Characterization of sonicated gluten protein and subsequent rheological properties of model dough and noodles

Background The present study aimed to investigate the effects of the thermo-mechanical and rheological properties of a wheat gluten-sonicated model dough and noodles, as well as the effects of ultrasonic frequency (20, 28, 40, 68 and 80 kHz) on the functional properties and structural features of gluten. Results Water absorption, stability and developmental time, and viscoelastic behavior of gluten-sonicated model dough were all found to be improved. Water absorption, tensile resistance and stretching distance of noodles increased markedly, whereas cooking loss decreased. Ultrasonication at different frequencies also significantly affected gluten structure, including its surface hydrophobicity, micro-network structure, and secondary and tertiary structures. These alterations then caused changes in its functional characteristics. Compared to untreated gluten, sonicated gluten exhibited significantly increased oil and water capacities (8.75-15.26% and 100.65-127.71% higher than the untreated gluten, respectively), foaming and emulsifying properties, and increased solubility (63.46-98.83% higher than control). In addition, these findings indicated that 40 kHz was the likely resonance frequency of the cavitation bubble in the gluten solution. However, sodium dodecyl sulfate-polyacrylamide gel electrophoresis electropherograms revealed that such treatments did not affect the molecular weight of gluten, which was also consistent with its unchanged disulfide bond content. Conclusion The present study clarified the impact of frequency on the properties of gluten and model dough. The best frequency for modification of gluten was 40 kHz. Collectively, these findings suggest that ultrasonic technology has the potential for use in modifying wheat gluten and commercial noodle processing. (c) 2022 Society of Chemical Industry.

Automated summary

The present study investigated the effects of ultrasonic frequency on the properties of wheat gluten and model dough. The results showed that ultrasonic treatment improved the water absorption, stability, and viscoelastic behavior of the dough, as well as the water absorption and stretching properties of the noodles. Ultrasonic frequency also affected the surface hydrophobicity, micro-network structure, and secondary and tertiary structures of gluten, leading to changes in its functional characteristics. The resonance frequency of the cavitation bubble in the gluten solution was determined to be 40 kHz. These findings suggest that ultrasonic technology has the potential for modifying wheat gluten and improving noodle processing.