gave the highest viscoelasticity values under all conditions and this in turn have an effect on the corresponding emulsion/foam stability.     

Simultaneous anion and cation exchange chromatography of whey proteins using a customizable mixed matrix membrane

Membrane chromatography can overcome some of the limitations of packed bed column chromatography but preparation of adsorptive membranes usually involves complex and harsh chemical modifications. Mixed matrix membranes (MMMs) require only the physical incorporation of an ion exchange resin into the membrane polymer solution prior to membrane casting. An advantage of MMMs not previously exploited is that resins with differing adsorptive functionalities can be conveniently embedded within a single membrane at any desired ratio. This presents the opportunity to customize an adsorptive membrane to suit the expected protein profile of a raw feed stream e.g. bovine whey or serum. In this work, a novel mixed mode interaction MMM customized to extract all major proteins from bovine whey was synthesized in a single membrane by incorporating 42.5 wt% Lewatit MP500 anionic resin and 7.5 wt% SP Sepharose cationic resin into an ethylene vinyl alcohol base polymer casting solution. The mixed mode MMM developed was able to bind both basic and acidic proteins simultaneously from whey, with binding capacities of 7.16±2.24 mg α-lactalbumin g(-1) membrane, 11.40±0.73 mg lactoferrin (LF)g(-1) membrane, 59.21±9.90 mg β-lactoglobulin g(-1) membrane and 6.79±1.11 mg immunoglobulin Gg(-1) membrane (85 mg total protein g(-1) membrane) during batch fractionation of LF-spiked whey. A 1000 m(2) spiral-wound membrane module (200 L membrane volume, 1m(3) module volume) is predicted to be able to produce approximately 25 kg total whey protein per h.     

Influence of whey protein denaturation on κ-carrageenan gelation

Response surface methodology was applied to study the effect of different heating temperature/time treatments on whey protein denaturation and its effect on κ-carrageenan gelation in milk. The path of gel formation was followed using small deformation rheology and the extent of whey protein denaturation was determined by gel permeation chromatography. κ-Carrageenan did not influence the rate of whey protein denaturation and it was unlikely that whey protein denaturation played a significant role on κ-carrageenan gelation in milk. In skim milk serum or skim milk ultrafiltrate the path of gel formation and gel strength were not influenced by the severity of heat treatment but increasing the concentration of whey proteins enhanced the gel strength. Heat treatment became important for carrageenan gelation in skim or recombined milks (i.e. in the presence of casein micelles) by influencing the gelation temperature and gel strength. Increasing the concentration of whey proteins in the recombined milks had a beneficial effect on gel strength.     

A differential microcalorimetric study of whey proteins and their behaviour in oil-in-water emulsions

Oil-in-water emulsions (20% soya oil, 1% protein) have been prepared containing lysozyme or isolates of -lactalbumin and β-lactoglobulin from whey protein. The structural characteristics of these proteins adsorbed at an oil/water interface were determined by following their thermal transitions using differential scanning microcalorimetry. Thermograms of the proteins in the adsorbed state differed markedly from the corresponding transitions seen for the proteins in solution. This suggests that the proteins underwent substantial changes in secondary and tertiary structure upon adsorption. In general, for all the proteins studied, a net decrease in the total energy absorbed during denaturation was found when the proteins were in an adsorbed state. Both lysozyme and -lactalbumin were in part “surface denatured”, and they showed a certain degree of reversibility between solution and the adsorbed state. β-Lactoglobulin showed the highest degree of denaturation upon adsorption and the conformational change was irreversible.     

Gelation of whey protein concentrate in the presence of partially hydrolyzed waxy maize starch and urea at pH 7.5

The effect of urea (50 and 100 g/l) and of partially hydrolyzed waxy maize starch (HWS, 100 and 150 g/l) on the heat-induced gelation of whey protein concentrate (WPC) at 100 g/l and pH 7.5 was investigated by small amplitude oscillatory measurements under heating to 80 °C and cooling to 25 °C, both treatments being followed by a stabilization period. Addition of urea contributed to the reduction of the values of the storage and loss moduli all over the heating/cooling treatment. On the contrary, addition of HWS alone led to higher moduli values. At the same HWS concentration, the increase of the moduli values was less pronounced when urea was present at 50 g/l. The microstructure of the systems was visualized by light microscopy at 25 °C, after the heating/cooling treatment. Addition of HWS affected the protein network in such a way that at 100 g/l, WPC/HWS mixed gels were visualized as a thick network with large pores, and at 150 g/l, the mixed gels were composed of denser strands with a larger number of smaller pores. However, when urea was also added to these mixed systems, homogeneous gels were imaged. Although leading to weaker gels, addition of urea seems to promote the compatibility of the two macromolecules.     

Effects of poly(ethylene oxide) and pH on the electrospinning of whey protein isolate

Poly(ethylene oxide) (PEO) is known for facilitating the electrospinning of biopolymer solutions, which are otherwise not electrospinnable. The objective of this study was to improve the understanding of the positive effects of PEO on the electrospinning of whey protein isolate (WPI) solutions under different pH conditions. Alterations in protein secondary structure and polymer solution properties (viscosity, conductivity, and dynamic surface tension), as induced by pH changes, significantly affected the electrospinning behavior of WPI/PEO (10% w/w: 0.4% w/w PEO) solutions. Acidic solutions resulted in smooth fibers (707 ± 105 nm) while neutral solutions produced spheres (2.0 ± 1.0 μm) linked with ultrafine fibers (138 ± 32 nm). In comparison, alkaline solutions produced fibers (191 ± 36 nm) that were embedded with spindle‐like beads (1.0 ± 0.5 μm). ¹³C NMR and FTIR spectroscopies showed that the increase in random coil and α‐helix secondary structures in WPI were the main contributors to the formation of bead‐less electrospun fibers. The electrospinning‐enabling properties of PEO on aqueous WPI solutions were attributed to physical chain entanglement between the two polymers, rather than specific polymer–polymer interactions. © 2012 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys, 2012     

Emulsifying properties of whey protein–dextran conjugates at low pH and different salt concentrations

The emulsifying behaviour of glyco-protein complexes of the non-ionic polysaccharide dextran (500 kDa) with whey protein isolate (WPI) have been investigated in systems containing (20 vol.% oil phase) medium-chain triglyceride oil, silicone oil, orange oil, and n-tetradecane under acidic and high electrolyte concentrations. Covalent coupling of protein to polysaccharide is achieved by dry heat treatment of protein+polysaccharide mixtures. Emulsions were made with WPI and whey protein isolate-dextran (WPI-DX) conjugate, and stability was followed by determining changes in average droplet size and extent of serum separation with time, with gum arabic (GA) chosen as reference emulsifier. The results show that the WPI-DX conjugate gives much better stability than the whey protein alone or GA under similar conditions. The improved emulsifying properties of WPI on complexing with dextran is probably due to the enhanced steric stabilization provided by the bulky hydrophilic polysaccharide moiety.     

Microencapsulation of dodecyl acetate by complex coacervation of whey protein with acacia gum and its release behavior

Complex coacervation of whey protein(WP) with acacia gum(AG) was carried out in water with the presence of dodecyl acetate (DA),a component of insect sex pheromones,in order to obtain microcapsules with DA as the core material and WP-AG coacervate as the wall materials.Through variations in wall/core ratios,concentrations of the wall materials in capsule preparations,DA encapsulation was optimized,which showed a high DA encapsulation was achieved when coacervation was conducted at pH 3.5 with wall/core mass ratio at 3 combined with concentration of wall materials at 1.0 wt%.Morphology and the structure of DA loaded microcapsules were examined by scanning electron microscope,which showed the microcapsules were of core/shell structure with DA encapsulated in the inner of the microcapsules.DA release was examined and the behavior of the release was discussed.     

Effect of surface character of filler particles on rheology of heat-set whey protein emulsion gels

Small-deformation and large-deformation rheological properties of heat-set whey protein emulsion gels containing active and inactive filler particles have been investigated using a controlled stress rheometer. The results suggest that the contributions to the gel network are quite different for pure protein gels and emulsion gels having similar storage moduli. An emulsion gel containing inactive filler has a larger phase angle due to the energy dissipation at the ‘slippery’ droplet surface under the influence of the applied shear stress. The large-deformation rheology of the heat-set protein gel has behaviour intermediate between that for an entropic biopolymer gel and that for a particle gel. Emulsion gels containing active or inactive fillers behave more like typical particle gel systems.