Granular hydrogels with tunable properties prepared from gum Arabic and protein microgels.

Granular hydrogels have emerged as a new class of materials for 3D printing, tissue engineering, and food applications due to their extrudability, porosity, and modularity. This work introduces a convenient method to prepare granular hydrogel with tunable properties by modulating the interaction between gum Arabic (GA) and whey protein isolate (WPI) microgels. As the concentration of GA increased, the appearance of the hydrogel changed from fluid liquid to moldable solid, and the microstructure changed from a macro-porous structure with thin walls to a dense structure formed by the accumulation of spherical particles. At a GA concentration of 0.5 %, the hydrogels remained fluid. Granular hydrogels containing 1.0 % GA showed mechanical properties similar to those of tofu (compressive strength: 10.8 ± 0.5 kPa, Young's modulus: 16.7 ± 0.4 kPa), while granular hydrogels containing 1.5 % GA showed mechanical properties similar to those of hawthorn sticks and sausages (compressive strength: 300.4 ± 5.8 kPa; Young's modulus: 200.5 ± 3.4 kPa). The hydrogel with 2.0 % GA was similar to hawthorn sticks, with satisfactory bite resistance and elasticity. Such tunability has led to various application potentials in the food industry to meet consumer demand for healthy, nutritious, and diverse textures.

In vivo absorption and fecal excretion of polysaccharides from the fruits of Lycium barbarum L. in rats through fluorescence labeling.

In the present study, the in vivo absorption and fecal excretion of a purified fraction of polysaccharides from the fruits of Lycium barbarum L. (LBPs-4) in rats were investigated by labelling LBPs-4 with fluorescein isothiocyanate (FITC). It was found that the fluorescent labeled LBPs-4 (LBPs-4-FITC) was not detected in the plasma within 24 h following the administration of a single dose of LBPs-4-FITC (100 mg/kg of body weight) to rats, indicating that LBPs-4 was hardly absorbed in its prototype form. Instead, a smaller fragment dissociated from LBPs-4-FITC was observed in feces and was accumulated in a time-dependent manner, suggesting that LBPs-4 was excreted into the feces with a form of degradation. Meanwhile, we observed that LBPs-4-FTIC could modulate the fecal bacterial community profile via increasing the relative abundances of Bacteroides ovatus and Alistipes and promote the production of acetic acid. Furthermore, the monoculture experiment confirmed that LBPs-4 could be metabolized into smaller fragment by B. ovatus, producing acetic acid. Collectively, our study provides information on the destiny of LBPs-4 after oral administration: non-absorbed but moved to the large intestine and catabolized by gut microbiota, especially B. ovatus.