Extractability of muscle protein as criterion for Technological evaluation of sea fish Part 1. Changes of protein fraction of Baltic herring and Baltic cod during storage in ice

Content of protein fractions dissolved in 0,5 – 5% NaCl solutions (total protein, myofibrillar protein and crude actomyosin) were investigated in meat tissue of Baltic cod and Baltic herring stored in ice at 1 °C (±1 °C). Cod was showing faster reduction in extractability of soluble proteins than herring during spoilage.     

The use of nisin as a preservative in fish sausage stored at ambient (28 ± 2 °C) and refrigerated (6 ± 2 °C) temperatures

Summary The efficacy of nisin at three different concentrations, 12.5, 25 and 50 ppm, on the keeping quality of fish sausage in synthetic casing at ambient (28 ± 2 °C) and refrigerated (6 ± 2 °C) temperatures was assessed. Gel strength, expressible water content, total volatile base nitrogen, total plate count and aerobic spore counts were affected by the storage temperatures and nisin concentrations used. Fish sausage treated with 50 ppm of nisin was acceptable after storage at ambient temperature for 20–22 days compared with the control, which were acceptable only for 2 days. The keeping quality of the sausages, at refrigerated temperature, varied from 30 days in the control to 150 days in 50‐ppm nisin‐treated samples. The residual nisin decreased slowly in samples stored at refrigerated temperature, whereas, in fish sausages stored at ambient temperature, the decrease was rapid. Nisin at 50‐ppm level showed a significant effect (P ≤ 0.05) on the gel strength and overall acceptability scores both at ambient and refrigerated temperature.     

Effect of pasteurisation on sensory quality of natural soursop puree under different storage conditions

Pasteurisation effects on natural soursop (Annona muricata L.) puree were evaluated in terms of appearance, colour, flavour, odour, consistency and overall acceptability for 12 weeks. The packaging and storage temperature combinations used were laminated aluminium foil (LAF), lacquered can (LC) and high density polyethylene plastic bottle (HDPE) at ambient temperature (28–38°C), 15, 4 and −20°C. Results showed pasteurisation at 79°C for 69 s significantly improved the sensory colour, flavour, appearance and overall acceptability of the puree. Pasteurised puree packed in LAF at 4°C had the highest score for almost every attribute evaluated. Overall, all samples were found acceptable by judges during the 12 week storage period. The better stability, in terms of colour, consistency and flavour characteristics, of pasteurised puree packed in foil at 4°C than the frozen control could be an additional and cheap advantage for storage and transport.     

Use of acid whey protein concentrate as an ingredient in nonfat cup set-style yogurt

Acid whey resulting from the production of soft cheeses is a disposal problem for the dairy industry. Few uses have been found for acid whey because of its high ash content, low pH, and high organic acid content. The objective of this study was to explore the potential of recovery of whey protein from cottage cheese acid whey for use in yogurt. Cottage cheese acid whey and Cheddar cheese whey were produced from standard cottage cheese and Cheddar cheese-making procedures, respectively. The whey was separated and pasteurized by high temperature, short time pasteurization and stored at 4°C. Food-grade ammonium hydroxide was used to neutralize the acid whey to a pH of 6.4. The whey was heated to 50°C and concentrated using ultrafiltration and diafiltration with 11 polyethersulfone cartridge membrane filters (10,000-kDa cutoff) to 25% total solids and 80% protein. Skim milk was concentrated to 6% total protein. Nonfat, unflavored set-style yogurts (6.0 ± 0.1% protein, 15 ± 1.0% solids) were made from skim milk with added acid whey protein concentrate, skim milk with added sweet whey protein concentrate, or skim milk concentrate. Yogurt mixes were standardized to lactose and fat of 6.50% and 0.10%, respectively. Yogurt was fermented at 43°C to pH 4.6 and stored at 4°C. The experiment was replicated in triplicate. Titratable acidity, pH, whey separation, color, and gel strength were measured weekly in yogurts through 8 wk. Trained panel profiling was conducted on 0, 14, 28, and 56 d. Fat-free yogurts produced with added neutralized fresh liquid acid whey protein concentrate had flavor attributes similar those with added fresh liquid sweet whey protein but had lower gel strength attributes, which translated to differences in trained panel texture attributes and lower consumer liking scores for fat-free yogurt made with added acid whey protein ingredient. Difference in pH was the main contributor to texture differences, as higher pH in acid whey protein yogurts changed gel structure formation and water-holding capacity of the yogurt gel. In a second part of the study, the yogurt mix was reformulated to address texture differences. The reformulated yogurt mix at 2% milkfat and using a lower level of sweet and acid whey ingredient performed at parity with control yogurts in consumer sensory trials. Fresh liquid acid whey protein concentrates from cottage cheese manufacture can be used as a liquid protein ingredient source for manufacture of yogurt in the same factory.     

Effects of oil roasting temperature and time on the quality of two Macadamia integrifolia cultivars

The effects of oil roasting temperature and time on the quality of kernels from two Macadamia integrifolia cultivars, were determined. A high quality product was obtained by roasting at 115°C for 19–35 min, 125°C for 10–14 min or 135°C for 4 min. There was a significant deterioration in the quality of nuts from all roasting treatments when stored for 6 months at ambient temperature in lacquered cans at a pressure of ?85 kPa. Further deterioration had occurred after 12 months storage.     

Physiochemical Properties and Probiotic Survivability of Symbiotic Corn‐Based Yogurt‐Like Product

Corn is a major grain produced in northern China. Corn‐based functional food products are very limited. In this study, a symbiotic corn‐based yogurt‐like product was developed. Corn milk was prepared through grinding, extrusion and milling, and hydration processes. Corn extrudate was prepared under the optimized conditions of corn flour particle size <180 μm, moisture content of 15% and extrusion temperature at 130 °C. The corn milk was prepared from 8% corn extrudate suspension and then milled twice with 0.1% glyceryl monostearate and 0.1% sucrose ester as emulsifiers. The corn milk was mixed with sugar (5%), glucose (2%), soy protein isolate (0.75%), inulin (1%), polymerized whey protein (0.3%) and xanthan gum (0.09%) as thickening agents. The mixture was fermented at 35 °C for 6 h using a probiotic starter culture containing L. plantarum. Chemical composition (%) of the symbiotic corn‐based yogurt‐like product was: total solids (17.13 ± 0.31), protein (1.12 ± 0.03), fat (0.30 ± 0.05), carbohydrates (15.14 ± 0.19), and ash (0.16 ± 0.02), respectively. pH value of this symbiotic product decreased from 4.50 ± 0.03 to 3.88 ± 0.13 and the population of L. plantarum declined from 7.8 ± 0.09 to 7.1 ± 0.14 log CFU/mL during storage at 4 °C. SDS‐PAGE analysis showed that there were no changes in protein profile during storage. Texture and consistency were also stable during the period of this study. It can be concluded that a set‐type corn‐based symbiotic yogurt‐like product with good texture and stability was successfully developed that would be a good alternative to the dairy yogurt.     

The effect of long‐term storage on amino acid content of ready‐to‐eat entrées

The effect of 24‐month storage at three different temperatures (6 ± 2 °C, 26 ± 2 °C, 37 ± 2 °C) on quality of three types of ready‐to‐eat entrées (MRE) was evaluated by means of amino acid, ammonia, moisture and crude protein contents. Spicy risotto, Pork meat with carrots and potatoes and Pork goulash with pasta, that are included into the Czech combat rations, were selected for the experiment. During storage, all the explored samples did not significantly differ in moisture and crude protein content. Higher losses of amino acids (e.g. sulphuric amino acids, lysine, leucine) were detected with the increasing storage time and temperature. Growing losses of amino acids resulted in rising ammonia content as a product of amino acid degradation process. The biological value expressed by essential amino acid index declined with higher temperature and longer time of storage. The dependence of amino acid losses on moisture content was observed, too.     

Relationship between N-nitrosodiethylamine formation and protein oxidation in pork protein extracts

The relationship between protein oxidation and N-nitrosodiethylamine (NDEA) formation was assessed. Packaged fresh minced pork was stored at 2 ± 1 °C for 0, 4, 7, and 10 days. Myofibrillar protein (MP), sarcoplasmic protein (SP), and muscle homogenate were obtained from the stored minced pork and allowed to react with sodium nitrite at 80 °C for 1 h. The relationship between NDEA formation and indexes of protein oxidation was assessed by principal component analysis. The formation of NDEA in meat was correlated with protein and lipid oxidation. Lipid oxidation promoted the formation of NDEA and was positively correlated with protein oxidation. Carbonyl compounds from oxidized MP and free amines from dissociated SP promoted NDEA formation. Therefore, the effect of protein oxidation on NDEA formation depends on the type of protein and its oxidation products.     

Temperature effects on type I pepsin‐solubilised collagen extraction from silver‐line grunt skin and its in vitro fibril self‐assembly

BACKGROUND: Fish skin is a potential source of collagen. Increasing the extraction temperature increases the yield of collagen. However, it may also result in degradation of the peptide chains, thus damaging the 3D structure of collagen that is vital for its application as a biomaterial. This work investigated the effects of extraction temperature on the yield and characteristics, including fibril self‐assembly, of type I pepsin‐solubilised fish skin collagen. RESULTS: Pepsin‐solubilised collagens were extracted from fresh skin of silver‐line grunt at 4, 10, 20 and 28 °C for 6 h. Extraction at 10 °C gave the highest yield of collagens (439.32 ± 96.43 mg g^?1 fresh skin, dry basis), which were identified as type I and comprised β, α1 and α2 subunits. Extraction at higher temperatures (20 and 28 °C) resulted in the formation of low‐molecular‐weight peptide fragments, thus reducing the yield of the resultant type I collagen. The denaturation temperatures of collagens extracted at 4 and 10 °C, as determined by thermal analysis using differential scanning calorimetry, were 39.5 and 37.5 °C respectively. In vitro fibril self‐assembly of 1 mg mL^?1 collagen solution (pH 6) incubated at 25 °C was only observed with collagens extracted at 4 and 10 °C. The 10 °C collagen not only showed a higher rate of self‐assembly, but its matrix also had a larger fibril diameter of 0.50 ± 0.07 µm (compared with 0.41 ± 0.07 µm for the 4 °C collagen) after 4 h of incubation. CONCLUSION: The results indicated strong effects of extraction temperature on the yield and characteristics of the collagen obtained. Extraction of pepsin‐solubilised collagen from silver‐line grunt skin at 4–10 °C gave a high yield of type I collagen with molecular integrity suitable for tissue‐engineering applications. Copyright © 2010 Society of Chemical Industry     

Iron and tin content of canned fruit juices and nectars

A survey of the iron and tin content of twelve different types of canned fruit juices and nectars revealed that, of the 122 cans examined, 23 (or 18·9%) contianed iron in excess of 15 mg kg^?1 and 16 (or 13·1%) contained tin in excess of 250 mg kg^?1. Apple juice and tomato juice were found to contain particularly high levels of iron, the maximum level recorded being 42·6 mg kg^?1. Mango juice and orange juice exhibited significant non-compliance with recommended Codex tolerance limits for tin. Statistical analysis showed that, at the 5% probability level, the mean iron contents of products packed in completely unlacquered and end-lacquered cans were not significantly different from each other, but were significantly lower than the mean iron content of products packed in fully lacquered cans. The mean tin content fell in the order unlacquered > end-lacquered > fully lacquered cans.     

Effect of thiamine hydrochloride,pyridoxine hydrochloride and calcium‐d‐pantothenate on the patulin content of apple juice concentrate

Thiamine hydrochloride, pyridoxine hydrochloride and calcium‐d‐pantothenate were applied apple juice concentrates (AJC) at various doses in order to reduce the patulin content. AJC samples containing high levels of patulin were stored at 22 ± 2°C and 4°C for 6 months after vitamins were added. Patulin was fully degraded at the end of a 6‐month period in samples stored at 22 ± 2°C, on the other hand, other quality parameters diminished significantly. Without any considerable reduction on other quality parameters, applications of 1000 and 2500 mg/kg calcium‐d‐pantothenate resulted in reduction of patulin of 73.6 and 94.3%, respectively, however, 42.1% of patulin reduction was observed in the control sample of AJC stored for 1 month at 22 ± 2°C. Addition of thiamine hydrochloride (1000 mg/kg( pyrodoxine hydrochloride (625 or 875 mg/kg) and calcium‐d‐pantothenate (1000 or 2500 mg/kg) into the samples and storage at 4°C for 6 months yielded 55.5 to 67.7% of patulin reduction which was only 35.8% for the control, while the other quality parameters were protected adequately.     

Effect of limited enzymatic hydrolysis on physico‐chemical properties of soybean protein isolate‐maltodextrin conjugates

The effect of limited hydrolysis was investigated on the physico‐chemical properties of soy protein isolate–maltodextrin (SPI‐Md) conjugate. The hydrolysates at a degree of hydrolysis (DH) of 1.8% showed much higher surface hydrophobicity (H₀; 71.39 ± 3.60) than that of the SPI control (42.09 ± 2.17) and SPI‐Md conjugates (53.46 ± 2.74). Intrinsic fluorescence analysis demonstrated the unfolding of protein molecule and exposure of hydrophobic groups of SPI‐Md conjugate hydrolysates. As evidenced by far‐UV circular dichroism (CD) spectroscopy, the limited hydrolysis increased the unordered secondary structures of SPI‐Md conjugates. The denaturation temperature (T_d) of SPI‐Md conjugate was significantly increased by subsequent limited hydrolysis from 102.53 ± 0.60 °C to 108.11 ± 0.61 °C at DH 1.8%. In particular, the emulsifying activity index (EAI) was improved notably after limited hydrolysis of DH 1.8% (147.76 ± 4.39 m² g^?1) compared with that of native SPI (88.90 ± 1.44 m² g^?1) and SPI‐Md conjugate (108.97 ± 1.45 m² g^?1).     

Quality Assurance of Model Infant Milk Formula Using a Front-Face Fluorescence Process Analytical Tool

Front-face fluorescence spectroscopy (FFFS) was evaluated as a quality assurance process analytical technology (PAT) tool for infant milk formula (IMF) manufacture. Batches of first-stage IMF (60:40 whey protein:casein ratio) powder were produced with protein:fat:lactose ratios of 1.3:3.6:7.3, differing only in heat treatment applied prior to spray drying (72, 95, or 115 °C for 15 s). Each IMF powder was stored at 15?±?2 °C and 37?±?2 °C and analyzed at months 0, 3, 6, and 12. Partial least squares (PLS) models were developed for IMF in both powder and liquid states using FFFS spectra to predict pre-drying heat treatment temperature, soluble protein content, and storage time. Models developed using tryptophan emission spectra for IMF powder predicted storage time, pre-drying heat treatment temperature, and soluble protein content with RMSECV values of 0.3 months, 8.3 °C, and 1.01 g protein/100 g powder, respectively. IMF powders were rehydrated to 13% total solids and analyzed using the vitamin A emission spectra. Models developed for rehydrated IMF predicted storage time and pre-drying heat treatment temperature with RMSECV values of 1.5 months and 6.7 °C, respectively. Surface free fats were predicted with an RMSECV range of 0.12–0.20% (w/w of powder) in rehydrated IMF. PLS discriminant analysis models developed for both powder and liquid IMF samples successfully discriminated for storage temperature. This preliminary study demonstrates the strong potential of FFFS as a PAT tool for IMF quality assurance.     

Co‐extrusion of pearl millet‐whey protein concentrate for expanded snacks

A study was conducted to develop pearl millet‐based extruded snacks with whey protein concentrate (WPC) to enhance its acceptability and nutritional value. Pearl millet grits (841 μ) was extruded with different levels (0%, 2.5%, 5.0% and 7.5%) of WPC at constant feed rate (10.5 kg h^?1) and moisture content (14%). Addition of whey protein at 7.5% level significantly (P ≤ 0.05) increased T_g from 75.1 ± 0.26 °C to 120.5 ± 1.28 °C and T_m from 89.1 ± 1.51 °C to 158.7 ± 1.37 °C, which resulted in less expanded and harder extrudates. The expansion index of extrudates was negatively correlated (P ≤ 0.05) with protein (r = ?0.940), bulk density (r = ?0.949), hardness (r = ?0.971) and breaking strength (r = ?0.921), while positively correlated (P ≤ 0.05) with overall acceptability (OAA; r = 0.988). Keeping in view the nutritional, textural and consumer's acceptability, incorporation of 5% WPC in pearl millet grits (841 μ) was recommended for preparation of acceptable expanded snacks.     

Zinc‐loaded whey protein nanoparticles prepared by enzymatic cross‐linking and desolvation

Zinc‐loaded whey protein nanoparticles were prepared by enzymatic cross‐linking whey protein followed by ethanol desolvation. Whey protein isolate (WPI) was denatured by heating (80 °C for 15 min) at pH 7.0 and then cross‐linked by transglutaminase at 50 °C for 4 h while stirring. Transglutaminase was inactivated by heating at 90 °C for 10 min, and then, ZnSO₄·7H₂O (1–10 mm ) was added. Zinc‐loaded whey protein nanoparticles were formed by adding ethanol at one to five times the volume of the protein solution at pH 9.0. The desolvated solutions were diluted by adding distilled water at ratio of 1:100 (w/v) immediately after desolvation. Dynamic light scattering (DLS) data showed that the particle size of zinc‐loaded whey protein nanoparticles increased with the amount of zinc and the volume of ethanol. Scanning electron microscopy micrographs revealed an almost spherical morphology for zinc‐loaded whey protein nanoparticles. The zinc loading efficiency was determined ranging from 76.7% to 99.2%. In vitro test data showed that the zinc release rate was low in simulated gastric fluid but high in simulated intestinal fluid. The results indicated that enzymatic cross‐linked whey protein nanoparticles may be used as a good vehicle to deliver zinc as a supplement.     

Influence of protein content and storage temperature on the particle morphology and flowability characteristics of milk protein concentrate powders

Milk protein concentrate (MPC) powders are widely used as ingredients for food product formulations due to their nutritional profile and sensory attributes. Processing parameters, storage conditions, and composition influences the flow properties of MPC powders. This study investigated the bulk and shear flow properties of 70.3, 81.5, and 88.1% (wt/wt, protein content) MPC after storage for 12 wk at 25 and 40°C. Additionally, the morphological and functional changes of the MPC powders were investigated and correlated with flowability. After 12 wk of storage at 25°C, the basic flow energy values significantly increased from 510 to 930 mJ as the protein content increased from 70 to 90% (wt/wt). Flow rate index was significantly higher for samples with high protein content. Dynamic flow tests indicated that MPC powders with high protein content displayed higher permeability. Shear tests confirmed that the samples stored at 25°C were more flowable than samples stored at 40°C. Likewise, the higher-protein content samples showed poor shear flow behavior. The results indicated that MPC powders stored at 25°C had less cohesiveness and better flow characteristics than MPC powders stored at 40°C. Overall, the MPC powders had markedly different flow properties due to their difference in composition and morphology. This study delivers insights on the particle morphology and flow behavior of MPC powders.     

The effects of temperature on the retention and denaturation of protein in lucerne leaves subjected to mechanical dewatering

The effects of pretreatment temperature on the retention and denaturation of protein were studied in relation to moisture removal from lucerne forage subjected to mechanical pressing. Leaf samples were held for 5 min at a temperature between 40-100°C, then pressed. Although the protein concentration of the expressed juice decreased with increasing temperature, the amount of soluble protein lost in the expressed juice was fairly constant, amounting at most to only 4%. The maximum reduction in water content (76 ± 1%) was achieved by pressing after a treatment of 60-70°C. However, the protein retained in the residue was not denatured completely until the pretreatment temperature exceeded 80°C. At 60°C, with maximum water removal, only one-third of the protein became denatured; at 50°C, 80% of the maximum water removal was obtained with only 16% denaturation of retained protein.     

Effect of dietary crude protein degradability and corn processing on lactation performance and milk protein composition and stability

The present study aimed to evaluate the effect of crude protein degradability and corn processing on lactation performance, milk protein composition, milk ethanol stability (MES), heat coagulation time (HCT) at 140°C, and the efficiency of N utilization for dairy cows. Twenty Holstein cows with an average of 162 ± 70 d in milk, 666 ± 7 kg of body weight, and 36 ± 7.8 kg/d of milk yield (MY) were distributed in a Latin square design with 5 contemporaneous balanced squares, 4 periods of 21 d, and 4 treatments (factorial arrangement 2 × 2). Treatment factor 1 was corn processing [ground (GC) or steam-flaked corn (SFC)] and factor 2 was crude protein (CP) degradability (high = 10.7% rumen-degradable protein and 5.1% rumen-undegradable protein; low = 9.5% rumen-degradable protein and 6.3% rumen-undegradable protein; dry matter basis). A significant interaction was observed between CP degradability and corn processing on dry matter intake (DMI). When cows were fed GC with low CP degradability, DMI increased by 1.24 kg/d compared with cows fed GC with high CP degradability; however, CP degradability did not change DMI when cows were fed SFC. Similar interactions were observed for MY, HCT, and lactose content. When cows were fed GC diets, high CP degradability reduced MY by 2.3 kg/d, as well as HCT and lactose content, compared with low CP degradability. However, no effect of CP degradability was observed on those variables when cows were fed SFC diets. The SFC diets increased dry matter and starch total-tract digestibility and reduced β-casein (CN) content (% total milk protein) compared with GC diets. Cows fed low-CP degradability diets had higher glycosylated κ-CN content (% total κ-CN) and MES, as well as milk protein content, 3.5% fat-corrected milk, and efficiency of N for milk production, than cows fed high-CP degradability diets. Therefore, GC and high-CP degradability diets reduced milk production and protein stability. Overall, low CP degradability increased the efficiency of dietary N utilization and MES, probably due to changes in casein micelle composition, as CP degradability or corn processing did not change the milk concentration of ionic calcium. The GC diets increased β-CN content, which could contribute to reducing HTC when cows were fed GC and high-CP degradability diets.     

Biochemical and Quality Characteristics of Ovine Muscles as Affected by Electrical Stimulation, Hot Boning, and Mode of Chilling

The combined effects of electrical stimulation and carcass holding temperature were evaluated on some biochemical and quality characteristics of intact and hot-boned ovine muscles. Twenty-four lamb sides were randomly assigned to four treatments. Electrical stimulation was performed within 15 min postmortem (350 V with 10 Hz) for 4 min. Electrically stimulated and slowly chilled (5 hr at 14 ± 2°C) sides significantly exhibited more rapid pH decline in the longissimus dorsi (LD) muscle, less cold shortening in the semitendinosus (ST) muscle and greater tenderness in both LD and ST muscles than sides chilled at 2°C. None of the treatments had any effect on cooking loss in ST and LD muscles, lean color of LD muscle during a 4-day retail display, and solubility of different protein fractions as well as the swelling factor of the stroma protein of LD muscles.     

Effects of Wall Materials and Operating Parameters on Physicochemical Properties,Process Efficiency,and Total Carotenoid Content of Microencapsulated Banana Passionfruit Pulp (<Emphasis Type="Italic">Passiflora tripartita var. mollissima</Emphasis>) by Spray-Drying

Banana passionfruit is an edible fruit widespread in the Andean highlands of Colombia and Ecuador, which has a high content of carotenoids. The microencapsulation process is used to improve the stability of this bioactive compound. The encapsulation agents, core/wall material ratio, and operational parameters influence the efficiency of the process. In this study, Maltodextrin (MD) and Gum Arabic (GA) were used as wall materials to assess the influence of inlet temperature and different MD:GA and core/encapsulating material (Core:EM) ratios on moisture, water activity, color, particle size, process yield (PY), encapsulation efficiency (EE), and total carotenoid content (TCC) of microencapsulated banana passionfruit pulp (MBP) by spray-drying. The lowest moisture (1.12?±?0.01%) of MBP was at a temperature of 150 °C; the water activity (Aw) for all samples was less than 0.4, and the Hue angle indicated a coloration between orange and yellow. The increase in temperature produced an increase in the particle size. However, the MBP showed a uniform particle diameter (1.25?±?0.21 μm). The treatment T2A1B2 (T?=?150 °C, Core:EM?=?1:1, MD:GA?=?4:6) showed the highest EE (50.79?±?0.29%) and the best PY (60.84?±?0.07%). The stability of MBP was carried out at temperatures of 4, 20, and 40 °C. The predicted shelf life can be up to 215 days on storage at 4 °C. The encapsulation improved the stability of TCC in banana passionfruit pulp. Therefore, the MBP can be considered as a potential ingredient for use in functional beverages.