Development and characterization of antimicrobial alginate hydrogel beads filled with cinnamon essential oil nanoemulsion.

The aim of the present study was to investigate the characteristics of alginate beads filled with cinnamon essential oil nanoemulsions (CEONs). The influence of the alginate and CaCl2 concentrations on their physical, antimicrobial and antioxidant properties was studied. The droplet size of CEON was 146.20 ± 39.28 nm and the zeta potential was -33.8 ± 0.72 mV demonstrating proper nanoemulsions stability. Decreasing the alginate and CaCl2 concentrations resulted in higher EOs release due to the increased pore size of the alginate beads. The scavenging activity of DPPH of beads was found to be dependent on the alginate and calcium ion concentrations which affected the pore size of the fabricated beads. The FT-IR results declared the new bands in the spectra of filled hydrogel beads, which verified the encapsulation of EOs in the beads. The surface morphology of beads was studied using SEM images which showed the spherical shape and porous structure of alginate beads. In addition, the alginate beads filled with CEO nanoemulsion demonstrated strong antibacterial activity.

The effects of fatty acids chain length on the techno-functional properties of basil seed gum-based edible films.

In this study, the effects of various fatty (including caprylic, lauric, and palmitic) acids on physicochemical, mechanical, and barrier properties of basil seed gum (BSG)-based edible films were investigated. The introduction of fatty acids (FAs) into the BSG-based matrix was confirmed by FT-IR. Increasing the FA chain length resulted in an increase in the thickness and opacity of FA-modified BSG films, while water solubility decreased. The water vapor permeability (WVP) of FA-modified films was significantly (P < 0.05) lower than that of control film. The mechanical properties and color attributes of edible films were improved after incorporating caprylic and lauric acids. SEM micrographs revealed a more homogenous microstructure with a higher surface density in the films incorporated with caprylic acid, while a higher roughness and insoluble particles were observed in those incorporated with lauric, and palmitic acids. Our findings showed that lauric acid is a good candidate for improving the barrier and textural characteristics of BSG-based edible films.