Structural development of sucrose-sweetened and sucrose-free sponge cakes during baking

The influence of sucrose, wheat starch and sorbitol upon the heat- and mass-exchanging processes forming the structure of sponge cake was studied. Under the influence of wheat starch and sorbitol the structure of the sucrose-free sponge cake was formed at more uniform total moisture release. This process was done at lower temperatures and smoother change of the sponge cake height with respect to the sucrose-sweetened sponge cake. The porous and steady structure of both cakes was finally formed at identical time--between 18th and 19th minute, at the applied conditions for baking of each batter (metal pan with diameter 15.4 cm and depth 6.2 cm containing 300 g of batter and placed in an electric oven "Rahovetz-02", Bulgaria for 30 min at 180 degrees C). The water-losses at the end of baking (10.30% and 10.40% for the sucrose-sweetened cake and sucrose-free cake, respectively) and the final temperatures reached in the crumb central layers (96.6 degrees C and 96.3 degrees C for the sucrose-sweetened cake and sucrose-free cake, respectively) during baking of both samples were not statistically different. The addition of wheat starch and sorbitol in sucrose-free sponge cake lead to the statistically different values for the porosity (76.15% and 72.98%) and the volume (1014.17 cm3 and 984.25 cm3) of the sucrose-sweetened and sucrose-free sponge cakes, respectively. As a result, the sucrose-free sponge cake formed during baking had a more homogeneous and finer microstructure with respect to that ofthe sucrose-sweetened one.     

Comparative study of texture of normal and energy reduced sponge cakes

The complete sucrose elimination and its replacement by microencapsulated aspartame (Nutra Sweet) and bulking agents (sorbitol, wheat starch and wheat germ) on the physical and textural sensory characteristics of two diabetic sponge cakes against a control sponge cake was studied. Mathematical and statistical methods were used and regression models worked out, describing the physical and textural characteristics of the three sponge cakes and their values were optimized. The effect on the porosity, springiness, volume and shrinkage of sponge takes was substantial and depended on the amount of the added ingredients. The diabetic sponge cake containing wheat germ showed the least physical and sensory deviations against the control sponge cake. The energy value of the diabetic sponge cakes against the control one was reduced with 25% for the ordinary sponge cake without sucrose and with 29% for sponge cake without sucrose containing wheat germ.     

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.     

The effect of par‐baking and frozen storage time on the quality of cup cake

The effects of frozen storage and initial baking time of par‐baked cake on baking loss, volume, moisture, colour and textural properties of cake obtained after thawing and rebaking were investigated. Cakes, par‐baked at 175 °C for 15, 20 and 25 min, were stored at ?18 °C for 3, 6 and 9 months. After storage, par‐baked cakes were thawed and rebaked at 175 °C for 10, 15 and 20 min. Baking loss, moisture content, L and +b colour values, firmness, gumminess and chewiness of the resulting full‐baked cakes were significantly affected by both par‐baking and frozen storage time, while specific volume, cohesiveness, springiness and resilience values were significantly affected by frozen storage time. The increase in the time of frozen storage of the par‐baked cake leads to a decrease in the quality of the rebaked cake, namely an increase of baking loss and cake crumb firmness, and a loss in the moisture content and specific volume. Moisture of cake crumb, L and +b colour values, firmness, gumminess and chewiness significantly increased as the par‐baking time increased. However, regarding baking loss, specific volume, moisture content and textural properties, 3‐month intermediate storage at ?18 °C and 20‐min initial baking time gave the best result among the cakes produced by using the two‐step baking procedure.     

4种功能性低聚糖对海绵蛋糕的面糊性能和烘焙品质的影响

针对海绵蛋糕的高糖问题,选用4种功能性低聚糖完全替代海绵蛋糕中的蔗糖,分别比较了它们对海绵蛋糕的面糊性能和烘焙品质的影响。结果表明:低聚异麦芽糖、低聚果糖、低聚半乳糖的面糊性能与蔗糖组较为接近,显示出良好的替代性,使用这3种糖制作的海绵蛋糕贮藏3d后依然是可接受的。而菊粉因为吸湿性极强,其海绵蛋糕成品比容小,硬度大,咀嚼时粉质感强烈,可接受度最低。     

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.     

Relative importance of moisture migration and amylopectin retrogradation for pound cake crumb firming

Moisture migration largely impacts cake crumb firmness during storage at ambient temperature. To study the importance of phenomena other than crumb to crust moisture migration and to exclude moisture and temperature gradients during baking, crustless cakes were baked using an electrical resistance oven (ERO). Cake crumb firming was evaluated by texture analysis. First, ERO cakes with properties similar to those baked conventionally were produced. Cake batter moisture content (MC) was adjusted to ensure complete starch gelatinisation in the baking process. In cakes baked conventionally, most of the increase in crumb firmness during storage was caused by moisture migration. Proton nuclear magnetic resonance (¹H NMR) showed that the population containing protons of crystalline starch grew during cake storage. These and differential scanning calorimetry (DSC) data pointed to only limited amylopectin retrogradation. The limited increase in amylopectin retrogradation during cake storage cannot solely account for the significant firming of ERO cakes and, hence, other phenomena are involved in cake firming.     

Optimization of microwave baking of model layer cakes

 Response surface methodology was used to optimize the formulation of microwave-baked cakes. The independent variables were water content, emulsifier content baking time, oven power, shortening content and starch type. The quality factors evaluated were specific gravity of batter and volume index, uniformity index and tenderness of the crumb. Constraints for quality factors were obtained by conventional baking of American Association of Cereal Chemists high-ratio cake formulation. Multiple contour plots showed the optimum region for various water and shortening combinations at different emulsifier, time and power levels. Cakes formulated with wheat starch, containing 0.3% polysorbate 60, 133.7% water and 45.2% shortening (flour substitute basis), baked for 6 min at 100% power yielded acceptable cakes that can compete with conventionally baked cakes. Rice and corn cakes had lower quality than conventionally baked high-ratio cakes. Power was found to be the most efficient independent variable affecting all the dependent variables. Received: 26 August 1999 / Revised version: 11 October 1999     

A study of the baking process by differential scanning calorimetry

The denaturation of the components of a baked product such as cake or bread can be observed under simulated baking conditions by differential scanning calorimetry. When starch or protein denaturation occurs, an increased flow of heat shows the temperature range over which that process takes place. Experimental results are presented for angel cake. In the absence of sucrose, the egg-white proteins are denatured predominantly near 65 and 85°C. For wheat flour, starch denaturation is observed near 65°C, and protein denaturation over a broad range from 80 to 110°C. In the presence of the concentration of sucrose used in a standard batter, both the starch and the major portion of the egg-white proteins are denatured near 95°C, at approximately the maximum temperature attained by the cake when it reaches maximum volume in the oven. Apparently, the main function of sucrose in an angel cake is to raise the denaturation temperature ranges of the starch and protein. Decreasing the amount of sucrose in batters designed for high altitudes causes denaturation of starch and protein at the lower maximum temperatures attained at those altitudes. This assures formation of a structural framework of denatured starch and protein which will not allow the cake to “fall” after it attains its maximum volume.     

Effect of batter freezing conditions and resting time on cake quality

The aim of the present study was to investigate the effects of batter freezing and conditions and resting time before baking on quality of two kinds of cakes (layer and sponge cakes), including freezing temperature (−18 °C, −26 °C), storage time at sub-zero temperatures (30 and 100 days), and resting time (60 and 120 min). Characteristics of the batter (pH, density, viscosity, and microstructure) and cakes (density, texture, and colour) were analysed. Freezing process increases batter density and viscosity, and consequently decreases cake volume and height, but increases hardness. Cakes from frozen batters have a darker and more yellow crumb and lighter-coloured crust than cakes from non-frozen batters. Freezing process has a greater effect on batter and cake quality characteristics than storage/freezing conditions or resting time. In layer cakes, freezing mainly affected volume and colour, whilst in sponge cakes, there was a more marked effect on texture. Differences between the two kinds of cake could be related to a distinct internal structure. Resting time mainly affected batter characteristics, although there were no apparent differences in the quality of the cakes obtained.     

Effects of polyols and nondigestible oligosaccharides on the quality of sugar-free sponge cakes

Interest in nutrition is driving consumer demands for less fat, sugar, and calories. In most foods, however, the removal or reduction of ingredients causes readily detectable losses in appearance, texture and mouthfeel. In this work seven bulking agents (maltitol, mannitol, xylitol, sorbitol, isomaltose, oligofructose and polydextrose) were used to totally replace sucrose in sponge cakes. The effect of this substitution on cake quality was determined by measuring texture, colour and volume after baking under controlled conditions. These parameters were established instrumentally and by sensory evaluation. Best results were obtained with xylitol and maltitol, leading to sponge cakes more similar to the control one – manufactured with sucrose – and with the highest acceptance level in sensory evaluations. Lower quality sponge cakes were those elaborated with mannitol.     

Functional characterization of steam jet‐cooked buckwheat flour as a fat replacer in cake‐baking

BACKGROUND: With rising consumer awareness of obesity, the food industry has a market‐driven impetus to develop low‐fat or fat‐free foods with acceptable taste and texture. Fancy buckwheat flour was thus subjected to steam jet‐cooking and the performance of the resulting product in cake‐baking was evaluated as a fat replacer. RESULTS: Steam jet‐cooking caused structural breakdown and starch gelatinization of buckwheat flour, thus increasing its water hydration properties. In the pasting measurements, steam jet‐cooked buckwheat flour exhibited high initial viscosity, while no peak viscosity was observed. Also, the suspensions of steam jet‐cooked buckwheat flour exhibited shear‐thinning behaviors, which were well characterized by the power law model. When shortening in cakes was replaced with steam jet‐cooked buckwheat gels, the specific gravity of cake batters significantly increased, consequently affecting cake volume after baking. However, shortening replacement with steam jet‐cooked buckwheat up to 20% by weight appeared to be effective in producing cakes as soft as the control without volume loss. CONCLUSION: When buckwheat flour was thermomechanically modified by steam jet‐cooking, it was successfully incorporated into cake formulations for shortening up to 20% by weight, producing low‐fat cakes with comparable volume and textural properties to the control. Copyright © 2010 Society of Chemical Industry     

乳化剂和保泡型流态起酥油对海绵蛋糕面糊及其烘焙特性的影响

比较了单甘酯型乳化剂和蔗糖酯型乳化剂与保泡型流态起酥油联用对海绵蛋糕面糊特性及其烘焙特性的影响。结果表明,采用蔗糖酯型乳化剂与保泡型流态起酥油联用组的面糊比重显著下降,面糊黏度和表面张力增加,从而提升了面糊的稳定性,此时蛋糕比容较大,达4.01mL/g,比仅含单甘酯型乳化剂的蛋糕提高了68.5%,可显著减少薄层海绵蛋糕的表面气泡。蛋糕贮藏期研究表明,贮藏28d后,含有蔗糖酯型乳化剂和保泡型流态起酥油的蛋糕硬度减小了37.8%。     

Effect of green plantain flour addition to gluten‐free bread on functional bread properties and resistant starch content

Green plantain flour (GPF) was used as a functional ingredient to produce gluten‐free (GF) bread based on a flour blend of rice flour and GF wheat starch (50:50) to improve their functional properties and to increase their resistant starch (RS) content. In pretrials, an addition of up to 30% GPF provided acceptable bread quality with maximum RS content. Based on these trials, two 2³ factorial screening experimental designs were applied, where water content, baking temperature and baking time of GF bread containing 30% GPF addition were optimised. The best baking conditions to achieve satisfying GF bread quality – higher loaf volume, softer crumb firmness and regular porosity structure at the highest RS content could be defined to a maximum addition of water at 160%, baking temperature of 180 °C and baking time of 90 min. The incorporation of GPF showed good potential to improve the quality of GF bread.     

Effect of oat β‐glucan and its oxidised derivative on the quality characteristics of sponge cake

The objective of this study was to investigate the characteristics of sponge cakes containing native oat β‐glucan (BG‐B) and its oxidised derivative with TEMPO (2, 2, 6, 6‐tetramethyl‐1‐piperidine oxoammonium ion) (Oxi‐B). BG‐B and Oxi‐B were substituted at 1% (w/w) into a formulation, and then the effects of BG‐B and Oxi‐B addition on the pasting properties of wheat flour and the physicochemical and textural properties of sponge cakes were determined. The pasting parameters of wheat flour were increased by BG‐B, whereas they were decreased in wheat flour with added Oxi‐B. The cake containing Oxi‐B had a lower volume, and a higher symmetry and uniformity than the BG‐B cake. The Oxi‐B cake exhibited smaller L* and b* values and a higher a* value than the control in crumb and crust colour. According to texture profile analysis, the BG‐B cake had increased hardness, chewiness and gumminess, whereas the Oxi‐B cake had decreased hardness.     

Designing a Clean Label Sponge Cake with Reduced Fat Content

The fat in a sponge cake formulation was partially replaced (0%, 30%, 50%, and 70%) with OptiSol?5300.This natural functional ingredient derived from flax seeds, rich in fiber and alpha‐linoleic acid, provides a natural substitute for guar and xanthan gums, avoiding E‐numbers on labels. The structure and some physicochemical properties of the formulations were examined, sensory analysis was conducted and changes in starch digestibility due to adding this ingredient were determined. Increasing quantities of OptiSol?5300 gave harder cakes, with less weight loss during baking, without affecting the final cake height. There were no significant differences (P > 0.05) in texture, flavor and overall acceptance between the control and the 30% substitution cake, nor in the rapidly digestible starch values. Consequently, replacing up to 30% of the fat with OptiSol?5300 gives a new product with health benefits and a clean label that resembles the full‐fat sponge cake.     

Batter rheology and bread texture of sorghum‐based gluten‐free formulations modified with native or pregelatinised cassava starch and α‐amylase

The influence of α‐amylase (0–0.3 U g^?1) on the crumb properties of gluten‐free sorghum batter and bread, respectively, was investigated. The formulations were modified using native or pregelatinised cassava starch (i.e. batter A – 17% pregelatinised starch, 83% sorghum, 100% water fwb; batter B – 17% native starch, 83% sorghum, 100% water fwb; and batter C – 30% native starch, 70% sorghum, 80% water fwb). The batters had solid viscoelastic character with the storage modulus predominant over the loss modulus. Storage moduli of batter A decreased with increasing angular frequency, whereas the moduli of batters B and C were independent from the angular frequency. Increasing enzyme concentration did not affect the loss factors of the batters. Batters’ resistance to deformation, from highest to lowest, followed the order C > A > B. Increasing enzyme concentration decreased crumb firmness, cohesiveness, springiness, resilience and chewiness but increased adhesiveness. Overall, breads containing native starch had better crumb properties (i.e. springier and less firm, chewy and adhesive) than breads containing pregelatinised starch.     

The effect of alternative sweeteners on batter rheology and cake properties

BACKGROUND: The aim of this research was to investigate whether certain polyols (mannitol, maltitol, sorbitol, lactitol), fructose, oligofructose and polydextrose can replace sugar (by an equal amount of each substitute) in cake formulations. The rheological behaviour of the cake batter and the physical characteristics of the cakes containing sugar substitutes were compared with the respective attributes of the control cake. Differential scanning calorimetry was used to investigate the effect of sugar substitutes on starch gelatinisation. Furthermore sensorial characteristics were evaluated by instrumental measurements and sensory evaluation. The correlation of the batter characteristics with the textural attributes of the final product was also attempted. RESULTS: The best results were obtained by using oligofructose, lactitol or maltitol as sugar replacers, which exhibited similar behaviour to sucrose in terms of batter rheology and increased starch gelatinisation temperature. Fructose and mannitol led to cakes of poor quality characteristics, as was demonstrated by instrumental measurements and sensory evaluation. CONCLUSIONS: Batter rheological behaviour as well as the ability of sugar substitutes to increase starch gelatinisation temperature proved to be controlling factors of the textural properties and volume of the cakes. The sensory evaluation indicated that overall acceptance followed closely the scores of tenderness and taste. Copyright © 2011 Society of Chemical Industry     

搅拌时间和乳化剂对海绵蛋糕表面气泡的影响

比较研究蔗糖酯型乳化剂和单甘酯型乳化剂对海绵蛋糕起泡和消泡阶段面糊特性的影响,并重点比较了在相同面糊比重情况下,不同搅拌时间组合对海绵蛋糕表面气泡的控制及对面糊比重、黏度、微观气相结构、蛋糕烘焙特性的影响,并探讨了乳化剂与搅拌时间控制表面气泡的机理。结果表明:使用蔗糖酯型乳化剂可以控制海绵蛋糕表面气泡生成,并保持较佳的烘焙特性。在工艺方面,采用合适的搅拌组合(起泡时间3.50min,消泡时间6.33min)可以减少面糊异常气泡数量,从而减少海绵蛋糕表面气泡生成。     

Use of Yuja (Citrus junos) pectin as a fat replacer in baked foods

Pectin from yuja pomace was incorporated into cake formulations to evaluate the baking performance as a fat replacer. When shortening in cakes was replaced with different levels of pectin gel, cake batter exhibited greater viscosity and less shear-thinning behavior. The viscosities were well characterized using a Power-law model. The specific gravity of cake batter significantly increased with increasing levels of pectin gel (p<0.05) and was highly correlated with the cake volume after baking. Although cakes containing pectin exhibited increased textural hardness, shortening replacement with pectin up to 10% by weight was effective in producing cakes as soft as the control cake without a volume loss. There was an overall tendency that cakes with higher amounts of pectin showed a lighter surface color. Yuja pectin was thus used in cake baking as a fat replacer, producing baked goods with reduced fat and calorie content.