Effects of fluid shear and temperature on whey protein gels, pure or mixed with xanthan

The effects of shear on whey protein isolate (WPI) gels, pure or mixed with xanthan, have been investigated at pH 5.4 by dynamic oscillatory measurements and light microscopy (LM). The shear was performed on the suspensions under a constant stress of between 0.04 and 2.1 Pa. Various temperature conditions were chosen in order to describe the effects of shear at the different states of aggregation of the WPI. Shear-sensitive aggregation phenomena were already found around 40°C for the pure WPI samples. Continuous shearing during heating from 20 to 40°C, prior to heat treatment at 90°C, resulted in a gel with a storage modulus (G′) half that of the unsheared gel, independent of the shear stress. Continuous shearing during heating from 20 to 76°C resulted in a further decrease in G′. Inhomogeneities arose in networks formed from continuously sheared suspensions during heating from 20 to 50°C and above. Depending on the shear stress and on the heating range of the shear, the networks showed areas of varied compactness and different classes of pores, ranging from 10 to 200 μm. A higher G′, compared to that for the unsheared gel, was found for gels subjected to shear for short periods in the vicinity of the gel point. The presence of xanthan inhibited the aggregation and demixing of the WPI, described as a sterical phenomenon. Under static conditions, the presence of xanthan resulted in a more homogeneous WPI network. Exposing the mixed suspensions to shear generally increased the inhomogeneity of the network structure. Short periods of shearing in the vicinity of the gel point affected the kinetics of the gel formation and resulted in gels with higher G′ values than the unsheared gel. Continuous shearing under stresses below 0.09 Pa, during heating from 20 to 60°C and above, also resulted in gels with an increased G′. Continuous shear under stresses above 0.9 Pa resulted in gels with a decreased G′     

Characterisation of low-fat high-dietary fibre frankfurters

Two different peach dietary fibre (DF) suspensions (17 and 29%) were used to obtain low-fat high-DF frankfurters (20-5% fat) which were compared to an all-meat control (25% fat). The viscosity of the meat batters increased with DF content. The protein (11.5±0.6%) and collagen (1.4±0.1%) contents of frankfurters were not affected by DF addition, and the higher the DF content, the lower the pH (6.4 to 5.8) due to the fibre solution acidity. The DF was effective in retaining added water in low-fat frankfurters since their cooking losses were similar to those of the controls (5.5±0.1%). Low-fat frankfurters were darker and browner than the controls and only high fibre addition significantly decreased the textural parameters. Sensory evaluation indicated that low fat-high DF frankfurters (20, 15 and 10% fat) were as acceptable as the all-meat frankfurters.     

Zinc incorporation capacity of whey protein nanoparticles prepared with desolvation with ethanol

Whey protein isolate (WPI) nanoparticles were prepared using ethanol desolvation, and their capacity to incorporate ZnCl(2) was analysed. Desolvation was carried out at pH 9 and the volume of added ethanol was 0-3 times the volume of protein solution. The desolvated solutions were dispersed in acidified water (pH 3) immediately after desolvation. The size of the WPI nanoparticles increased with the volume ratio of ethanol:water used, as well as with the amount of ZnCl(2). The nanoparticles showed high incorporation efficiencies, and remained stable after 30 days of storage at 22 °C. The amount of zinc incorporated in the WPI particle suspensions was within the range of daily zinc requirements for healthy adults.     

Ca2+-Induced Gelation of Pre-heated Whey Protein Isolate

Addition of CaCl₂ to pre-heated whey protein isolate (WPI) suspensions caused an increase in turbidity when pre-heating temperatures were ≥ 64°C. Pre-heating to ≥ 70°C was required for gelation. WPI suspensions which contained CaCl₂ became turbid at 45°C and formed thermally induced gels at 66°C. Thermally and Ca²⁺-induced gels showed significant time/temperature effects but the penetration force values in the Ca²⁺-induced gels were always lower. However, Ca²⁺-induced gels were higher in shear stress at fracture. The Ca²⁺-induced gels had a fine-stranded protein matrix that was more transparent than the thermally induced gels, which showed a particulate microstructure.     

具有“核壳”结构的乳清分离蛋白-黄原胶复合颗粒的构建

采用乳清分离蛋白（whey protein isolate,WPI）和阴离子多糖黄原胶（xanthan gum,XG）作为基础原料制备复合颗粒,通过改变离子强度、温度、混合方式等条件,对WPI-XG复合体系浊度、粒径、Zeta电位进行分析,探究影响复合颗粒形成的主要因素,并通过激光共聚焦显微镜观察颗粒的结构。结果表明：低离子强度（≤20 mmol/L）可促进WPI-XG复合物的形成;温度越高,复合颗粒的粒径越大;先单独热处理WPI溶液后再与XG溶液混匀制得的颗粒具有更大的蛋白质多糖比、更小的粒径和更大的电位绝对值;剪切会使颗粒的粒径和电位绝对值下降。最终根据浊度、粒径、电位和共聚焦显微镜的结果,得出剪切后的75 ℃热处理WPI颗粒与XG复合形成更为完整的“核壳”结构。     

Influence of shearing on the physical characteristics and rheological behaviour of an aqueous whey protein isolate–κappa-carrageenan mixture

The incompatibility of whey protein isolate (WPI) and κappa-carrageenan (κ-car) in aqueous mixtures has been extensively studied under quiescent conditions; however, the effect of shear on segregative phase separation is still not fully understood. The present work reports for the first time quantitatively the effect of shearing on the segregative phase separation behaviour of these two polymers. Demixing was observed at pH 7.0 and 22 °C, determining the phase diagram and rheological properties of the mixtures. Phase diagrams were derived after heating and cooling mixes at a constant shear rate (28 s⁻¹). The phase behaviour was compared to that of the same mixtures under quiescent conditions. The shearing process affects segregative phase separation, causing a shift in the position of the binodal towards lower concentrations of WPI. The bottom layer contained a higher ratio of WPI while the upper layer was enriched in κ-car. The addition of κ-car to WPI solutions led to a much stiffer heat-induced gel than that prepared with WPI heated in isolation. The height of the plateau of the final elastic modulus G′_∞(t) depends on the position of the system on the phase diagram. Using a selected tie line, the viscosity of different systems measured at 80 °C was more influenced by the amount of WPI, than by the κ-car concentration. Shear treatment of segregative phase separating systems offer a way to modulate the functional properties of the ingredients and the texture of the final product.     

Factors Influencing Whey Protein Gel Rheology: Dialysis and Calcium Chelation

Influence of dialyzable compounds on the Theological properties (shear stress and shear strain at failure) of heat-induced whey protein concentrate (WPC) and whey protein isolate (WPI) gels was examined. Dialyzing WPC and WPI suspensions prior to gelation increased the stress of two of three WPC gels and a WPI gel. Dialysis also significantly increased the strain of the same two WPC gels, normalizing all strain values. Replacement of calcium lost through dialysis did not significantly change gel rheology. However, chelating calcium caused a significant decrease in the stress of all gels: a minimum amount of calcium and/or a calcium complex appears to have a major role in whey protein gelation.     

Modulation of rheological properties by heat-induced aggregation of whey protein solution

Heat-induced protein aggregation at low protein concentrations generally leads to higher viscosities. We here report that aggregated protein can yield weaker gels than those from native protein at the same concentration. Aggregated protein was produced by heating a solution of whey protein isolate (WPI) at 3% and 9% w/w. The higher protein concentration resulted in a larger aggregate size and a higher intrinsic viscosity. The protein fraction in native WPI had the smallest size and the lowest intrinsic viscosity. The same trend was observed for the shear viscosity after concentrating the suspensions containing aggregates to around 15% w/w. Suspensions containing aggregates that were produced from a higher concentration possessed a higher viscosity. After reheating the concentrated suspensions, the suspension from the 9% w/w aggregate system produced the weakest gel, followed by the one from 3% w/w, while the native WPI yielded the strongest gel. Reactivity of the aggregates was also an important factor that influenced the resulting gel properties. We conclude that aggregation of whey protein solution is a feasible route to manipulate the gel strength of concentrated protein systems, without having to alter the concentration of the protein.     

CORN GERM PROTEIN IN FRANKFURTERS: TEXTURAL,COLOR, AND SENSORY CHARACTERISTICS AND STORAGE STABILITY1

Textural properties, water holding capacity, color, sensory characteristics, and storage stability of frankfurters containing hexane-defatted corn germ protein (CGP) as a meat extender were studied. CGP was incorporated at 2 and 3% levels as a powder or a preswelled slurry. Batter viscosity and shear force values of frankfurters were increased by the preswelled CGP. The redness values of the experimental samples with 2 and 3% CGP added as a powder were less than those of controls. There were no significant effects of CGP incorporation or its preswelling on the initial sensory properties of frankfurters. Meaty flavor and aroma and off-flavor acceptability decreased during 45 days of storage. Off-flavor and off-aroma of frankfurters showed a slight increase with time in storage. Total volatile nitrogen and nonammonia amino nitrogen of experimental and control frankfurters were not significantly different.     

Evaluation of Antibacterial Activity of Whey Protein Isolate Coating Incorporated with Nisin,Grape Seed Extract,Malic Acid,and EDTA on a Turkey Frankfurter System

ABSTRACT: The effectiveness of whey protein isolate (WPI) coatings incorporated with grape seed extract (GSE), nisin (N), malic acid (MA), and ethylenediamine tetraacetic acid (EDTA) and their combinations to inhibit the growth of Listeria monocytogenes, E. coli O157:H7, and Salmonella typhimurium were evaluated in a turkey frankfurter system through surface inoculation (approximately 10⁶ CFU/g) of pathogens. The inoculated frankfurters were dipped into WPI film forming solutions both with and without the addition of antimicrobial agents (GSE, MA, or N and EDTA, or combinations). Samples were stored at 4 °C for 28 d. The L. monocytogenes population (5.5 log/g) decreased to 2.3 log/g after 28 d at 4 °C in the samples containing nisin (6000 IU/g) combined with GSE (0.5%) and MA (1.0%). The S. typhimurium population (6.0 log/g) was decreased to approximately 1 log cycles after 28 d at 4 °C in the samples coated with WPI containing a combination of N, MA, GSE, and EDTA. The E. coli O157:H7 population (6.15 log/g) was decreased by 4.6 log cycles after 28 d in samples containing WPI coating incorporated with N, MA, and EDTA. These findings demonstrated that the use of an edible film coating containing nisin, organic acids, and natural extracts is a promising means of controlling the growth and recontamination of L. monocytogenes, S. typhimurium, and E. coli O157:H7 in ready‐to‐eat poultry products.     

应用流变模型分析乳清分离蛋白-果胶复配体的微观结构

通过对几种流变模型(剪切-黏度模型)的分析比较,配合使用透射电镜(TEM)的方法,在pH值中性并且不加入盐的条件下研究乳清分离蛋白(WPI)、果胶以及两者复合体的微观结构。流变模型主要为Cross模型、Carreau模型及其衍变形式。结果表明：在剪切速率为0.09～600s-1、温度80℃、溶液质量分数分别为WPI 5%、果胶0.8%、5%WPI-0.8%果胶复合物的条件下,发现WPI和果胶溶液表现出牛顿流体特性,与Carreau衍变模型相符合,而它们的混合物表现出切稀特性,与Carreau模型相符合。     

QUALITY AND STORAGE STABILITY OF FRANKFURTERS CONTAINING 15% MECHANICALLY DEBONDED TURKEY MEAT

SUMMARY –Fresh and frozen stored mechanically deboned turkey meat was incorporated into frankfurters at the 15% level and compard to red meat frankfurters. Mechanically deboned turkey meat exhibited higher emulsifying capacity than beef but lower than pork on a protein basis. This trend for emulsifying capacity was reversed when reported on a total meat basis. Emulsion stability was not essentially affected by the addition of 15% mechanically deboned turkey meat in red meat frankfurters. Differences flavor tests, preference flavor tests, and TBA values indicated that frankfurters containing 15% mechanically deboned turkey meat were comparable to all red meat frankfurters in flavor stability if fresh deboned poultry meat is used. The use of mechanically deboned poultry meat, which had undergone 90 days of frozen storage, resulted in a significantly inferior product as indicated by flavor evaluation and TBA values. Color evaluation showed slight color fading of all frankfurter treatments during storage. Microbial loads in the three frankfurther treatments showed some increased in total counts during refrigerated storage.     

Rheological,thermal and microstructural properties of whey protein isolate‐modified cassava starch mixed gels at different pH values

The objective of this study was to investigate the rheological, thermal and microstructural properties of whey protein isolate (WPI)‐hydroxypropylated cassava starch (HPCS) gels and WPI‐cross‐linked cassava starch (CLCS) gels at different pH values (5.75, 7.00 and 9.00). The rheological results showed that the WPI‐modified starch gels had greater storage modulus (G?) values than the WPI‐native cassava starch gels at pH 5.75 and 7.00. Differential scanning calorimetry curves suggested that the phase transition order of the WPI and modified starch changed as the pH increased. Scanning electron microscopy images showed that the addition of HPCS and CLCS contributed to the formation of a compact microstructure at pH 5.75 and 7.00. A comprehensive analysis showed that the gelling properties of the WPI‐modified starch were affected by the difference between the WPI denaturation temperature and modified starch gelatinisation temperature and by the granular properties of the modified starch during gelatinisation. These results may contribute to the application of WPI‐modified starch mixtures in food preparation.     

Foams Prepared from Whey Protein Isolate and Egg White Protein: 2. Changes Associated with Angel Food Cake Functionality

ABSTRACT:  The effects of sucrose on the physical properties and thermal stability of foams prepared from 10% (w/v) protein solutions of whey protein isolate (WPI), egg white protein (EWP), and their combinations (WPI/EWP) were investigated in wet foams and angel food cakes. Incorporation of 12.8 (w/v) sucrose increased EWP foam stability (drainage 1/2 life) but had little effect on the stability of WPI and WPI/EWP foams. Increased stability was not due to viscosity alone. Sucrose increased interfacial elasticity ( E  ') of EWP and decreased E' of WPI and WPI/EWP combinations, suggesting that altered interfacial properties increased stability in EWP foams. Although 25% WPI/75% EWP cakes had similar volumes as EWP cakes, cakes containing WPI had larger air cells. Changes during heating showed that EWP foams had network formation starting at 45 °C, which was not observed in WPI and WPI/EWP foams. Moreover, in batters, which are foams with additional sugar and flour, a stable foam network was observed from 25 to 85 °C for batters made from EWP foams. Batters containing WPI or WPI/EWP mixtures showed signs of destabilization starting at 25 °C. These results show that sucrose greatly improved the stability of wet EWP foams and that EWP foams form network structures that remain stable during heating. In contrast, sucrose had minimal effects on stability of WPI and WPI/EWP wet foams, and batters containing these foams showed destabilization prior to heating. Therefore, destabilization processes occurring in the wet foams and during baking account for differences in angel food cake quality.     

改性大豆分离蛋白对法兰克福香肠品质的影响

采用酶水解和酶交联的方法对SPI进行改性,制备能够提高法兰克福香肠的持水性和贮存稳定性的功能性食品用蛋白配料.通过应用全质构分析和色差的方法,考察添加改性蛋白的香肠品质,用TBARS反应物的含量来监测改性蛋白对香肠在储藏过程中的脂肪氧化稳定性的影响.结果表明:SPI水解交联产物可以显著(P＜0.05)抑制法兰克福香肠脂肪氧化的发生,显著(P＜0.05)降低香肠的蒸煮损失,显著(P＜0.05)提高香肠的质构品质.采用碱性蛋白酶水解SPI至水解度4后停止水解、再用谷氨酰胺转氨酶交联2 h获得的改性蛋白,以2%的量添加到法兰克福香肠中,其防止香肠蒸煮损失和抗氧化效果显著.     

Shear-induced structuring of particulate whey protein gels

The effects of steady shear on particulate whey protein isolate (WPI) gels, at pH 5.4, have been investigated by light microscopy (LM) and dynamic oscillatory measurements. The steady shear was performed on suspensions at constant rates between 0.5 and 126/s. The gel point under static conditions (T_g) was around 78 °C and the shearing was performed during heating from 20 to 76 or to 82 °C. The gel point was postponed by the shear up to 82 °C. Steady shear up to 76 °C, at rates less than 6/s, resulted in a weaker storage modulus (G′), less frequency dependence and a higher stress at fracture compared to the unsheared gel. Steady shear up to 82 °C, at rates below 6/s, resulted in the formation of two different types of network structure. One structure was similar in appearance to the unsheared network, showing pores in the range of 50 μm. The other structure was dense, composed of smaller particles than the unsheared network and with pores in the range of 10 μm. The gels composed of two structures showed a lower G′ and stress at fracture compared to the unsheared gel. A shear rate above 24/s up to 76 °C resulted in irregular networks, which were composed of two different types of structures. One was loose and open, similar in appearance to the unsheared network structure. The other structure was dense and compact, and was present as individual aggregates. These gels also showed a weaker G′ than the unsheared gel. A shearing up to 82 °C at rates above 24/s resulted in a coarse, inhomogeneous network structure. The gels showed a weak G′, indicating aggregate break-up during the steady shear.     

Influence of whey protein isolate on pasting,thermal, and structural characteristics of oat starch

We investigated the effects of different concentrations of whey protein isolate (WPI) on oat starch characteristics in terms of pasting, thermal, and structural properties. The pasting properties of the starch showed that hot paste viscosity increased with the addition of WPI in the system, and relative breakdown decreased. Thermal analysis showed a significant effect of WPI on oat starch by increasing the peak temperature of differential scanning calorimeter endotherms. The X-ray diffraction and Fourier transform infrared spectroscopy studies revealed that WPI increased the ordered structuration of starch paste, as evident by an increase in relative crystallinity; in addition, a decrease in infrared bands at 1,024 cm^?1 and 1,080 cm^?1 suggested decreased gelatinization of oat starch granules. Overall, WPI at different concentrations affected the oat starch gelatinization properties.     

Coating of Peanuts with Edible Whey Protein Film Containing α‐Tocopherol and Ascorbyl Palmitate

ABSTRACT: Physical properties of whey protein isolate (WPI) coating solution incorporating ascorbic palmitate (AP) and α‐tocopherol (tocopherol) were characterized, and the antioxidant activity of dried WPI coatings against lipid oxidation in roasted peanuts were investigated. The AP and tocopherol were mixed into a 10% (w/w) WPI solution containing 6.7% glycerol. Process 1 (P1) blended an AP and tocopherol mixture directly into the WPI solution using a high‐speed homogenizer. Process 2 (P2) used ethanol as a solvent for dissolving AP and tocopherol into the WPI solution. The viscosity and turbidity of the WPI coating solution showed the Newtonian fluid behavior, and 0.25% of critical concentration of AP in WPI solution rheology. After peanuts were coated with WPI solutions, color changes of peanuts were measured during 16 wk of storage at 25 °C, and the oxidation of peanuts was determined by hexanal analysis using solid‐phase micro‐extraction samplers and GC‐MS. Regardless of the presence of antioxidants in the coating layer, the formation of hexanal from the oxidation of peanut lipids was reduced by WPI coatings, which indicates WPI coatings protected the peanuts from oxygen permeation and oxidation. However, the incorporation of antioxidants in the WPI coating layer did not show a significant difference in hexanal production from that of WPI coating treatment without incorporation of antioxidants.     

Whey protein isolate-based edible films as affected by protein concentration,glycerol ratio and pullulan addition in film formation

Edible films were prepared from whey protein isolate (WPI), and characterized in order to select a best combination of protein concentration and glycerol (Gly) ratio. 5%, 7% and 9% (w/v) WPI were used at three WPI:Gly ratios (3.6:1; 3:1; and 2:1). 5% WPI with a 3.6:1 WPI:Gly ratio showed the best combination with factors considered being thickness and water vapor permeability (WVP), while the 9% WPI with 3.6:1 WPI:Gly showed the best result as seen from the oxygen permeability (OP). Further studies were conducted by adding pullulan (PUL) at different WPI:PUL ratios (1:0; 1:1; 2:1; 3:1; 4:1; 5:1; 6:1; 8:1; 10:1) to a selected film in order to investigate the effect of pullulan on thickness, OP, WVP, moisture content (MC), film solubility (FS) and morphology using scanning electron microscopy (SEM). WPI–PUL film had a good appearance and 1:1 WPI:PUL resulted in films with greatest values of OP, WVP, MC, FS, and transmittance. The SEM micrographs showed many pinholes and a favorable structure for the low barrier ability. However, addition of PUL at low concentration was good enough to significantly modify these properties, hence improving the potential characteristics of WPI-based films for food applications.     

Cricket (Acheta domesticus) flour as meat replacer in frankfurters: Nutritional,technological, structural,and sensory characteristics

This study investigated the use of cricket flour in frankfurters as a meat replacer and its impact on nutritional, technological, structural, and sensory characteristics. Four treatments were prepared with different concentrations of cricket flour (Control, CF2.5, CF5.0, and CF7.5). There was a significantly high protein content in treatments with cricket flour addition, but without change in the fat content. The CF7.5 treatment showed significantly high SFA and PUFA contents, but there was no significant impact on MUFA content, compared with control treatment. Cricket flour significantly improved the contents of zinc, calcium, and manganese but not that of sodium. The processing loss of reformulated frankfurters was significantly reduced. Reformulated frankfurters were brownish in color compared with the control, which affected the sensory scores of those treatments. No effect on the structural characteristics of frankfurters were observed. The CF2.5 treatment appeared to be the best alternative for using edible insects in frankfurters.