Formulation optimisation of gluten‐free functional spaghetti based on quinoa,maize and soy flours

In this work, the formulation of non‐conventional gluten‐free fresh and dry pasta based on quinoa, maize and defatted soy was optimised. Results showed that the dough samples with high content of maize had the higher value of elongation and shear viscosity and then increased dough firmness. The pre‐gelatinised maize content also affected the rheological properties by increasing the dough firmness. Regarding the dry spaghetti sensorial properties, the surface response plot showed that the overall acceptability of both non‐cooked and cooked spaghetti increases with the increase of the pre‐gelatinised maize content and the decrease of the quinoa flour, whereas the soy flour did not affect the overall quality. In particular, the pre‐gelatinised maize improved the resistance to break and the taste of non‐cooked and cooked spaghetti, respectively. Regarding the fresh spaghetti, results showed that the overall acceptability for fresh non‐cooked spaghetti increases with the increase of the pre‐gelatinised maize content and with the decrease of the quinoa flour; whereas, only the pre‐gelatinised maize content affected the overall acceptability of fresh cooked spaghetti.     

Effect of pulse flours on the physiochemical characteristics and sensory acceptance of baked crackers

Pulse flours offer nutritional alternatives to wheat flour in the production of baked snacks due to their high protein and fibre levels and low glycaemic index. In this study, broad‐bean (Vicia faba), yellow‐pea and green‐pea (Pisum sativum) flours were each blended with wheat flour at 40% in the formulation of chemically leavened crackers. The effects of flour type and baking time on the physiochemical properties, sensory acceptability, nutritional composition and antioxidant activity of the crackers were observed in comparison with 100% wheat crackers. Broad‐bean crackers had the highest protein content and antioxidant activity (13 g per 100 g DM and 38.8 mgAAE per 100 g DM, respectively). Yellow‐pea crackers had the highest fibre content (12 g per 100 g DM). Physical dimensions and colour attributes were significantly affected by pulse‐flour substitution. Yellow‐pea and broad‐bean crackers were significantly preferred by consumers compared to the control, demonstrating the potential application of these flours to improve the eating quality and nutritional profile of crackers.     

Utilisation of pigeon pea (Cajanus cajan L) byproducts in biscuit manufacture

Biscuits were prepared by substituting wheat flour with dehulled pigeon pea (Cajanus cajan L) flour (PPDF) or pigeon pea byproduct flour (PPBF). PPBF was obtained by recovering edible cotyledon material from milling byproducts. PPBF had a higher level of protein (29.42 g/100g) compared to PPDF (24.67 g/100g). Composite flour blends were prepared by substituting wheat flour (WF) with either PPDF or PPBF at 95:5, 90:10, 85:15, 80:20 and 75:25 incorporation levels. Biscuits were analysed for composition, physical and sensory parameters. Protein content of PPDF and PPBF fortified biscuits increased by 1.3 and 1.4 times respectively compared to control along with a significant increased in fibre content. Results indicate that good quality biscuits with increased levels of protein and fibre can be prepared by substituting wheat flour using 85:15 of PPDF or 90:10 of PPBF without significantly affecting the sensory quality of biscuits. This study demonstrates the potential feasibility of incorporating pigeon pea milling byproducts in the manufacture of biscuits.     

Nutritional and physicochemical characteristics of wholemeal bread enriched with pea flour

In this work, wholemeal bread enriched with hydrated and nonhydrated pea flour was investigated. Moreover, hydrocolloids, such as hydroxypropylcellulose, agar‐agar and guar seed flour, were added to the bread to improve its organoleptic properties. The bread samples were analysed from the nutritional, microstructural and textural properties point of view, and their correlations were also evaluated. Results showed that guar gum at 2% gave the better results. In particular, the overall quality of the bread enriched with hydrated pea flour and guar gum was statistically similar to that of the CTRL reference sample (7.70). The fibres and ash content of all pea‐enriched bread samples were significantly higher compared with the CTRL sample; moreover, all functional bread samples recorded significantly lower glycaemic response with respect to the CTRL sample. In addition, the mixture of both guar gum and hydrated pea flour significantly improved the dough properties and reduced the firmness of the bread.     

The effect of pea (Pisum sativum L.)‐originated asparaginase on acrylamide formation in certain bread types

The aim of this study was to investigate the effect of pea (Pisum sativum L.)‐originated asparaginase on acrylamide formation in white wheat, wheat bran and whole‐grain wheat breads. Two‐day germinated pea flour was used at 0%, 1%, 3% and 5% levels for each bread type. Acrylamide analysis was performed with liquid chromatography–mass spectrometry. Besides, colour and sensory properties of the breads were evaluated to search out the effects of pea flour substitution on the consumer acceptance. Reduction of acrylamide in white wheat bread was not found significant and addition of pea flour decreased the acceptance. However, it was found that acrylamide level can be reduced by 57% and 68% with addition of 5% pea flour in wheat bran and whole‐grain breads, respectively, without any negative impact on colour and sensory properties.     

Effects of cricket powder on selected physical properties and US consumer perceptions of whole-wheat snack crackers

Successful introduction of insect consumption to a reluctant US population requires novel insect-based foods that are responsive to consumers’ expectations of sensory quality. Based on our ‘product appropriateness’ data, snack crackers were formulated with increasing levels of cricket powder (0%, 5%, 10%, 15%, and 20%) in substitution of whole-wheat flour. Colour, texture, flavour and overall perceptions of snack crackers were evaluated by 150 US consumers in terms of preference (2-alternative choice), degree of liking (9-point scale) and acceptability (yes/no). Flavour liking was most highly correlated with overall liking (r = 0.93). Instrumental analyses indicated that increasing cricket powder resulted in darker and harder crackers, negatively impacting colour and texture preference at 5% and 15% cricket powder addition, respectively. Snack crackers remained acceptable at 15% wheat flour substitution (80% acceptability; mean overall liking = 5.5). However, to promote future consumption, an upper limit of 7.9% cricket powder addition is recommended until sensory quality can be improved.     

Total phenolic and total flavonoid content,antioxidant activity and sensory evaluation of pseudocereal breads

The aim of the study was to investigate the effect of adding (in two different doses 15% and 30%) pseudocereal (buckwheat, amaranth and quinoa) flour on the antioxidant properties and sensory value of breads. Buckwheat flour had the highest phenolic content (7.25 ± 0.23 mg/g dw). The content of total flavonoids in flours was about 2–4 fold higher when compared to breads. The addition of buckwheat flour to wheat bread, particularly in higher dose, was more effective in enhancing antioxidant activity, as evaluated by means of FRAP and DPPH, which increased by 2.36 fold, and 3.64 fold respectively, in comparison with other pseudocereal flours (amaranth, quinoa), which caused, in higher doses, the changes of above parameters within the ranges 1.20–1.79 fold, and 0.60–1.71 fold. Analysis of sensory results of breads showed that addition of buckwheat flour to the dough might improve subjective properties of bread and increase acceptable quality attributes such as taste, colour or odour. All these observations suggest that addition of buckwheat flour into bread can improve antioxidant as well as sensory properties of bread. Bread fortified with pseudocereal flours, and especially with buckwheat flour, may be placed on the market as a functional food.     

Fortification of pasta with split pea and faba bean flours: Pasta processing and quality evaluation

Nutritionally enhanced spaghetti was produced by adding high amounts (35% db) of legume flour (split pea or faba bean) to durum wheat semolina. The production of fortified pasta required an adaptation of the pasta making process (higher hydration level and mixing speed) to limit agglomeration of particles during mixing. Moreover, addition of legume flour induced a decrease in some pasta quality attributes (e.g. higher cooking loss, lower breaking energy). This could be attributed to the introduction of non-gluten proteins and insoluble fibres which weakened the overall structure of pasta. A modification of the sensorial properties including higher hardness and higher fracturability were also observed. Some quality attributes (e.g. lower cooking loss) of fortified pasta were improved by applying high and very high temperatures during the drying cycle, reflecting strengthening of the protein network. However, these treatments resulted in excessively firm and rubbery pasta according to the panelists.     

Effect of the Addition of Common Bean (Phaseolus vulgaris L.) Flour on the In Vitro Digestibility of Starch and Undigestible Carbohydrates in Spaghetti

Abstract: Spaghetti is considered to be a slowly digestible starch food, a feature ruled by the particular physical properties of the product. Several studies have been reported to increase nutritional value of spaghetti, using legumes. We have studied the addition of common bean flour on the starch in vitro digestibility. Spaghetti was prepared with semolina and different concentrations of common bean flour (0%, 15%, 30%, and 45%, w/w). Proximate analysis, optimal cooking time, and cooking loss were estimated in crude spaghetti. Total, available, and resistant starches, indigestible fractions, and in vitro starch hydrolysis kinetics were accomplished in cooked spaghetti. Pasta with 30% and 45% of common bean flour showed higher values of protein. Particularly, the lowest cooking time was observed for composite spaghetti with 45% of common bean flour. There was a significant increase in cooking loss when common bean flour in the composite was added. Composite spaghetti samples with increasing common bean flour showed decreasing values of total starch but an important increase in the resistant starch (RS) level and indigestible insoluble fraction values. Plain pasta made with semolina showed the highest enzymatic hydrolysis rate, which decreased when common bean flour was added to the spaghetti. Spaghetti with a higher level of common bean flour was more slowly available, which may have positive implications for human health.     

Cooking quality characterisation of ‘spaghetti’ based on soft wheat flour enriched with oat flour

The cooking quality of pasta based on soft wheat flour and supplemented with three percentages of oat flour was studied. Results showed that oat flour modified deeply the cooking quality of spaghetti in comparison with samples based on only soft wheat flour. These effects were attributed to both starch‐lipid complex formation and presence of β‐glucans that weak gluten network. An increase in optimal cooking time with increase in oat percentages was observed (480 vs. 630 min). Samples enriched with oat flour showed a good‐quality cooking total organic matter (TOM values ranged from 1.4 to 2).     

Effects of increasing levels of transglutaminase on cooking quality of bran supplemented spaghetti

This study investigated the possibility of incorporating high levels of bran into spaghetti formulation by using transglutaminase (TG)—catalyzed crosslinking, without deterioration in spaghetti quality. Two durum wheat samples and one bread wheat sample were milled to semolina or farina. Ground mixture of coarse and fine brans of each cultivar was substituted for a portion of semolina or farina obtained from the respective cultivar, at the levels of 15 and 30% and then processed into spaghetti. Bacterial TG was added to the spaghetti formula at the levels of 0.2% and 0.4% (w/w). The results indicated that the TOM values and the sensory characteristics of the spaghetti were generally affected by the cultivar, bran supplementation, and TG addition level. The samples with TG exhibited significantly lower scores for TOM and higher sensory scores for firmness, stickiness, and bulkiness when compared with the respective control sample of each cultivar. As a result, transglutaminase addition had a significant improving effect on spaghetti quality which was more obvious in the weaker cultivar and it was possible to overcome the deteriorative effects of bran on spaghetti quality.     

Effect of Incorporating Taro (Colocasia esculenta), Rice (Oryza sativa), and Pigeon Pea (Cajanus cajan) Flour Blends on Noodle Properties

Noodles were produced by blending varying proportions (20, 30, 40, 50, and 60% levels) of taro flour with remaining equal proportions of rice and pigeon pea flour, which were evaluated for anti-nutritional, cooking, textural, and sensory properties and possible correlations between various noodles' properties were established using principal component analysis. Anti-nutritional evaluation of noodles revealed a decrease in phytic acid content, as the percentage of taro flour in the noodles increased. Pasting properties of the blends were also measured, which differed significantly (P < 0.05). Taro flour addition produced noodles with decreased gumminess, adhesiveness, b* value, and increased a* value as compared to the control sample (100% wheat flour). Significant correlations among various noodle properties were established using principal component analysis. Texture and color can be adopted as distinguished parameters for analyzing the noodle samples using a principal component analysis loading plot. Noodles containing 50% taro flour, with remaining equal proportions of rice and pigeon pea flour, resulted in the highest scores for color, taste, firmness, and overall acceptability.     

Simplex lattice mixture design approach on physicochemical and sensory properties of wheat chips enriched with different legume flours: An optimization study based on sensory properties

In this study, physicochemical and sensory characteristics of wheat chips enriched with different legume flours were investigated. Wheat chips formulations were composed with the mixture of wheat flour and the mixture of three different legume flours (wheat–legume ratio 80:20). Mixture design approach was used to determine the effect of interactions between pea, chickpea and soy flour on the physicochemical and sensory properties of chips produced with wheat–legume flour mixture. In addition, product optimization was carried out by using ridge analysis to determine the optimum legume flour mixture proportions based on sensory properties of chips samples. Chickpea flour was found to be highest desired component depending on the general acceptability scores of chips. Protein content of chips increased significantly with the addition of soy flour. Optimum limit values of chickpea, pea and soy flour in the legume flour mixture used for the enrichment of the wheat chips were found to be 50–100 g/100 g, 0–60 g/100 g and 0–45 g/100 g legume flour, respectively, with respect to sensory properties. Additionally, ridge analysis results showed that the wheat chips should include only chickpea flour in the legume flour fraction to obtain maximum overall preference score (6.08).     

Effects of hydrocolloids on chemical properties and cooking quality of gluten‐free spaghetti

The effects of different hydrocolloids on chemical composition and cooking quality of spaghetti based on maize and oat flours were investigated. Rheological and texture properties of the gluten‐free dough were also assessed. Amount of 2% of gellan gum, carboxymethylcellulose, pectin, agar, egg protein powder, tapioca starch, guar seed flour and chitosan were separately added to the formulation. The samples enriched with hydrocolloids generally showed a different rheological behaviour compared with the control samples. As regards chemical composition, spaghetti with chitosan showed a value of insoluble dietary fibres (8.0%) higher than the control ones (3.9%). Moreover, results highlighted that most hydrocolloids improved cooking quality and texture properties of spaghetti (adhesiveness, cooking loss, hardness), thus supporting their application in gluten‐free pasta.     

Sunflower protein concentrate: A possible and beneficial ingredient for gluten-free bread

The global demand for gluten-free products increased and resulted in a significant technological challenge for the bakery industries: producing gluten-free bread with similar quality to wheat bread. This study aimed to analyze the effects of different concentrations of sunflower protein concentrate (SPC) addition on the gluten-free bread quality parameters compared to the use of pea flour. The SPC flour was inserted at 5%, 10%, and 20% on a flour basis mixture (70% rice flour and 30% cornstarch). Some parameters as specific volume, color, and texture profile were evaluated during 21 days of storage. The obtained results showed that SPC has a significant potential to be used in gluten-free bread with high quality and sensory acceptability. The addition of this beneficial ingredient, in all concentrations, resulted in gluten-free bread with lower hardness after 21 days of storage and with a 100% increment in the protein content when compared to pea flour bread.     

Phenolic profile and carbohydrate digestibility of durum spaghetti enriched with buckwheat flour and bran

The potential of common buckwheat flour (Supreme) and bran (Farinetta) in improving upon the phenolic and antioxidant properties of durum spaghetti was investigated. The cooking quality and carbohydrate digestibility of products were also studied. Significantly large increments of between 114 and 522% for total phenolic content (TPC), 50 and 242% for total flavonoids content (TFC), and over 359% for 2,2-diphenyl-1-picrylhydrazyl (DPPH) antioxidant activity were recorded for uncooked experimental spaghetti samples over the control. Farinetta contributed more phenolic and antioxidant compounds than Supreme flour. Processing and cooking resulted in decreases in phenolic content and antioxidant activity. Cooking losses of up to 8.8% were recorded for the experimental samples and were higher in Farinetta-substituted products. These were generally higher than that of the control (6.3%). The introduction of buckwheat increased carbohydrate digestibility of products, but at the same time, resulted in an overall lower amount of reducing sugars after 120 min of in vitro hydrolysis. Results show that the phenolic and antioxidant properties of durum spaghetti fortified with buckwheat milling fractions can compare favourably with those of 100% whole buckwheat soba pasta, and at the same time, maintain a higher cooking quality due to the presence of semolina.     

Gluten‐Free Precooked Rice‐Yellow Pea Pasta: Effect of Extrusion‐Cooking Conditions on Phenolic Acids Composition,Selected Properties and Microstructure

Rice/yellow pea flour blend (2/1 ratio) was used to produce gluten‐free precooked pasta using a single‐screw modified extrusion‐cooker TS‐45. The effect of moisture content (28%, 30%, and 32%) and screw speed (60, 80, and 100 rpm) on some quality parameters was assessed. The phenolic acids profile and selected pasta properties were tested, like pasting properties, water absorption capacity, cooking loss, texture characteristics, microstructure, and sensory overall acceptability. Results indicated that dough moisture content influenced all tested quality parameters of precooked pasta except firmness. Screw speed showed an effect only on some quality parameters. The extrusion‐cooking process at 30% of dough moisture with 80 rpm is appropriate to obtain rice‐yellow pea precooked pasta with high content of phenolics and adequate quality. These pasta products exhibited firm texture, low stickiness, and regular and compact interne structure confirmed by high score in sensory overall acceptability.     

加水量对豌豆挂面品质的影响

研究加水量对豌豆挂面品质的影响规律,为豆类挂面加工中加水量的选择提供依据。以黄豌豆全粉为研究对象,将豆粉按照15%和25%的添加量与小麦粉混合,添加不同加水量制作成豌豆挂面,并对豌豆挂面品质进行分析。结果表明:当豌豆粉添加量为15%时,随着加水量的增加,干面条的光泽度和表观状态得分无显著性差异,面片颜色变暗;煮后面条的干物质损失率、感观评价的各项评分均无显著性差异。当豌豆粉添加量为25%时,随着加水量的增加,干面条的光泽度和表观状态得分增加,干物质吸水率和干物质损失率均呈下降趋势。加水量在32%和34%时,质构特性和微观结构优于其他加水量。28%加水量的挂面,其微观结构的表面和截面都非常粗糙,感观评价的总分最低,为77.2分。因此,豆粉添加量在15%时,适宜加水量为32%~36%;添加量在25%,适宜加水量为32%和34%。     

Cooking behaviour and acceptability of composite pasta made of semolina and toasted or partially defatted soy flour

The effects of the replacement of increasing amounts of semolina with toasted or partially defatted soy flour on dough rheological indices and spaghetti quality were evaluated. The replacement caused the dough weakening and the increase of the tenacity-extensibility ratio. Due to the competition of soy proteins and starch for water, the substitution of increasing amounts of semolina was able to increase the optimal cooking time without significant changes of the ratio between the increase in weight or diameter and the weight or diameter of dry spaghetti (ΔP/P and ΔD/D) but with a significant slowing of the ΔL/L (ratio between the increase in length and the length of dry spaghetti) increase during overcooking. Around the optimal cooking time, the release of organic matter was higher in pasta made exclusively of semolina whereas the sensory response was similar for control and composite spaghetti. Statistically significant correlations were obtained between protein content of the flour mixtures or dough alveographic indices and the cooking behaviour of semolina-soy spaghetti according to non-linear regression models. In particular, both protein content and alveographic indices allowed to predict approximately 92-94% of the variation of cooking losses and, in a lower measure, the variation of bulkiness and elasticity of semolina-soy spaghetti.