This study investigated the physical, thermal, rheological, and binding properties of faba bean protein concentrate (FBC) and FBC-anionic gum mixtures. The anionic gums used in this study were sodium alginate (NaA), low-methoxyl amidated pectin (LMA), l-carrageenan (lCA), and gellan gum (GLG). The study found that FBC successfully incorporated the minced textured vegetable protein (TVP), but the formed TVP block had a fragile and soft texture. The water absorption index decreased in FBC-NaA and FBC-LMA mixtures but increased in FBC-lCA and FBC-GLG mixtures. The water solubility index decreased by adding NaA, LMA, and lCA, excluding GLG, to FBC. Adding anionic gums to FBC decreased solubility, while the swelling power was reversed in FBC-anionic gum mixtures, except for the FBC-LMA mixture. The addition of anionic gums to FBC increased melting onset and peak temperatures compared to FBC. The G′ value of FBC and FBC-anionic gum mixtures increased with temperature, indicating their thermogelling characteristic. The hardness of hamburger patties prepared with minced TVP and FBC or FBC-anionic gum mixtures generally tended to increase upon reheating, refrigeration, and reheating after refrigeration. The study concluded that the FBC-anionic gum mixtures have significant potential for binding different types of TVPs, highlighting its practical application.

This study investigated the impact of hydrolyzed plant proteins on the physical, thermal, and rheological properties of rice flour (RF) for protein fortification for the elderly and general food systems. Faba bean protein concentrate and chickpea flour were first treated with polysaccharide hydrolyzed enzymes (control; CTFP and CTCF, respectively) and subsequentially with protease hydrolyzed enzymes (hydrolyzed protein material; HZFP and HZCF, respectively). The addition of CTFP and HZFP enhanced the swelling power of RF, whereas the CTCF and HZCF exhibited the opposite trends. Adding all controls and hydrolyzed protein materials to RF increased the solubility and gelatinization temperature and decreased the gelatinization enthalpy. The HZFP addition successfully developed the pasting viscosity of RF, whereas the others did not. The RF-HZFP mixture had a higher peak viscosity than RF but lower trough, breakdown, final, and setback viscosities. These findings suggest that the controls and hydrolyzed protein materials studied here could be used as sources for protein fortification of foods, particularly for the elderly, with minimal changes in textural and rheological characteristics, thereby contributing to the development of nutritious and palatable food products.