Effect of using Erythritol as a Sucrose Replacer in Making Spanish Muffins Incorporating Xanthan Gum

Spanish muffins are sweet, high-calorie baked products which are highly appreciated for their good taste and soft texture. The aim of this work was to evaluate the suitability of erythritol and of its combination with xanthan gum and double quantities of leavening agent for replacing sucrose in Spanish muffins and to understand their functionality in a muffin system. The linear viscoelastic properties of the batter during heating, its specific gravity and bubbles, muffin weight loss during baking and muffin bubbles, height, volume, and instrumental texture were studied. Both erythritol and sucrose increase in the temperature at which the viscoelastic functions increased with temperature. In comparison with the reduced sucrose muffins, the use of erythritol increased the number of air bubbles in the batter. The height of the muffins also increased in the presence of erythritol when compared to the corresponding reduced sucrose muffins, although the volume did not. Erythritol was not effective in diminishing the increased hardness associated with sucrose reduction, but the combination of erythritol with xanthan gum and a double quantity of leavening agent significantly improved the muffin volume (from 94 cm³ for 100% erythritol formulation to 108 cm³ for 100% erythritol–xanthan double-leavening agent formulation) and significantly decreased the hardness (from 75 N for 100% erythritol formulation to 25 N for 100% erythritol–xanthan double leavening agent formulation).     

Quality Attributes of Muffins: Effect of Baking Operative Conditions

Muffins are sweet baked products highly appreciated by consumers because of their soft texture and characteristic taste. The aim of this work was to study the influence of baking conditions on muffins’ quality. Surface crust color was monitored during baking tests at oven temperatures ranging from 140 to 220 °C, and browning kinetics was modeled by means of a browning index, BI, which follows a logistic model; a joint analysis of core temperature profile and BI curve can assist in the prediction of baking time. Finally, weight loss, crust/crumb ratio, crumb and crust moisture content, porosity, crumb and global densities, and texture were measured in the already baked muffin. The water content in the crumb remains almost constant, while considerable dehydration occurs in the crust. Finally, the results showed that intermediate oven temperatures led to a more porous, aerated, and soft crumb, with intermediate textural properties.     

Characterisation of chickpea flour‐based gluten‐free batters and muffins with added biopolymers: rheological,physical and sensory properties

Chickpea flour (CF)‐based muffin formulations were made with CF alone and with added biopolymers [whey protein (WP), xanthan gum (XG) and inulin (INL)] to evaluate their suitability to be a wheat flour (WF) substitute in muffins. Structural characteristics of the batters and muffins were studied by means of rheometry, microscopy, physicochemical properties, and texture and sensory analysis. Partial replacement of CF with XG, alone (at 0.5 and 1%) or blended with either WP or INL, significantly increased the batter viscoelasticity as denser matrices developed; moreover, the muffins with XG added at 1% had similar hardness to wheat gluten muffins. The replacement of WF decreased the springiness, cohesiveness, chewiness, resilience and specific volume of the muffin. However, baked muffins with added XG also showed higher sensory sponginess and moisture associated with numerous air bubbles in the batter and were perceived to be easier to swallow and to have better general appearance.     

Influence of water chestnut (<Emphasis Type="Italic">Trapa natans</Emphasis>) on chemical,rheological, sensory and nutritional characteristics of muffins

Water chestnut flour (WCF) was utilized in the formulation of muffins. Blends were prepared by replacing 25, 35, 45 and 55 % of wheat flour with WCF. Farinograph characteristics of the blends showed that with increase in the level of WCF there was a decrease in the dough stability and increase in mixing tolerance index, indicating weakening of the dough in comparison to control. Pasting characteristics indicated increase in gelatinization temperature and peak viscosity of the blends. Micrographs of muffin crumb prepared by incorporating WCF showed gelatinized starch granules embedded in the disrupted protein matrix. The lightness value of muffin crumb and sensory scores for crust color, shape, crumb color, grain and texture decreased with increase in the level of WCF in muffins when compared to control. However the 55 % WCF incorporated muffins received significantly lower scores for overall quality. Incorporation of WCF at 45 % level produced muffins of acceptable quality.     

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.     

Effects of lupin incorporation on the physical properties and stability of bioactive constituents in muffins

Germinated Australian sweet lupin (ASL) flour (after germination for 7 days) was incorporated into muffin formulation at 0%, 2%, 4%, 6% and 8% of dried muffin weight. The effect on the physical characteristics of muffins including height, diameter, colour and texture (hardness, cohesiveness, springiness and chewiness) was measured. The stability of phenolic, phytosterol compounds and the antiradical activity of the muffins before and after baking (190 °C, 25 min) were determined. The level of incorporation of germinated ASL flour affected the volume, colour, hardness and muffin texture. Muffins incorporated with germinated ASL flour at the levels used in this research exhibited higher concentrations of total phenolic compounds, phytosterol and antiradical activity than those in control muffins. The baking process did not significantly reduce the phenolic compounds, phytosterol and antiradical activity.     

Effect of Nutriose on Rheological, Textural and Sensorial Characteristics of Spanish Muffins

The effect of fat replacement with Nutriose on the physical properties of Spanish muffin batter and baked muffins and on consumer acceptability was studied. In the muffin batter, replacement of fat by Nutriose increased the number of larger air bubbles, although the bubbles were not retained during baking. DSC analysis of the muffin batters revealed that the starch gelatinization temperature rose with increased fat replacement with Nutriose (100 % fat replacement with Nutriose increased T _o values by 6 °C in comparison to the control) (p?≤?0.05). The presence of Nutriose decreased the height and volume of the muffins and significantly reduced their hardness and springiness (p?≤?0.05). No significant differences between the control and the 50-%-fat-replacement muffin were found in the consumer acceptability test (p?>?0.05), indicating that Nutriose can be a suitable fat replacer up to the 50 % level.     

Replacing Fat and Sugar with Inulin in Cakes: Bubble Size Distribution,Physical and Sensory Properties

The replacement of fat and sugar in cakes is a challenge as they have an important effect on the structural and sensory properties. Moreover, there is the possibility to incorporate an additional value using novel replacers. In this work, inulin and oligofructose were used as fat and sugar replacers, respectively. Different combinations of replacement levels were investigated: fat replacement (0 and 50 %) and sugar replacement (0, 20, 30, 40 and 50 %). Simulated microbaking was carried out to study bubble size distribution during baking. Batter viscosity and weight loss during baking were also analysed. Cake characteristics were studied in terms of cell crumb structure, height, texture and sensory properties. Fat and sugar replacement gave place to batters with low apparent viscosity values. During heating, bubbles underwent a marked expansion in replaced cakes if compared to the control cake. The low batter stability in fat-replaced samples increased bubble movement, giving place to cakes with bigger cells and less height than the control. Sugar-replaced samples had smaller and fewer cells and lower height than the control. Moreover, sugar replacement decreased hardness and cohesiveness and increased springiness, which could be related with a denser crumb and an easily crumbled product. Regarding the sensory analysis, a replacement up to 50 % of fat and 30 % of sugar—separately and simultaneously—did not change remarkably the overall acceptability of the cakes. However, the sponginess and the sweetness could be improved in all the replaced cakes, according to the Just About Right scales.     

Physical properties of muffins sweetened with steviol glycosides as the sucrose replacement

Overconsumption of sweets contributes to increasing obesity among children and adults. Functional food brings an opportunity to improve nutritional value of commonly eaten products, e.g., pastry products. New trends in the food industry tend to produce low-calorie products by replacing sugar or fat with additives having pro-health benefits. The aim of this study was to determine the effect of replacing sucrose with steviol glycosides (natural non-caloric sweetener) on the quality properties of bakery products. The analysis of muffin’s texture, color, cooking yield, browning index, and sensory analysis were performed. The study showed that a 25% addition of steviol sweetener (as a sucrose replacement) was the most appropriate modification of the basic formula. The resulting muffins gained sensory attractiveness and health-promoting qualities. Moreover, the study showed that a reduction of sucrose in excess of 50% had a negative impact on the quality of muffins and their sensory profiles.     

Rheological,textural and sensorial properties of low-sucrose muffins reformulated with sucralose/polydextrose

A study was made of the structure, texture, appearance, colour and consumer sensory analysis of low-sucrose muffins in which the sucrose had been totally or partially replaced (25%, 50%, 75%) by a sucralose:polydextrose mixture (1:1012). The structural characteristics of the muffin batters and of the baked muffins were studied through rheometry, microscopy, image analysis and texture analysis. The replacement of sucrose decreased the viscosity, viscoelasticiy and specific gravity of the raw muffin batter. The evolution of the batter’s viscoelastic properties during heating reveals a decrease in the thermosetting temperature with sucrose replacement. These changes in the batter were associated with a muffin with less height, hardness, springiness, cohesiveness, chewiness and resilience and fewer air cells than the control. For 50% sucrose replacement, the appearance, colour, texture, flavour and sweetness and general acceptability were similar to those of the control. Significantly less acceptable muffins were obtained with 100% sucrose replacement.     

A COMPREHENSIVE EVALUATION OF EGG AND EGG REPLACERS ON THE PRODUCT QUALITY OF MUFFINS

ABSTRACT

Five muffin formulations, liquid whole egg, dry whole egg, and three commercial egg replacers, which partially replaced egg in the formulations, were evaluated to determine differences in product qualities caused by egg and egg replacers. The products were prepared following the same procedure and other ingredient compositions, except for egg or egg replacer used in the formulation. Physical product characteristics and sensory properties of the samples were evaluated. It was found that egg, as an ingredient in the muffin formulation, is critical to obtain expected product quality characteristics. None of the commercial egg replacers produced acceptable quality muffins at 100% replacement. Partial replacement of egg with commercial egg replacers changed product characteristics altering moisture retention, bulk volume, color, texture and flavor. Some of these differences, however, were not readily detected by the sensory panelists.

PRACTICAL APPLICATIONS

This study comprehensively evaluated the effects of egg and egg replacers on final product quality, when used in pilot‐scale muffin production. An array of tests were conducted on samples prepared according to respective ingredient manufacturers' recommendations – partially replacing egg with commercial egg replacers – to objectively evaluate the differences in quality and sensory attributes. The functionalities of each ingredient (egg replacer) in muffin formulations were interpreted based on the results obtained. The observations and results of this study would be important in selecting appropriate ingredients for muffin formulations to obtain desired product qualities.

     

Optimization of a sponge cake formulation with inulin as fat replacer: structure, physicochemical, and sensory properties

The effects of several fat replacement levels (0%, 35%, 50%, 70%, and 100%) by inulin in sponge cake microstructure and physicochemical properties were studied. Oil substitution for inulin decreased significantly (P < 0.05) batter viscosity, giving heterogeneous bubbles size distributions as it was observed by light microscopy. Using confocal laser scanning microscopy the fat was observed to be located at the bubbles' interface, enabling an optimum crumb cake structure development during baking. Cryo-SEM micrographs of cake crumbs showed a continuous matrix with embedded starch granules and coated with oil; when fat replacement levels increased, starch granules appeared as detached structures. Cakes with fat replacement up to 70% had a high crumb air cell values; they were softer and rated as acceptable by an untrained sensory panel (n = 51). So, the reformulation of a standard sponge cake recipe to obtain a new product with additional health benefits and accepted by consumers is achieved. Practical Application: In this study, fat is replaced by inulin in cakes, which is a fiber mainly obtained from chicory roots. Sponge cake formulations with reductions in fat content up to 70% are achieved. These high-quality products can be labeled as "reduced in fat" according to U.S. FDA (2009) and EU regulations (European-Union 2006).     

EFFECT OF SOY PROTEIN ISOLATE AND SOY FIBER ON COLOR, PHYSICAL AND SENSORY CHARACTERISTICS OF BAKED PRODUCTS

Quick breads were formulated to contain 0%, 40%, 50% or 60% Soy Protein Isolate and Fiber (SPI/Fiber), and yeast breads were formulated to contain 0%, 14%, 21% or 28% SPI/Fiber replacement for wheat flour. Physical and sensory data were collected. As SPI/fiber level increased, muffin batter specific gravity, baked product air cell number, Instron peak force to compress by 75%, a value, beany flavor, grain-like flavor, aftertaste, moistness and denseness increased while muffin peak height at the crown, baked volume, L and b values, hue angle, sweetness and crumbliness decreased. There were significant negative correlations between increased level of SPI/fiber in muffins and acceptability of flavor and texture, as well as willingness to purchase or purchase the product at a higher price. As SPI/fiber level increased, bread dough pH after fermentation, air cell number, Instron peak force to compress by 75%, a and b values, beany flavor, grain-like flavor, and aftertaste increased while loaf volume, peak height at the crown, L value, hue angle, cohesiveness and crumbliness decreased. There were significant negative correlation coefficients between level of SPI/fiber and acceptability of flavor and texture, as well as willingness to purchase the product or to purchase it at a higher price.     

Evaluation of four types of resistant starch in muffin baking performance and relationship with batter rheology

The influence of wheat flour partial replacement with different types of resistant starch (RS) in muffin batter rheological properties and in baked muffin height, volume and number of air bubbles was investigated. The type of RS affected the above-described properties differently. In comparison to the control batter (without RS), replacement with RS type 3 (Novelose 330 and C*Actistar) increased viscosity and viscoelasticity, at both 20 and 80 °C. On the contrary, RS type 2 (Hi-maize 260 and Novelose 240) decreased them. These differences in viscosity and viscoelasticity were related to different baking performance. The RS3 type muffins had higher height, volume and number of air bubbles than the RS2 type muffins. An increase in viscosity and elasticity of the raw batter and during the heating process favours bubble retention and stability, thus favours baking performance. However, despite the improvement provided by the RS type 3, the baking performance was still lower than in the control muffins. One feature that may contribute to the baking differences is the delay in all the RS batters in the starch gelatinization temperature.     

Modification of gluten-free sorghum batter and bread using maize, potato, cassava or rice starch

Gluten-free sorghum bread was made from cassava, maize, potato or rice starch and sorghum in the ratios 10:90, 20:80, 30:70, 40:60 and 50:50. The other baking ingredients, on flour-weight-basis, were water (100%), sugar (6.7%), egg white powder (6%), fat (2%), salt (1.7%) and yeast (1.5%). Increasing starch content changed the batters’ consistencies from soft doughs to thin pourable batters. Increasing starch content decreased crumb firmness and chewiness, and increased cohesiveness, springiness and resilience of all breads. Cassava-sorghum and rice-sorghum breads had better crumb properties than maize-sorghum or potato-sorghum breads. Although the crumb properties of all breads declined (i.e. firmness and chewiness increased; cohesiveness, resilience and springiness decreased) on storage, the formulation containing 50% cassava starch retained the best overall texture.     

EFFECT OF COMMERCIAL ENZYMES ON THE BAKING AND KEEPING QUALITY OF A FAT REDUCED MUFFIN

Utilization of a protein-based fat substitute (100% replacement) in a muffin with and without added fungal protease, fungal amylase and/or bacterial amylase was compared with a full fat counterpart. The enzymes were evaluated independently and in combination with each other. Physical tests indicated no significant differences (P>0.05) among any of the variations in volume, crumb L and crust L and b values. The full fat muffin was significantly (P<0.05) more tender, lower in moisture, and more yellow of crumb when compared with the other variations. The 100% fat substituted muffin with enzymes, generally, had a lower moisture content, lower volume, decreased staling rate, and decreased crumb firmness when compared with the 100% fat substituted muffin without enzymes.     

Effect of sugar replacement with stevianna and inulin on the texture and predictive glycaemic response of muffins

The application of sugar replacers used in bakery products is of growing interest to the food industry, as it provides the possibility of delivering products with reduced energy and sugar. The aim of this study was to investigate the textural properties and glycaemic responses of muffins made using stevianna and inulin. Two levels of sugar replacer were used (50% and 100%). Total replacement of sucrose gave muffins with a firmer texture than the control (P < 0.05); 50% replacement, however, gave a similar texture to control. The predicted glycaemic response was reduced in sugar‐replaced muffins compared to control samples. In particular, the replacement of sucrose with 100% stevianna caused a significant decrease in the standardised area under the curve values. Therefore, there exists the potential to regulate the glycaemic response of muffins by the incorporation of 50% stevianna or 50% inulin without affecting their textural properties.     

菊粉、大豆拉丝蛋白及茶叶提取物在发酵香肠中的应用

以菊粉部分代替肥肉,以大豆拉丝蛋白部分代替瘦肉,在肉馅中添加茶叶提取物,通过质构仪结合感官评定,对产品主料配方进行研究,确定产品的主料配方为:猪瘦肉56%、猪肥肉10%、菊粉10%、大豆拉丝蛋白9%、茶叶提取物15%。用少量的菊粉及大豆拉丝蛋白分别部分替代肥肉及瘦肉,添加少量茶叶提取物生产发酵香肠可行,在此条件下,产品色泽均匀,茶香味与发酵芳香风味协调,口感润滑,质地紧密。