Incorporation of chia seed flour into gluten-free rice layer cake: Effects on nutritional quality and physicochemical properties

The purpose of this research was to incorporate 0% to 30% chia seed flour into rice flour gluten-free layer cake and evaluate its effect on nutritional qualities and physicochemical properties. The supplement of chia seed flour resulted in higher batter viscosity, hardness of gluten free layer cake, crude protein, fat, ash, α-linolenic acid (increase up to 10.2% of total fatty acid), total phenolics content, and reducing power but the lower crust, crumb white index, cohesiveness, and resilience of gluten-free layer cake was found. Substitution of rice flour with 10% prehydrated chia seed flour can achieve a higher center height and volume index of gluten-free layer cakes. Higher carosine and angiotension I-converting enzyme (ACE) inhibitory activity was observed in the supplement of 10% chia seed flour when compared to a rice flour layer cake. Gluten-free layer cake with 10% prehydrated chia seeds flour had similar overall acceptability, texture, flavor, and odor scores except for lower appearance score to those of gluten-free layer cake made with 100% rice flour and layer cake made with 100% wheat flour. Incorporation of 10% prehydrated chia seed flour results in more desirable volume index of gluten-free layer cake and it is feasible for gluten-free layer cake application. Gluten-free layer cakes with improved quality characteristics and high nutritional value can be manufactured by the incorporation of chia seed flour.     

In vitro starch digestibility,expected glycemic index,and thermal and pasting properties of flours from pea,lentil and chickpea cultivars

In vitro starch digestibility, expected glycemic index (eGI), and thermal and pasting properties of flours from pea, lentil and chickpea grown in Canada under identical environmental conditions were investigated. The protein content and gelatinization transition temperatures of lentil flour were higher than those of pea and chickpea flours. Chickpea flour showed a lower amylose content (10.8–13.5%) but higher free lipid content (6.5–7.1%) and amylose–lipid complex melting enthalpy (0.7–0.8 J/g). Significant differences among cultivars within the same species were observed with respect to swelling power, gelatinization properties, pasting properties and in vitro starch digestibility, especially chickpea flour from desi (Myles) and kabuli type (FLIP 97-101C and 97-Indian2-11). Lentil flour was hydrolyzed more slowly and to a lesser extent than pea and chickpea flours. The amount of slowly digestible starch (SDS) in chickpea flour was the highest among the pulse flours, but the resistant starch (RS) content was the lowest. The eGI of lentil flour was the lowest among the pulse flours.     

Quality characteristics of angel food cake and muffin using lentil protein as egg/milk replacer

Replacement of animal proteins could be interesting for the food industry because it allows long‐term cost savings, among other reasons. Replacing egg/milk protein (50–100 wt%) by lentil protein (LP) was evaluated on angel cake/muffin quality. The replacement did not significantly affect final product volume, neither the muffins nor the angel food cakes. LP did not affect dough formation and contributed to hold crumb structure building an entangled network in both cake products. In addition, angel cakes and muffins containing LP had significantly lower baking loss than the control. Inferior quality for angel cakes and muffins containing LP was observed regarding hardness and chewiness that increased upon storage, compared to the control. For sensory evaluation in angel cakes, appearance of LP formulations showed lower scores than the control, likely due to the change of crumb colour. Other attributes were not significantly impacted by LP presence. For muffins, M‐100‐LPC formulation showed significant differences with the control for most of the attributes, except appearance and flavour. Indeed, consumers preferred muffins with 100% egg/milk protein replacement, which received higher acceptability scores than control. They also appreciated the ‘nutty’ flavour and moisture of angel cake with 50% egg protein replacement. This research suggests that lentil protein can totally or partially substitute egg/milk protein as foam and emulsion stabiliser in cakes, producing products with satisfactory quality.     

Navy Bean Flour Particle Size and Protein Content Affect Cake Baking and Batter Quality1

Whole navy bean flour and its fine and coarse particle size fractions were used to completely replace wheat flour in cakes. Replacement of wheat flour with whole bean flour significantly increased the protein content. The protein content was adjusted to 3 levels with navy bean starch. The effect of navy bean flour and its fractions at 3 levels of protein on cake batter rheology and cake quality was studied and compared with wheat flour samples. Batters prepared from navy bean flour and its fractions had higher viscosity than the cake flour. Reducing the protein content by addition of starch significantly lowered the viscosity of cake batters. The whole navy bean flour and coarse bean fraction cakes were softer than cakes made with wheat flour but had reduced springiness. Principal component analysis showed a clear discrimination of cakes according to protein. It also showed that low protein navy bean flour cakes were similar to wheat flour cakes. Navy bean flour with protein content adjusted to the level of cake (wheat) flour has potential as a healthy alternative in gluten‐free cakes.     

Addition of pin-milled pea flour and air-classified fractions in layer and sponge cakes

Legumes have interesting nutritional properties and many organizations, such as the World Health Organization, encourage their inclusion in the diet; their incorporation into bakery products could be a good method for increasing consumption. The aim of this study was to examine the addition of different percentages of pin-milled pea flour or its air-classified protein and starch fractions to sponge and layer cakes. Specific volume, pH and viscosity were measured in batters and specific volume, shape and texture in cakes. Evaluation through sensory analysis in a consumer test was performed after exclusion of the poorest cakes. Pin-milled pea-flour and starch-fraction cakes had similar specific volumes and firmness to wheat-flour cakes with substitution of up to 50% of the wheat flour in sponge cakes and up to 25% in layer cakes. In contrast, protein produced a lower cake specific volume and increased firmness at lower substitution percentages. Sensory acceptability decreased with increasing substitution percentages, and this was more pronounced in layer cakes. In sponge cakes, evaluations were similar to controls after substitution of 25% of the wheat flour by starch concentrate.     

Natural fermentation of lentils. Functional properties and potential in breadmaking of fermented lentil flour

The effects of fermentation on functional properties of lentil flour and rheological properties of doughs and breads produced from blends of wheat and fermented lentil flour were studied. Lentil protein solubility was higher at neutral pH than acid pH; the lowest and highest protein solubility values were observed at pH 4.0 and pH 7.0, respectively. Water hydration capacity and fat binding capacity of fermented lentil flour (FLF) were always higher than those of non-fermented lentil flour (NFLF), irrespective of fermentation temperature (28–42°C) and flour concentration (79–221 g/l). Emulsifying properties of NFLF were similar to the properties of other legume flours in the range used in experiment. In contrast, the emulsion capacity and stability of FLF were very low and flours fermented at 42°C did not even form emulsion. Rheological properties of doughs made from wheat-fermented lentil blends were similar to those from wheat flour with the addition of other legume flours such as pea and bean. Good quality breads were produced at 2.5 to 10% NFLF and FLF supplementation (except for bread with 10% FLF addition which was middle quality).     

Rheological,Physical, and Sensory Attributes of Gluten‐Free Rice Cakes Containing Resistant Starch

In this study the effect of resistant starch (RS) addition on gluten‐free cakes from rice flour and tapioca starch physical and sensorial properties was investigated. Increase in RS concentration made cake batters less elastic (drop of G'(ω), G''(ω) values) and thinner (viscosity decreased). Cakes specific volume increased with an increase in RS level and was maximized for 15 g/100 g RS, although porosity values were significantly unaffected by RS content. Crumb grain analysis exhibited a decrease in surface porosity, number of pores and an increase in average pore diameter as RS concentration increased. During storage, cake crumb remained softer in formulations with increasing amounts of RS. Sensory evaluation of cakes demonstrated the acceptance of all formulations, with cake containing 20 g/100 g RS mostly preferred. Gluten‐free cakes with improved quality characteristics and high nutritional value can be manufactured by the incorporation of RS.     

Effects of adding chickpea and chestnut flours to layer cakes

Chestnut and chickpea flours have interesting nutritional characteristics and can be incorporated into layer cake formulations. This study aims to evaluate the effect of incorporating mixtures of these flours with wheat flour in the elaboration of layer cakes. With this aim, layer cakes were elaborated with the three different flours. Mixes of 50% of these flours and a mixture of the three flours in the same proportion were analysed. Batter density, microstructure and viscosity, as well as the specific volume, texture and acceptability of layer cakes were evaluated. Chickpea flour reduced the batter density and increased viscosity compared to wheat flour, while chestnut flour reduced viscosity and did not clearly affect density. Although both flours produced layer cakes with lower specific volume, as well as less cohesive and springiness, the effect on specific volume was clearer in chestnut flour. With 50% of chickpea flour, it was possible to obtain layer cakes with the same specific volume and hardness as those made with wheat flour. Layer cake acceptability decreased with the reduction in wheat flour, regardless of the type of flour incorporated. No improved acceptability has been found when combining chickpea and chestnut flours.     

Physical and nutritional evaluation of wheat cookies supplemented with pulse flours of different particle sizes

With the aim to develop functionally and nutritionally improved cookies, the influence of the total or partial replacement of wheat flour by pulses flours on the quality characteristics of cookies was analysed. Blends containing 25, 50, 75 and 100 g/100 g of navy bean, pinto bean, green lentil and commercial yellow pea flours were prepared. Green lentil, navy and pinto bean flours were used at two degrees of milling (fine and coarse). The incorporation of pulse flours significantly affected the physical and chemical parameters of the cookies. Incorporation of fine flours remarkably increased cookies’ hardness and decreased spread while coarse flours marginally reduced both parameters. The greatest impact on the physical characteristics was observed with the incorporation of green lentil flour, where cookies made with coarse flour were of unacceptable structure and were sticky to handle. Cookies baked with pulse flours were higher in protein level and showed increased antioxidant activity compared to the control. Overall analysis indicated that cookies with acceptable physical characteristics and improved nutritional profile could be produced with partial or complete replacement of the wheat flour.     

Influence of Flour Particle Size on Quality of Gluten-Free Rice Cakes

There is a growing interest in developing gluten-free bakery products in recent time. In cake making, gluten network formation is not essential, but hardly any information exists about the influence of the gluten-free flour characteristics affecting the final cake product. This study analyses the influence of two different rice cultivars (short and long) with different flour particle size in batter characteristics (specific volume, viscosity and internal structure) and in sponge and layer cake formulas (volume, shape, texture and colour). During starch gelatinization, the finest flours (median particle size finer than 100 μm) increased their viscosity and reached the peak viscosity (RVA) later than the coarsest flours. Moreover, the finest flours gave batters with lower specific volumes but with an air distribution in smaller and uniform bubbles in both formulas. These flours also produced higher volume and lower firmness in sponge cakes and greater symmetry index both in sponge and layer cakes. The rice type also influenced batter and cakes characteristics but in a lesser extent. The different results obtained depending on the rice flour particle size, type flour and cake formulation indicate the need to define them both in industrial specifications and in research studies.     

Development of gluten-free cracker snacks using pulse flours and fractions

With nearly two million North Americans suffering gluten intolerance, the objective of this study was to develop gluten-free, pulse-based cracker snacks that exploit the anti-allergenic and health-enhancing nature of pulses ingredients. Nine commercially available pulse fractions (chickpea, green and red lentil, yellow pea, pinto and navy bean flours and pea protein, starch and fibre isolates) were evaluated in a model cracker formulation. Early prototype crackers exhibited light colour, good flavour, and crisp texture. Based on its acceptability data, processing characteristics and consultation with an industry partner, the chickpea cracker formulation was advanced to a commercial-scale processing trial. The physical and nutritional characteristics of these pulse crackers were similar to existing products on the market. The products were scored highly during consumer acceptance testing. Interestingly, the % daily values per serving of iron in the chickpea crackers were 3–6 times higher than existing products. Based on these findings, pulse-based, gluten-free crackers have good potential for both consumer appeal and imparting health benefits.     

Studies of the quality of cakes made with wheat-lentil composite flours

Legume flours, due to their amino acid balance and their demonstrated nutritional benefits, are ideal ingredients to improve the nutritional characteristics of bakery products. We have studied the inclusion of lentil flour on layer and sponge cakes, and its effect on the characteristics of the batter and of the final product. The addition of lentil flours reduced the density of layer-cake batter but increased the density of sponge-cake batter. This effect was greater with the smaller flour-particle size. Adding lentil flour to the formula reduced layer-cake volume, symmetry index, cohesiveness and springiness and increased hardness. In sponge cakes, no clear tendencies were observed in volume or symmetry index, but the total substitution of wheat flour by lentil flour gave rise to harder and less cohesive cakes. The use of lentil flour with a fine particle size increased cake volume but reduced hardness, particularly in sponge cakes.     

A model approach to starch and protein functionality in a pound cake system

Different modified wheat starches were used in a model pound cake recipe. The properties of the starches were linked to differences in batter viscosity, cake height and protein extractability during baking, collapse during cooling and final cake quality. The impact of incorporation of 30% cross-linked (CL) starches on batter properties during baking was much smaller than that of incorporation of the same level of hydroxypropylated (HP) starches. Incorporation of HP starches with various degrees of modification in the recipe caused batter viscosity during baking to start rising from 92 or 88 °C rather than at 96 °C and diminished oven rise significantly. Furthermore, the extractability of the protein in cakes containing HP starch was significantly higher. During cooling, control cake collapsed less than did CL starch-containing cake, which itself collapsed significantly less than did HP starch-containing cake. Presumably, most of the cake collapse takes place before the starch gel is formed during cooling. Protein and starch apparently function in determining cake quality, by providing the cell walls with structural material and high resistance to collapse. Starch does not prevent cake collapse, but still co-determines crumb structure, whereas a strong correlation was found between the gel-forming capacity of starch blends and intrinsic crumb firmness (r = 0.99). Furthermore, a strong negative correlation was found between springiness and percentage of extractable protein in final cakes (r = −0.95). We conclude that the combination of a protein network, formed during baking, with a starch gel, formed during cooling, makes up the crumb cell walls and determines cake quality.     

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).     

Studies on cake quality made of wheat–chickpea flour blends

Legume flours, due to their amino acid composition and fibre content are ideal ingredients for improving the nutritional value of bread and bakery products. In this study, the influence of the total or partial replacement of wheat flour by chickpea flour on the quality characteristics of two kinds of cake was analyzed. The effects of the chickpea variety and the kind of flour used (white or whole) were also considered. Volume, symmetry, chroma, and crust and crumb L^* diminished when increasing the amount of chickpea flour. The replacement of wheat flour by chickpea flour also induced an increase in the initial firmness but cohesiveness and resilience diminished, increasing the tendency to hardening. Among the studied varieties, Pedrosillano and Sinaloa produced cakes with the highest volume. Those varieties also gave layer cakes with the lowest firmness, gumminess and chewiness. White flours produced sponge cakes with higher volume and symmetry than whole flours. No significant differences, however, were observed in layer cakes between white and whole flours. In both layer and sponge cakes, white flour produced cakes with lower firmness, gumminess and chewiness than whole flours.     

Optimization of Baking of Rice Cakes in Infrared–Microwave Combination Oven by Response Surface Methodology

In this study, response surface methodology was used to design gluten-free cakes made from rice flour to be baked in infrared-microwave combination oven. Two types of cake formulations containing different types of gums were used in the experiments, which were xanthan gum and xanthan–guar gum blend. The independent variables were emulsifier content (0, 3, and 6% of flour weight), upper halogen lamp power (50, 60, and 70%), and baking time (7, 7.5, and 8 min). Specific volume, surface color change, firmness and weight loss of the cakes were determined for optimization. Cakes formulated with xanthan gum had better quality characteristics than cakes containing xanthan–guar gum blend. Cakes formulated with xanthan gum and 5.28% emulsifier and baked using 60% halogen lamp power for 7 min had the most acceptable quality.     

Optimisation of protein-enriched gluten-free layer cakes using a mixture design

The effect of different protein mixtures (pea, whey and egg white proteins) on the physical characteristics of batters and baked gluten-free layer cakes after substituting 45% of flour was evaluated. A mixture design approach was used to determine the interaction effects of the three proteins on the cakes physical characteristics. For batter density, two interactions were observed, and higher values were found for batters containing a mixture of 60–80% egg white and 20–40% whey than in batter containing only one of these proteins, or a pea content of 70–90% than in batter containing only pea. For batter viscosity, significant interactions between egg white and pea, and between whey and pea proteins were observed, which explains the gentler decrease in viscosity at higher egg white and/or whey protein ratios. Regarding hardness, an interaction between egg white and whey occurred, and increasing whey content helped to reduce hardness to a greater extent than increasing pea content.     

Original article: Influence of flour mill streams on cake quality

Wheat‐milling process generates different flour streams that differ in particle size, composition and functional and cake‐making properties. Particle size, composition and pasting properties of flour fractions (two from break and three from reduction system) obtained during milling of three wheats varying in protein content were determined. Shape, textural, colour and sensory analyses were performed on cakes prepared with the different mill streams. The final break and reduction streams had the highest protein and ash contents, pasting temperatures and the lowest starch percentage. Cakes prepared with the last streams showed higher batter density and lower volume. These results could indicate good air incorporation but deficient air distribution. Last streams cakes showed a darker, more reddish and yellowish crumb that was significantly related to flour colour characteristics. Because of these differences, such cakes obtained the lowest sensory scores. In this study, it has been verified that, to adapt flours to cake preparation, the final streams should be eliminated. The particle size of each stream is the most determinant parameter to obtain cakes with better volume and texture, being the flours with small particle size the most adequate.     

Potential of teff (Eragrostis tef) flour as an ingredient in gluten-free cakes: chemical,technological and sensory quality

This article aimed to evaluate the chemical, technological and sensory characteristics of gluten-free cakes made with teff (Eragrostis tef). Four cakes were evaluated: T1, 100% teff flour; T2, 75% teff flour, 12.5% rice flour, 12.5% cassava starch; T3, 50% teff flour, 25% rice flour, 25% cassava starch and T4, 25% teff flour, 37.5% rice flour, 37.5% cassava starch. Higher percentages of teff increased total ash. For apparent and specific volumes, T4 was the one with the highest mean. In sensory analysis, the attributes of appearance, colour and odour did not have significant difference among treatments. T1 received the lowest overall average for flavour (5.03). Regarding the purchase intention, the cakes did not show significant difference between T3 and T2 (3.25 and 3.08). T2, T3 and T4 obtained acceptance index higher than 70%. The use of teff flour in cakes can be promising in gluten free diet.