Nanocomposite Film Based on Gluten Modified with Heracleum persicum Essence/MgO/Polypyrrole: Investigation of Physicochemical and Electrical Properties

In this study, the wheat gluten film was prepared. Heracleum persicum essence, magnesium oxide nanoparticles and polypyrrole were used to modify the structure of the wheat gluten film. Physicochemical properties of the prepared films such as thickness, solubility, moisture absorption ability, antioxidant properties, and electrical conductivity of the films were investigated. Also, the mechanical, structural and thermal properties of the films were investigated by techniques such as SEM, FTIR, XRD, TGA, DTA and tissue analysis. SEM images showed that the essence and polypyrrole strengthened the gluten film structure and made it more resistant to the passage of gases. FTIR spectra confirmed the electrostatic interactions between gluten and essence and polypyrrole. XRD spectra showed the amorphous structure of gluten film and its composites. The results of thermal analysis showed that polypyrrole greatly increased the thermal resistance of the film and the nanoparticles had little effect on the thermal resistance. Thickness, solubility, moisture content and ability to absorb moisture were further affected by the essential oil. The antioxidant and electrical conductivity of the film was greatly increased in the presence of all three additives of essence, magnesium oxide nanoparticles and polypyrrole. The gluten-essence-MgO-PPy (Glu-E-MgO-PPy) composite film had the most antioxidant properties. Glu-E-MgO-PPy film with important electrical conductivity and antioxidant properties has the potential to be used as an active and intelligent film in the packaging of perishable food products.

Automated summary

In this study, wheat gluten films were modified using Heracleum persicum essence, magnesium oxide nanoparticles, and polypyrrole, resulting in improved physicochemical properties and enhanced resistance to gas permeability. The addition of essence and polypyrrole strengthened the structure of the films, while magnesium oxide nanoparticles had little impact on thermal properties. The films showed increased antioxidant properties and electrical conductivity with the presence of all three additives, making the composite film a potential candidate for active and intelligent packaging of perishable food products.