Anti-staling effects of β-glucan and barley flour in wheat flour chapatti

Effect of Shearing and Annealing on the Pasting Properties of Different Starches

The functional characteristics of starch can be altered by shear force, which makes the impact on its microstructure of great importance to the food industry. This study investigated the effects of freeze-drying on the gel texture, pasting capabilities, and swelling power of starches made from sweet potatoes (SP), chickpeas (CP), and wheat (WS) combined with Cordia (CG) and Ziziphus gum (ZG). The samples were annealed in water without shearing and in a rapid visco-analyzer (RVA) for 30 min at 60 °C while being spun at 690 rpm. Both native and freeze-dried samples were mixed with 1% or 3% ZG and CG. After annealing, the starches were examined using a texture analyzer and RVA. The results showed that freeze-drying had a substantial (p > 0.05) impact on the starch granule, in addition to the effect of annealing. The peak viscosity of freeze-dried native CP and SP starches increased, but the peak viscosity of freeze-dried wheat starch decreased. The setbacks for CP and WS increased, whereas the setbacks for SP varied slightly. Furthermore, it was demonstrated that annealing in an RVA exhibited a substantially lower peak viscosity than annealing in a water bath; the RVA's shearing effect may have been the cause of this difference. Cordia gum fared better than ZG in terms of peak viscosity, although ZG significantly reduced setback in comparison to CG. Among the various blends, the native WB sample had the lowest hardness (100 ± 4.9 g), while the freeze-dried WB SP sample had the greatest (175.5 ± 4.8 g). Shearing of starches broke up the granules into smaller pieces, which made them gel at lower temperatures. This could be a good thing when they are needed for food uses that require little cooking.

Structural characteristics of β-glucans from various sources and their influences on the short- and long-term starch retrogradation in wheat flour

Beta-glucans possess the ability of retarding starch retrogradation. However, β-glucans from different sources might show various influences on retrogradation process and the structure-function relationships of β-glucans related to the feature still remains unclear. In the study, the β-glucans from oat (OG), highland barley (HBG), and yeast (YG) were selected. Each β-glucans formed aggregate as observed by atomic force microscopy. OG and HBG with a lower Mw aggregated more obviously and exhibited higher intrinsic and apparent viscosity. The two β-glucans showed more restraining effect on the short-term starch retrogradation in the sol-like test system (RVA) and the long-term starch retrogradation in the gel-like test system (DSC). However, YG with a higher Mw exerted a greater retarding effect on the short-term starch retrogradation in gel-like test systems (Mixolab and rheology). LF-NMR indicated that OG and HBG increased the population of less-bound water by wrapping around the starch. In summary, the structural characteristics of β-glucan (Mw and aggregation state) and experiment condition (solid content) jointly influenced starch retrogradation, because a lower Mw and higher aggregation capacity β-glucan interacted more readily with starch and inhibited more starch re-association due to the higher diffusion rate in the sol-like system.

Corn silk flour fortification as a dietary fiber supplement: evolution of the impact on paste, dough, and quality of dried noodles

Corn silk flour is a natural, functional ingredient, rich in dietary fiber and polyphenols. Fortification of a wheat flour-based staple food such as dried noodles, with corn silk flour could directly affect the pasting properties of wheat flour and hydration properties of dough, and thus influence the quality of dried noodles. The competition for water between corn silk flour and wheat flour inhibited the gelatinization of starch and hindered the formation of the gluten network which harmed the cooking properties and decreased consumer acceptance of the resulting dried noodles. Nutritionally, the dietary fiber and polyphenols content of the resulting dried noodles was effectively improved, especially at a 6∼9% replacement rate. The current work demonstrates the feasibility of fabricating corn silk flour-enriched dried noodles and its nutritional superiority compared to the corresponding normal product.

Development of pearl millet flour-based cookies supplemented with mung bean and orange fleshed sweet potato flours

The study explored the feasibility of producing cookies from pearl millet flour (PMF), mung bean flour (MF) and orange fleshed sweet potato flour (OFSPF). Sixteen formulations were produced by mixing the three basic ingredients: PMF, MF and OFSPF using optimal mixture design of response surface methodology. The sensory properties of cookies developed from these flour blends were evaluated and the result showed variations among cookie samples. Three samples were selected from the optimization results and compared with 100% wheat flour cookies (control). The selected flour blend samples showed a significant (p<0.05) increase in swelling capacity and water absorption capacity. Supplementation with MF improved the protein content of cookie samples while PMF led to an appreciable increase in crude fibre, β-carotene and total phenol contents. This study has confirmed that the production of acceptable cookies of high crude fibre, micronutrients and antioxidant sources that would help reduce the problems of malnutrition and diet-related non-communicable diseases is feasible through the optimization of the basic ingredients.

Development of Functional Candy with Banana, Ginger and Skim Milk Powder as a Source of Phenolics and Antioxidants

The present pandemic situation has increased the demand for plant-based functional foods that enhancing the immunity of all aged groups against COVID-19. This factor has led to innovation in confectionery market because healthy and good quality confectionery products are lacking. In this study, an attempt has been made to develop functional candy from various combinations of banana, ginger, skim milk powder, and honey at 2-10% and evaluated its sensory, nutraceutical, functional properties and microbial stability for 60 days. Among various combinations of banana and ginger pulp, candy prepared from 96:6 w/w (banana: ginger) ratio was found better than other combinations in respect to organoleptic and nutritional quality. Ginger and skim milk powder addition increased the contents of protein (4.54%), ash (2.82%), phenolic (8.59 mgGAE/g), flavonoid (2.43 mQ/g), and antioxidant activity (36.15% DPPH activity) of functional candy. Microbial studies of functional candy revealed it could be stored up to 60 days without microbial contamination and acceptable by the consumer. The cost of functional candy was Rs.1.53 per candy, which was less than market candy. This study showed that candy manufactured from banana, ginger, skim milk powder, and honey was nutritionally and economical improved with acceptable sensory properties. Developed functional candy increases the market's revenue and enables confectionary market to develop a new candy type.

Effect of Hulless Barley Flours on Dough Rheological Properties, Baking Quality, and Starch Digestibility of Wheat Bread

Hulless barley (Hordeum vulgare L.), also known as highland barley, contains nutritional compounds, such as β-glucan and polyphenol, which can be added to wheat flour to improve the dough nutritional quality. In this study, different formulated dough samples were obtained by individually adding four hulless barley flours into flour of a wheat variety (Jimai 44, designated as JM) which has very strong gluten. The effects of hulless barley supplementation on gluten structure, dough rheological properties, bread-making properties, and starch digestibility were assessed. The results showed that compared with JM dough, substitution of hulless barley flour to wheat flour at levels ranging from 10 to 40% negatively affected gluten micro-structure and dough mixing behavior, because the cross-links of gluten network were partially broken and the dough development time and stability time were shortened. For the hulless barley-supplemented bread, specific volume was significantly (P < 0.05) increased while springiness was not greatly changed. Furthermore, the hydrolysed starch rate in hulless barley-supplemented bread was decreased, compared with that in JM bread. Importantly, the contents of β-glucan, polyphenols and flavonoids in hulless barley-supplemented bread were 132.61-160.87%, 5.71-48.57%, and 25-293.75% higher than those in JM bread, respectively. Taken together, the hulless barley-supplemented bread has been fortified with enhanced nutritional components, more desirable bread-making quality, and improved starch hydrolytic properties, which shows a great potential to use hulless barley as a health supplement.

Effects of chitosan oligosaccharide and hyriopsis cumingii polysaccharide on the quality of wheat flour and extruded flour products

Abstract

Effects of chitosan oligosaccharide (COS) and hyriopsis cumingii polysaccharide (HCP) on the quality of wheat flour and corresponding extruded flour products were investigated in this work. The results showed that both COS and HCP are conducive to the improvement of dough quality. Moreover, compared to control group samples, the moisture content, expansion ratio and oil absorption rate of the samples were increased and the hardness were decreased with the addition of COS. These phenomena indicate the quality of extruded flour products became better in the presence of COS as well. However, HCP has little or no effect on the quality of extruded flour products may be due to its degradation under high temperature and pressure extrusion. COS with higher stability exhibited better improvement effects on the quality of extruded flour products and showed a promising prospect for application in extruded food industry.

Graphical Abstract

Rheological, textural, and technological modifications in wheat unleavened flatbread substituted with extruded finger millet

Finger millet incorporation in wheat flour increases the nutritional value of flatbread and provides health benefits. However, it also has a detrimental effect on the quality of flatbread. The present study evaluates the effect of extruded finger millet (EFM) over unextruded finger millet (UFM) flour on pasting, textural and rheological properties of composite dough and their impact on the quality of flatbread. EFM modified the dough handling properties leading to higher viscoelastic moduli and elastic share of compliance. In addition, a significant reduction in firmness and increment in extensibility of dough was also observed. The flatbread prepared by substituting 20% of EFM in wheat flour exhibited better puffing and lower resistance, shrinkage, and baking time in comparison to flatbread prepared with UFM at the same level of substitution. The sensory score for the same was at par with the control whole wheat flatbread. Results suggest that the substitution of EFM flour in composite dough maintains the rheological and technological quality of composite wheat flatbread.

Impact of wheat bran micronization on dough properties and bread quality: Part I - Bran functionality and dough properties

This study aimed to investigate the effect of wheat bran micronization on its functionality including physicochemical and antioxidant properties, and dough properties. Coarse bran (D₅₀ = 362.3 ± 20.5 μm) was superfine ground to medium (D₅₀ = 60.4 ± 10.1 μm) and superfine (D₅₀ = 11.3 ± 2.6 μm) bran, accompanied with increasing specific surface area and breakdown of aleurone layers. Bran micronization increased its soluble dietary fibre content, ferulic acid liberation, and antioxidant properties including total polyphenol content, ABTS•+ and DPPH• scavenging activities, while decreased its water retention capacity and insoluble dietary fibre content. Moreover, bran micronization impacted dough rheological properties. The dough with superfine bran had higher water absorption and gelatinization temperature, peak viscosity, final viscosity and setback value, lower stability time, resistance to extension, and extensibility than the dough with coarse bran. This dough furthermore exhibited more solid-like properties characterized by decreased loss moduli and frequency dependence (n').

The effect of additives combination on rheological properties of dough and quality of bread with Agaricus bisporus powder

The bread with Agaricus bisporus powder has the defects of poor texture and taste, so it is necessary to optimize the appropriate additives in order to improve its quality. The purpose of this study was to evaluate improvement of the combination of vital wheat gluten, sucrose fatty acid esters and cellulase on the improved Agaricus bisporus powder bread (IABPB), with wheat bread (WB) and bread with Agaricus bisporus powder (ABPB) as control. The results of rheological properties indicated the dough samples improved with three improvers had higher solid-like behaviour than the control sample. The results of nutritional quality analysis showed that the protein and dietary fiber content of IABPB was higher than those of WB and ABPB, but the fat content was relatively low. In addition, the additives combination could effectively improve the baking quality of ABPB. Compared with ABPB without additives, the specific volume increased by 21.22%, the brightness of bread crumb increased by 8.75%, but the crumb hardness decreased by 32.57%. Furthermore, the study on texture property and water migration during the storage showed that the addition of three improvers could delay the aging of bread. Therefore, it was feasible to use additives combination as a special quality improver for ABPB, which could effectively improve its quality.

Characterisation of Wheat–Oat Flour Extrudate: Physicochemical and Β-Glucan Attributes

The objective of this study was to evaluate the effect of wheat–oat flour ratio on the physical properties and β-glucan characteristics of extrudates. Results showed that increasing the wheat–oat flour ratio resulted in a decrease in the water solubility index (r2=0.8567) and hardness (r2=0.9316), whereas the expansion ratio (r2=0.9307) and water absorption index (r2=0.9061) increased. Wheat flour generally caused an increase in L values from 57.81 to 62.94 providing bright samples. Few cells were observed at high wheat–oat flour ratios under a scanning electron microscope, and a smooth surface was noted. Meanwhile, the total (r2=0.9867) and soluble (r2=0.9848) β-glucan contents were inversely proportional to the wheat–oat flour ratio. Extrudates with added wheat flour had a high molecular weight, but wheat flour had no significant (P<0.05) effect on the viscosity of β-glucan extracts. Conclusively, incorporation of wheat flour at a wheat–oat flour ratio of 2.33 provides ready-to-eat food based on whole oat flour, on account of improving the texture and providing sufficient β-glucan contents (0.806 g/100 g) without significantly affecting β-glucan viscosity.

Effect of spent brewer's yeast β-D-glucan on properties of wheat flour dough and bread during chilled storage

Effect of spent brewer's yeast β-D-glucan incorporation (0.25-2.00%, w/w wheat flour) on the characteristics of wheat flour dough and bread during chilled storage at 4 °C for 8 days was investigated. The dough containing 0.75% yeast β-D-glucan had the highest strength, work of adhesion, and stickiness. The addition of yeast β-D-glucan up to 0.75% yielded the breads with an appearance comparable to the control bread (without yeast β-D-glucan). The staling of bread was retarded by the addition of yeast β-D-glucan up to 0.75% as evidenced by the higher retained moisture content and cohesiveness and the lower L* value and hardness of the bread crumb during chilled storage compared to the control and the 1.00-2.00% yeast β-D-glucan breads. The 0.75% yeast β-D-glucan bread exhibited the lowest melting enthalpy of retrograded starch (ΔH_ret), the lowest B-type- and total crystallinities, the least microstructure change of the crumb matrix, and the highest consumer acceptance after 4 days chilled storage. These results suggested that the incorporation of an appropriate amount of yeast β-D-glucan could improve the quality and shelf life of bread or other starch-based food products during chilled storage.

Mixolab behavior, quality attributes and antioxidant capacity of breads incorporated with Agaricus bisporus

At present, some breads rich in edible mushrooms are more popular to meet the needs of functional bread products. In this study, different proportions of Agaricus bisporus powder (0, 2, 4, 6, 8%) were added into wheat flour to prepare bread, and their Mixolab behavior, bread quality and antioxidant capacity were studied. The results showed that the addition of Agaricus bisporus powder diluted the gluten in the flour, destroyed the dough matrix, which changed the water absorption of dough, the gelatinization and retrogradation of starch on the Mixolab. Meanwhile, the results of specific volume, texture and color measurement showed that addition of Agaricus bisporus powder reduced the specific volume of bread, deteriorated the texture and darkened the crumbs. In addition, the higher proportion of Agaricus bisporus powder, the higher total phenolics content and antioxidant ability of compound bread. However, sensory analysis showed that the overall acceptability of breads was relatively high after adding a small amount of Agaricus bisporus powder. Our results showed that breads containing about 4% Agaricus bisporus powder had higher antioxidant capacity and better sensory acceptability.

Functional and antioxidant properties of cookies incorporated with foxtail millet and ginger powder

The functional, sensory, nutritive, phytochemical and antioxidant properties of flours derived from wheat, foxtail millet and ginger along with the cookies formulated from these ingredients was studied. The foxtail millet (20, 30 and 40%) and ginger powder (5, 10 and 15%) blended wheat flours were investigated and compared to control (100% wheat flour). The increase in substitution levels of both the alternatives improved the functional properties of the composite flour and cookies formulated. Sensory analysis revealed that cookies prepared from 30% foxtail millet and 10% ginger powder had comparable scores. These were further subjected to nutritive and phytochemical analyses. The results revealed that cookies formulated using both the alternatives had reasonable proximate composition comparable to control. The substituted cookies had higher total soluble phenolic content and antioxidant capacities in terms of DPPH and ABTS scavenging potential and a strongly positive correlation was observed between the total soluble phenolic content and antioxidant capacities in composite flour and the cookies formulated from the flours. Overall the addition of foxtail millet flour (30%) and ginger powder (10%) improved the nutritional and phenolic linked antioxidant potential which can lead to shelf life extension and enhanced health benefits.

Effects of Blends of Low-Protein Winter Wheat Flour and Barley Byproducts on Quality Changes in Noodles

The physicochemical characteristics of fresh noodles made with blends of low-protein wheat flour and barley byproduct (BBP, 250 μm) were investigated. The crude protein contents (PC) of flour from Goso and Backjoong cultivars were 7.91% and 7.67%, respectively. PC and β-glucan contents from the BBP were 14.10% and 3.11%, respectively, which were higher than those in wheat flour. The water-holding capacity (WHC) of various blends was increased as a function of BBP but not gluten contents. Goso flour had the highest starch content (78.68%), with peak and final viscosities of 3,099 and 3,563 cp, respectively. Peak and final viscosities, trough, breakdown, and setback of the blends were decreased with the addition of BBP. Noodles made with Backjoong had the highest thickness score, while the hardness of noodles made with blends of Goso or Backjoong and 20% BBP were similar to those made from wheat flour only. The WHC of the samples was strongly correlated with PC, crude fiber, and β-glucan. The PC was not correlated with final viscosity, setback, thickness, hardness, gumminess, or chewiness.

Bread Staling: Updating the View

Staling of bread is cause of significant product waste in the world. We reviewed the literature of the last 10 y with the aim to give an up-to-date overview on processing/storage parameters, antistaling ingredients, sourdough technology, and measurement methods of the staling phenomenon. Many researchers have been focusing their interest on the selection of ingredients able to retard staling, mainly hydrocolloids, waxy wheat flours (WWF), and enzymes, but different efforts have been made to understand the molecular basis of bread staling with the help of various measurement methods. Results obtained confirm the central role of amylopectin retrogradation and water redistribution within the different polymers in determining bread staling, but highlighted also the importance of other flour constituents, such as proteins and nonstarch polysaccharides. Data obtained with thermal, spectroscopy, nuclear magnetic resonance, X-ray crystallography, and colorimetry analysis have pointed out the need to encourage the use of one or more of these techniques in order to better understand the mechanisms of staling. Results so far obtained have provided new insight on bread staling, but the phenomenon has not been fully elucidated so far.