Effects Provided by Sugar Substitutes upon the Quality Indicators of Model Systems of Sweetened Condensed Milk in Storage

Sweetened condensed milk (SCM) is a product widely used by both consumers and other food production branches. However, it contains a lot of sucrose. This study aimed to examine the effects provided by sugar substitutes, such as trehalose, isomaltulose, and polydextrose, upon the SCM sensory profile and valuable quality indicators, such as water activity, viscosity, acidity, crystals size, and Maillard reaction potential (browning index, color change, loss of free amino acids). The study was performed by making model systems of SCM (MSCMs) using the method of reconstitution of powdered ingredients. All the presented carbohydrate compositions in MSCMs provided Aw value typical of intermediate-moisture food, which contributes to the long-term shelf-life of the product. However, only 2 MSCMs with compositions consisted of isomaltulose, trehalose (22.55% and 22.55%); trehalose (28.19%), sucrose (5.64%), polydextrose (5.64%), isomaltulose (5.64%) showed the stability of Aw within 14-d storage period. Trehalose and polydextrose in MSCMs with mono-carbohydrate added fraction demonstrated their high structure-forming ability expressed in high values of dynamic viscosity (>30 Pa·s), provided not by crystallization. MSCMs containing trehalose in predominant amount in the carbohydrate compositions (≥50%) showed lower average crystal size (<16 μm) compared with other MSCMs with di- and tetra-carbohydrate added fractions with predominant amount of isomaltulose and polydextrose. Isomaltulose and polydextrose added to MSCMs led to pronounced browning, while trehalose and sucrose reduced this effect in MSCMs with di- and tetra-carbohydrate added fractions. Addition of 22.55% of polydextrose to carbohydrate fraction of MSCMs caused bitterness, while 5.64% didn't affect the taste. Based on the results of all the research conducted the most optimal carbohydrate compositions to produce SCM with lower calorie, sucrose contents and stable adequate values of processing and sensory properties were trehalose (22.55%) with isomaltulose (22.55%) and trehalose (28.19%) with sucrose (5.64%), polydextrose (5.64%), isomaltulose (5.64%).

Effect of Gluten Composition in Low-Allergy O-Free Wheat Flour on Cookie-Making Performance Compared with Flours with Different Gluten Strengths

The increasing demand for allergen-free and reduced-allergen foods has led to an investigation into the potential use of O-free wheat, a low-allergy wheat cultivar, in cookie production. This study focused on assessing the gluten composition of O-free flour and comparing its suitability for cookie making in comparison to flours with varying gluten strengths. Several analyses were conducted, including gluten composition, solvent retention capacity (SRC), thermal and pasting properties, dough-mixing characteristics, and cookie-making performance. The gluten composition of O-free flour by SDS-PAGE confirmed the absence of ω-gliadins and the reduced levels of low-molecular-weight glutenins and γ-gliadins. The SRC values of O-free flour fell between the flours with weak and medium gluten strengths. While thermal and pasting properties showed significant differences in sucrose solution but not across flour types, indicating similar starch structures, mixograms displayed distinct variations influenced by both sucrose solution and flour type, highlighting the importance of gluten quality and composition. Cookies made with O-free flour demonstrated similarities to those produced with weak gluten flour, known for their favorable cookie characteristics. This study emphasizes the significant influence of flour gluten composition on cookie-making performance and advocates for the adoption of O-free flour in the development of allergy-friendly cookies.

Oligosaccharide, sucrose, and allulose effects on the pasting and retrogradation behaviors of wheat starch

The pasting and retrogradation behaviors of starch are altered by the presence of sugars and are important in dictating the storage stability and texture of starch-containing foods. The use of oligosaccharides (OS) and allulose in reduced-sugar formulations is being explored. The objectives of this study were to determine the impacts of different types and concentrations (0% to 60% w/w) of OS (fructo-OS, gluco-OS, isomalto-OS, gluco-dextrin, and xylo-OS) and allulose on the pasting and retrogradation attributes of wheat starch compared to starch in water (control) or sucrose solutions using DSC and rheometry. Physicochemical properties of the additives and their effects on amylose leaching were also considered. Significant differences in starch pasting, retrogradation, and amylose leaching were found between the control and additive solutions, influenced by additive type and concentration. Allulose increased starch paste viscosity and promoted retrogradation over time (60% conc. PV = 7628 cP; ΔHret, 14 = 3.18 J/g) compared to the control (PV = 1473 cP; ΔHret, 14 = 2.66 J/g) and all OS (PV = 14 to 1834 cP; ΔHret,14 = 0.34 to 3.08 J/g). In the allulose, sucrose, and xylo-OS solutions, compared to the other OS types, the gelatinization and pasting temperatures of starch were lower, more amylose leaching occurred, and pasting viscosities were higher. Increasing OS concentrations elevated gelatinization and pasting temperatures. In most 60% OS solutions these temperatures exceeded 95 °C thereby preventing starch gelatinization and pasting in the rheological analysis, and in conditions relevant for inhibiting starch gelatinization in low moisture-sweetened products. Fructose-analog additives (allulose and fructo-OS) promoted starch retrogradation more than the other additives, while xylo-OS was the only additive that limited retrogradation across all OS concentrations. The correlations and quantitative findings from this study will assist product developers in selecting health-promoting sugar replacer ingredients that impart desirable texture and shelf-life properties in starch-containing foods.

How isomaltulose and oligofructose affect physicochemical and sensory properties of muffins?

This article analyses, the replacement of sucrose in muffins with nine different combinations of isomaltulose and oligofructose. Being a structural isomer of sucrose with approx. 50% of sucrose sweetness, isomaltulose is non-cariogenic and with a low glycemic profile but having the same calories as sucrose. Oligofructose is composed of fructose polymers, with a reduced caloric value and prebiotic effect. Specifically, height, percentage of alveoli, water content, A_w , mechanical, and optical properties have been measured along with a sensory evaluation. The results showed that all combinations of sweeteners gave place to softer muffins than control ones. Moreover, isomaltulose caused a darkening of the products likely due to an enhancement of the Maillard reactions. The highest amount of isomaltulose and the absence of sucrose meant the worst score in sweetness and flavor due to the low sweetening powder of isomaltulose.

The effects of commercially available sweeteners (sucrose and sucrose replacers) on wheat starch gelatinization and pasting, and cookie baking

A variety of sucrose replacers (SRs) are increasing in popularity for reducing sucrose usage in low moisture baked goods (cookies, biscuits, etc.). The goal of this study was to link SR physicochemical properties to their observed effects on starch thermal properties, including results from differential scanning calorimetry, rapid viscoanalysis, particle size analysis, and model wire-cut cookie baking performance. The 12 SRs examined in this study were: Truvia, Splenda, Swerve, coconut palm sugar, Monk Fruit, erythritol, Benefiber, Miralax, blue agave syrup, yacon syrup, Sukrín Fiber Gold Syrup, and date syrup. The onset gelatinization temperature (T_gel ) of wheat starch increased significantly (P < 0.05) as sucrose and SR concentration increased (0 to 60% w/w), with significant variations in T_gel found between different sweetener types at the same concentration. Generally, as solution concentration increased, the larger SRs (degree of polymerization [DP]> 10) decreased paste viscosity (peak and final), decreased granule swelling, and increased T_gel compared to the control (water). The smaller SRs (DP < 10) increased both paste viscosity (peak and final) and granule swelling, unlike the larger SRs, and did not increase T_gel as much as larger SRs. The SRs which performed similar to sucrose in model cookie baking (fracturability, spread, color, etc.) and effects on starch properties (T_gel , paste viscosity, and granule swelling) were yacon, Sukrín, date syrups, and coconut palm sugar. The results linking sweetener physicochemical properties to their effects on starch gelatinization, pasting, and swelling can be used to guide reformulation strategies for potentially reducing sugar and/or increasing fiber content in foods. PRACTICAL APPLICATION: Several commercially available natural sweeteners and polymers (coconut palm sugar, date syrup, yacon syrup, Sukrín Fiber Gold syrup, and Benefiber) show promise for reducing or replacing sucrose in cookies, and other low-moisture baked goods, based on their similar effects on wheat starch gelatinization, pasting, and swelling, as well as performance in cookie baking trials. Compared to sucrose, some of these ingredients have a lower glycemic response and higher dietary fiber content, and act as prebiotics, thereby providing potential health benefit.

Exploration of the functionality of sugars in cake-baking, and effects on cake quality

This review paper describes our exploratory experimental studies on the functionality of sucrose and other sugars in cake-baking, and effects on cake quality. We have used the American Association of Cereal Chemists Method 10-90.01 as a base cake-baking method, and have applied Differential Scanning Calorimetry, Rapid Visco-Analyzer, and time-lapse photography analyses in experimental design studies of the effects of the following ingredient and formulation variables on cake quality (e.g. texture, color, moisture content) and other finished-product properties (e.g. shape, dimensions): (a) cake formula levels of sucrose and water, in terms of %Sucrose and Total Solvent; (b) concentration of sucrose or other sugars (e.g. xylose, ribose, fructose, glucose, maltose, polydextrose) vs. wheat flour starch gelatinization temperature and starch pasting during baking and gluten development during mixing; (c) unchlorinated flour vs. chlorinated flours (of varying pH); (d) cake formula %Sucrose and TS vs. cake color, shape, and dimensions; (e) cakes formulated with sucrose or other sugars (i.e. xylose, fructose, glucose), and variable %S and TS, and unchlorinated or chlorinated flour (pH 4.6), vs. cake color, shape, and dimensions.

Assessment of simultaneous addition of sucrose and xanthan effects on the thermal, pasting, and rheological behavior of corn starch

Thermal, pasting, and rheological properties of starch-based systems are the key characteristics for its processing. This study aimed to investigate the main and interactive effects of sucrose and xanthan on the thermal, pasting, and rheological behavior of corn starch. A central composite design (CCD) was used to evaluate the effect of simultaneous addition of sucrose and xanthan on some processing properties of starch-based systems. The results showed that besides the xanthan and sucrose effects (p < .001), the interactions played a significant role in all considered properties of corn starch except the flow behavior index (p < .05). Adding xanthan and sucrose increased the transition temperatures and the enthalpy change (ΔH) of the starch gelatinization, while they increased all pasting properties except setback viscosity. Statistical analysis results revealed the synergistic effects due to adding xanthan and sucrose on the thermal and pasting properties of starch. These were ascribed to the first- and second-order interaction effects (p < .05). Regression models proposed for prediction of all considered properties of the starch-based mixtures in the range of selected factors (R² > 0.88). The Fourier-transform infrared (FTIR) spectra revealed an increase in hydrogen bonding by increasing xanthan and sucrose. Since the formation of hydrogen bonds between mixture components could be affected the considered properties of the starch pastes. PRACTICAL APPLICATIONS: Starch-based foods are the most frequently consumed kind of foods in the developing countries, which provide a great deal of energy, and nutrients in a healthy diet. Therefore, the production of these kinds of food products is of great importance. The gelatinization, pasting, and rheological properties of starch-based foods are imperative aspects in its processing. These properties show differences according to the presence of other ingredients such as hydrocolloids and sweeteners. Since the addition of xanthan as hydrocolloid and sugar as a common sweetener in starch-based foods, affect optimal processing condition. Knowing the effects of the hydrocolloid and sweetener addition on thermal, pasting, and rheological properties of starch systems, help to improve the process and finding optimal process conditions for the production of sauces, baby foods, bread, confectionery, etc.