Comparative studies on the rheological characteristics, functional attributes, and baking stability of xanthan and guar gum formulated honey gel matrix

The research aims to enhance the characteristics of honey by incorporating xanthan gum (XG) and guar gum (GG) at various concentrations (0.5-2.0% w/w) and preparing a honey gel matrix (HGM) through high-shear homogenization. This approach serves as a substitute for fat-based filling materials commonly used in bakery products. The study encompassed an investigation of the rheological characteristics (steady and dynamic), total phenolic content (TPC), antioxidant activity, and baking stability of the HGMs. The concentration of the gums used significantly influenced the transformation of honey into the HGM and its stability. Notably, the XG-HGM demonstrated greater shear thinning behavior and higher consistency compared to the GG-HGM. Herschel Bulkley and power law models were found to be the best-fitted models for XG-HGM and GG-HGM, respectively. Furthermore, both XG-HGM and GG-HGM exhibited a higher viscous component (G) than an elastic component (G') at low concentrations, up to 1% (w/w) for XG-HGM and 1.5% (w/w) for GG-HGM; however, this behavior reversed beyond those concentrations (G' > G). The XG-HGM exhibited lower temperature sensitivity compared to GG-HGM, indicating better stability under varying heat conditions. Moreover, both TPC and antioxidant activity decreased with increasing concentrations of both gums. The XG-HGM achieved the highest baking stability index, reaching 95.23% at a 2% concentration. This modified HGM formulated with XG demonstrated superior consistency, color retention, and exceptional baking stability, making it a promising candidate for application as a filling material in the bakery sector. Its improved stability and quality can facilitate the development of a wide range of baking products in the food industry.

Automated summary

This research aims to enhance the characteristics of honey by incorporating xanthan gum (XG) and guar gum (GG) and preparing a honey gel matrix. The concentration of the gums used significantly influenced the transformation of honey into the gel and its stability. XG gel demonstrated greater shear thinning behavior and higher consistency compared to GG gel. Both XG gel and GG gel exhibited higher viscous components than elastic components at low concentrations, but this behavior reversed beyond those concentrations. The TPC and antioxidant activity decreased with increasing concentrations of both gums, and XG gel achieved the highest baking stability index.