Effect of aging at different temperatures on LAOS properties and secondary protein structure of hard wheat flour dough

Regulation of ice crystal growth in frozen dough: From the effect of gluten and starch fractions interaction on water binding - A review

The formation and growth of ice crystals are critical factors affecting the quality of frozen dough. Gluten and starch are the primary components of dough, and their hydration properties and effects on dough structure are crucial in determining the type of ice crystals formed. Gliadins, glutenins, A-type starch, and B-type starch are their refined components, each with distinct hydration properties and impact on dough structure. This review examines the structural properties and hydration properties of protein and starch components in frozen dough, as well as their individual and interactive influences on water absorption and the structural properties of frozen dough. Additionally, it explores changes at different structural levels during the interaction between protein and starch components in frozen dough. The review provides theoretical support for wheat breeding aimed at frozen flour products, ultimately contributing to the improvement of frozen dough quality and final product outcomes.

Investigation of the behavior of wheat flour dough under different sheeting-resting cycles and temperatures: Large deformation rheology and gluten molecular interactions

The molecular mechanisms underlying the structural changes in wheat flour dough subjected to repeated sheeting-resting treatments at two temperatures were investigated. The results revealed that alternating calendering and resting processes significantly contributed to the formation of a well-developed and organized gluten network, thereby enhancing the dough's resistance to deformation. Multiple complex treatments in a low-temperature environment promoted the formation of small aggregated proteins and monomeric proteins. In contrast, treatments at a high-temperature environment facilitated the formation of large aggregated proteins, reaching a maximum of 23.58 mg/g. The contribution of ionic and hydrogen bonding was maximum in the dough after two and three alternating treatments in both low- and high-temperature environments, while the strength of hydrophobic interactions remained weak. Furthermore, a combination of noncovalent interactions and sulfhydryl disulfide bond transitions induced notable changes in the structure of the glutenin molecular chain.

Microstructural and textural characteristics of blend gels and high-moisture meat analogs of soy protein isolate and faba bean protein concentrate

In this study, the effects of faba bean protein concentrate (FPC) and soy protein isolate (SPI) on the microstructure and texture of high-moisture meat analogs (HMMA) were extensively analyzed using rheological methodologies. Rheological analyses revealed that introducing FPC disrupted the gel structure and hindered the formation of a protein network among the SPIs. The gel stability also indicated that higher FPC content increased the susceptibility to continuous oscillation, potentially resulting in structural collapse. The β-sheets content decreased from 43.55 % to 37.19 % as the FPC content increased. The observed decline in the textural properties of HMMA, accompanied by microstructural alterations and diminished protein alignment, further supported the hypothesis that FPC disrupts protein network formation. Additionally, as the FPC content increased, the content of disulfide bonds decreased, emphasizing the role of FPC as a texture modulator that affects the rubbery texture of SPI.

Enzymatic hydrolysis method for development of low glycemic index rice flour from temperate grown rice (var. Jehlum): Numerical optimization, rheological and spectroscopic characteristics

This study aimed at optimizing process protocols for development of low glycemic index (GI) rice flour (LGIRF) by employing enzymatic hydrolysis method using central composite rotatable design (CCRD). LGIRF was evaluated for pasting, farinographic, spectroscopic and microbiological attributes. Independent variables for optimization included concentrations of α-amylase (0.02-0.12 %), glucoamylase (0.02-0.24 %), as well as the incubation temperature (55-80°C). Resistant starch (RS), glycemic index (GI) and glycemic load (GL) were investigated as response variables. The optimum conditions for development of LGIRF with better quality were- α-amylase concentration of 0.040 %, glucoamylase concentration of 0.070 % and an incubation temperature of 60 °C. The results of mineral analysis revealed significantly (p < 0.05) lower levels of boron, potassium, zinc, phosphorus, magnesium, and manganese in LGIRF, while iron and copper were significantly higher. The viscosity profile as evident from pasting profile and farinographic characteristics of LGIRF were significantly (p < 0.05) lower than native rice flour. 1H NMR and 13C NMR spectroscopic studies showed an increase in flexible starch segments and a decrease in amorphous portion of starch LGIRF, along with chemical shift alterations in carbons 1 and 4. Free fatty acids and total plate count were significantly (p < 0.05) higher in LGIRF although was within limits.

Binary hydrogels constructed from lotus rhizome starch and different types of carrageenan for dysphagia management: Nonlinear rheological behaviors and structural characteristics

This study focused on binary hydrogels constructed from lotus rhizome starch (LRS) and three types of carrageenan (κ-C, ι-C, and λ-C). The enthalpy of LRS gelatinization was reduced by 32.1%-88.4% with the incorporation of carrageenan. Compared with ι-C and λ-C, the conformations of κ-C more facilitated the development of the binary hydrogel network structure. The ability of the LRS/carrageenan binary hydrogel to immobilize water was mainly related to the effect of different types of carrageenan on starch molecular ordering. LRS-based hydrogels were recognized as level 4 in the International Dysphagia Diet Standardization Initiative (IDDSI) framework. Nevertheless, the incorporation of carrageenan significantly reduced the ability of the LRS hydrogel to resist stress under large deformations, which might be favorable to oral processing and swallowing. This research provides preliminary evidence for relevant industries to use carrageenan to adjust LRS hydrogel properties and improve the quality of starch-based foods for dysphagia management.

Effect of different starch acetates on the quality characteristics of frozen cooked noodles

The physicochemical properties of starch acetates with an equal degree of substitution prepared from pea, corn, and wheat starch and their effects on frozen cooked noodle (FCN) quality were investigated. The result showed that the three kinds of starch acetates had different effects on the quality of FCN due to their different blue values, freeze-thaw stability, and crystalline morphology analyzed by XRD (p < .05). The FCN with the addition of 20% CAS exhibited slow deterioration of textural properties during holding for 30 min. The analysis of the changes in the content of free SH group and glutenin macropolymer (GMP) demonstrated that the addition of CAS promoted protein disulfide cross-linking and decreased protein mobility during holding. Fourier transform infrared spectroscopy (FT-IR) revealed that FCN with the addition of CAS had low decrement in α-helix and β-sheet during holding, indicating that starch acetates contributed to the maintenance of the gluten network structure.