Rheological and Thermal Properties of Salecan/Sanxan Composite Hydrogels for Food and Biomedical Applications.
Xiusheng Zhang, Haihong Yang, Guangming Zhang, Xiaoxue Yan, Jun Han, Xuesong Cao, Yan Xu, Zhiping Fan
Abstract
Open AccessThe rational design of advanced composite gels requires rigorous rheological analysis to decode their flow-deformation mechanisms, a prerequisite for optimizing performance in food and biomedical applications. However, systematic thermal analysis and rheological profiling of Salecan/Sanxan hydrogels remain unexplored, constituting a critical knowledge gap in this field. This study engineered Salecan/Sanxan hydrogels and systematically probed Salecan-dependent rheological and thermal properties. Through Power Law and Herschel-Bulkley model analyses, the hydrogels demonstrated composition-dependent rheological properties: yield stress (4.7-29.2 Pa), η50 (342.6-3011.4 mPa·s), and Arrhenius equation fitting revealed tunable activation energy (14,688.3-30,997.1 J·mol-1). Notably, when the gel was formulated with 3% Sanxan and 2% Salecan at a volume ratio of 1:2, its thermal-decomposition temperature rose by 9%, from 224.4 °C to 245.1 °C. Conversely, a 1:1 mixture of 2% Sanxan and 2% Salecan produced the lowest freezing point recorded (-18.3 °C), an 18% reduction compared with the control (-15.4 °C). These findings demonstrate the tunable rheological and thermal properties of Salecan/Sanxan hydrogels. By establishing that precise modulation of polymer mixing ratios can match the entire processing shear spectrum, this study not only fills a critical knowledge gap but also creates a versatile platform for designing tailor-made foods and biomedical matrices.