Ultrasonic treatment combined with curdlan improves the gelation properties of low-salt Nemipterus virgatus surimi

In this study, the gel properties of ultrasonic alone, curdlan treatment alone, and the combination of both at lowsalt surimi levels were investigated, mainly in terms of textural properties, water holding capacity, water distribution, dynamic rheology, protein secondary structure, microstructure and correlation analysis. The results showed that the springiness, gel strength, water holding capacity and energy storage modulus (G ') of the low-salt surimi gels without ultrasonic or curdlan treatment were lower than those of the high-salt concentration surimi gels. Compared with the 1 % low-salt group, the ultrasonic treatment combination with curdlan resulted in a significant improvement (p < 0.05) in the texture, water holding capacity and energy storage modulus (G ') of the low-salt surimi at the same salt concentration. The gel strength increased significantly from 3386.360 g.mm to 5457.203 g.mm, but there was no significant improvement in whiteness (p > 0.05). In addition, ultrasonic treatment combined with curdlan promoted the shift of the a-helix to the random coil and the ss-turn angle shift, thus exposing the internal groups, enhancing protein intermolecular interactions, and promoting the orderly aggregation of proteins, resulting in a microstructure of dense, and obtained the lowest porosity of 14.534 %. The present study might be necessary for promoting the high-value use of aquatic surimi products and the development of low-salt foods.

Automated summary

This study investigated the gel properties of surimi with ultrasonic alone, curdlan treatment alone, and the combination of both at low salt levels. The results showed that the combination of ultrasonic treatment and curdlan significantly improved the texture, water holding capacity, and energy storage modulus of the low-salt surimi. The combination treatment also promoted protein structural changes and enhanced protein interactions, resulting in a denser microstructure.