Multiphase visualisation of fat containing β-lactoglobulin-κ-carrageenan gels by confocal scanning laser microscopy, using a novel dye, V03-01136, for fat staining

In this study, the gel strength and visible microstructure of fat containing β-lactoglobulin-κ-carrageenan gels were investigated using puncture testing and confocal scanning laser microscopy, respectively. The gel strength was closely linked to the visible microstructure of the whey protein network as stained with Rhodamine B. Covalent labelling of κ-carrageenan with FITC prior to gel formation enabled localisation of the hydrocolloid phase, but caused a significant drop in the gel strength. This effect coincided with the observed reduction of the κ-carrageenan intrinsic viscosity, which was found to be a result of the labelling process. The use of a novel dye, V03-01136, for the staining of fat allowed for the specific and concurrent visualisation of the protein, hydrocolloid and fat phases under the conditions applied in the study.     

Next target for food hydrocolloid studies: Texture design of foods using hydrocolloid technology

Texture is important in terms of both food palatability and the safety of eating. Recently, the importance of texture has been emphasized for the development of nursing-care foods, including dysphagia foods, in recent aged society, where the number of patients with mastication and swallowing difficulties is increasing. Texture design of these food products is now one of the most important tasks in the food industry in Japan. Texture of these food products should be optimized by modulating viscoelasticity using hydrocolloids so that they can easily transform to ‘ready-to-swallow’ bolus during oral processing. This article reviews the importance of texture as an essential attribute of foods and also the usefulness of hydrocolloids as an ingredient to modify and control food texture. The article also covers recent trials by the author’s research team on bolus rheology and in vivo acoustic analysis. The trials are to find some objective parameters describing the mastication and swallowing eases as an alternative to conventional bulk rheology and subjective sensory analysis.     

Improvers and functional ingredients in whole wheat bread: A review of their effects on dough properties and bread quality

BackgroundDespite the associated health benefits of whole grains, consumption of whole grain products remains far below recommended levels. Whole wheat bread is often associated with many distinctive attributes such as low loaf volume, firm and gritty texture, dark and rough crust and crumb appearance, bitter flavor, and reduced shelf-life. There is a need to improve its quality and sensory characteristics so as to increase consumer appeal and, ultimately, increase the intake of whole wheat bread. The inclusion of various ingredients improves dough and bread properties.Scope and approachThis review examines the effects of enzymes, emulsifiers, hydrocolloids, and oxidants on the properties of whole wheat bread and dough, with particular attention to effects on loaf volume and hardness. Wheat gluten and other plant materials are also discussed. Gaps in the research into whole wheat bread are identified, and future research needs are recommended.Key findings and conclusionsXylanase reduces the water absorption of whole wheat flour and increases loaf volume and crumb softness by hydrolyzing ararbinoxylans. α-amylase can be beneficial under certain conditions. Phytase may activate endogenous α-amylase. G4-amylase is promising but needs validation by further research on its effect on loaf volume, crumb hardness, and staling. Vital wheat gluten overcomes many of the challenges of whole wheat bread production and is found in the majority of commercial whole wheat breads. Emulsifiers DATEM and SSL can improve the volume, texture and staling profile of whole wheat bread. Several types of improvers are generally needed in combination to provide the greatest improvement to whole wheat dough and bread.     

Development of an efficient stabiliser mixture for physical stability of nonfat unfizzy doogh

The effects of locust bean, carboxymethyl cellulose, a mixture of locust bean and carboxymethyl cellulose and Persian gum on different properties of nonfat doogh were studied over a period of 28 days. The results showed that samples containing a mixture of locust bean and carboxymethyl cellulose had the highest stability. Furthermore, the rheological behaviour of the doogh changed from Newtonian to pseudoplastic. Better sensory acceptability was shown for the treatments containing a mixture of locust bean gum and carboxymethyl cellulose. In general, it was shown that a mixture of locust bean and carboxymethyl cellulose could be of practical use in the industrial production of nonfat doogh.     

Quality of Processed Cheddar Cheese as a Function of Emulsifying Salt Replaced by κ-Carrageenan

Hydrocolloids act as stabilizer and thickening agents, thus able to replace emulsifying salts. The present study was planned to use к-carrageenan in the production of processed cheddar cheese and to explore its effect on physico-chemical and textural properties of processed cheddar cheeses. Different concentration of ?-carrageenan were used with gradual decrease in salt contents along with natural cheese, fat, and water to prepare processed cheddar cheese. The prepared samples were analyzed for physico-chemical and sensory attributes at storage interval of 45 days during and after 90 days. With the increase in hydrocolloid concentration, stiffer product was obtained and meltability of the samples decreased than control. Processed cheddar cheese samples having 0.15% к-carrageenan with 2% emulsifying salt (1.34% sodium citrate and 0.66% disodium phosphates) were found more acceptable in terms of physico-chemical and sensory attributes, but all sensory attributes got fewer score with the passage of storage time.     

Effect of various salts and pH condition on rheological properties of Salvia macrosiphon hydrocolloid solutions

The extraction of Salvia macrosiphon seed hydrocolloid was performed successfully and the optimum hydration time and temperature were found to be 30 min and 25 °C for 12% extraction yield. The effect of solution pH (3–9) and addition of NaCl (0.5–3%), CaCl₂ (0.5–3%) and Na₂HPO₄ (0.2–0.6%) on rheological properties of the hydrocolloid solutions were investigated. Rheologcal data were fitted with the Power law model with regression coefficient of greater than 0.95. Strong shear thinning behavior with the n value of less than 0.53 was recorded. All variables had significant impacts on rheological parameters. The minimum and maximum consistencies were found at pH 3 and the 9, respectively. This was explained with the presence of carboxylic groups on the biopolymer backbone as indicated by FTIR. NaCl, CaCl₂ and Na₂HPO₄ had significant effects on rheological properties. Moreover, at similar salt concentration of 0.5%, Na₂HPO₄ had the greatest and NaCl had the lowest effect.     

The effect of selected hydrocolloids on the rheological properties of processed cheese analogues made with vegetable fats during the cooling phase

The aim of this work was to observe the influence of different hydrocolloids on changes in the rheological properties of processed cheese and their analogues within the process of cooling depending on the type of the fat used (butter, coconut fat and palm oil). κ‐carrageenan, ι‐carrageenan, λ‐carrageenan, arabic gum and locust bean gum were used at a concentration of 1.0% w/w. With the decreasing temperature during the cooling period, an increase in the complex modulus (G*) was observed in all samples tested. Within the cooling period, the sample with the addition of κ‐carrageenan showed both the most significant increase in G* in comparison with the control and the highest values of hardness after a 7‐day storage period regardless of the type of the fat used. The samples with coconut fat were assessed as the hardest. On the other hand, the samples with palm oil showed the lowest hardness (with the same hydrocolloid used). In the gelling hydrocolloids (κ‐ and ι‐carrageenan), only small changes in temperature of coil‐to‐helix transition were observed (in range of 2–7 °C) as a result of the addition of different types of fat.     

医用棉纱布的羧甲基化改性

采用两步加碱水媒法,并通过浸轧的方式对医用棉纱布进行羧甲基化改性,制备高吸水性医用敷料。考察了烧碱浓度、烧碱与氯乙酸的配比对样品的取代度、吸水性、透气性和力学性能的影响,确定了最佳工艺条件。结果表明：随着第一步烧碱浓度和第二步烧碱与氯乙酸的摩尔比的增加,羧甲基化医用棉纱布的取代度和吸水性均呈现明显的上升趋势。当第一步加碱的烧碱浓度为20%,烧碱与氯乙酸的摩尔比为2.7：1时,样品的拉伸断裂强力及伸长率上升到最大值,羧甲基化医用棉纱布表现出良好的柔韧性,同时也具有较好的透气性。此时,样品的取代度为0.17,吸水率达到170.98%,纱布表面形成了均匀有效的水凝胶保护层。     

Effect of salep as a hydrocolloid on storage stability of ‘İncir Uyutması’ dessert

Salep is a natural stabilizing agent used widely in Turkish-type Mara? ice cream and some milk desserts. The effect of salep addition on the storage stability of a representative ?ncir Uyutmas? dessert, prepared from whole cows’ milk, fig and sugar was studied. Dry matter, pH, viscosity, water-holding capacity (WHC), color properties (L*, a*, b* values), mineral matters (Al, Ca, Cu, Fe, K, Mg, Na, P and Zn), sensorial properties and microbial quality of desserts were affected by salep addition, sugar and fig concentrations. Salep addition caused an important increase in the viscosity and the WHC of dessert. Salep, sugar and fig improved the storage stability of the dessert.     

Nanostructural modification of a model homogalacturonan with a novel pectin methylesterase: Effects of pH on nanostructure,enzyme mode of action and substrate functionality

A Carica papaya pectin methylesterase (CpL-PME) present in a commercial papain preparation was used to modify the amount and distribution of anionic charge in a population of a model pectic homogalacturonan (HG) at pH 4.5 and pH 7.5. Introduced negatively charged demethylesterified blocks (DMB) were excised as oligomers with limited endo-polygalacturonase (EPG) digestion, and then separated and quantified by high performance anion exchange chromatography. Exhaustive EPG digestion was also performed and the concentrations of mono-, di- and tri-galacturonic acid (GalA) produced were estimated. The CpL-PME mode of action was modeled while the HG population's nanostructure and the resulting functionality of the modified pectin were characterized. The results indicated that average DMB size and number of these “average” blocks per molecule increased as the overall degree of methylesterification (DM) decreased by CpL-PME treatment (P < 0.05). Average DMB size differed depending on the reaction pH at each DM. Absolute degree of blockiness (DB_abs) increased as DM decreased and demonstrated a linear relationship with the DM at both reaction pH values. Significant positive correlations between DB_abs and average DMB size were observed for both pH series (P < 0.05). The enzyme mode of action, modeled in silico, demonstrates a processive multiple attack mechanism. Functionally, the storage modulus of ionotropic gels formed from the processed substrates increased as DM decreased, and as DB_abs and average DMB size increased with highly significant correlations (P < 0.001). These results indicate it is feasible to engineer pectin nanostructure and functionality with CpL-PME.