Use of ferulic and cinnamic acids to obtain active films based on starch and pla for food packaging applications

Resumen

Food packaging waste is a major contributor to the current environmental crisis caused by conventional plastic. Therefore, the food industry needs more sustainable environmentally friendly packaging solutions, such as using biodegradable and active materials to extend the food shelf-life. In this sense, the present doctoral thesis aims to obtain active films based on starch and PLA by incorporating ferulic or cinnamic acids as active compounds, in order to develop multilayer assemblies useful to meet food packaging requirements, with antibacterial capacity to extend the product shelf life. The incorporation of ferulic and cinnamic acids into cassava starch matrices through melt-blending process, at 1 and 2% w/w, promoted the film plasticization, probably due to the partial hydrolysis of polymer during the melt-blending process. The analyses of the antibacterial activity of the films against E. coli and Listeria innocua strains, in culture medium, revealed that films with cinnamic acid were more effective at inhibiting the bacterial growth, and that L. innocua was more sensitive to both acids than E. coli. When the acids were incorporated into PLA matrices at 1 and 2% w/w by melt blending, the functional properties of the films were not greatly affected. However, the in vitro antimicrobial tests with L. innocua and E. coli, did not show antibacterial action. Release studies showed very limited release of the ferulic and cinnamic acids from the PLA matrix due to the glassy state of polymer matrix and its hydrophobic nature that limits the polymer swelling and relaxation in contact with aqueous media, such as many food matrices. Therefore, in order to promote the release of active compound from the PLA matrix, different strategies were analysed: 1) plasticizing the thermoprocessed films with PEG 1000, 2) increasing the concentration of the compounds in the film, 3) processing the films by casting and 4) anchoring the active compounds to the film surface. Only the surface incorporation of ferulic or cinnamic on PLA films gave rise to significant bacterial growth inhibition. Pulverization of PLA films with ferulic or cinnamic acid ethanol solutions allows the formation of an overconcentrated layer of active compounds on the films with crystalline formations that led to an adequate release of actives to inhibit the bacterial growth. PLA-acid solutions, using blends of ethyl acetate with dimethyl sulfoxide (DMSO) or glacial acetic acid, were electrospun on the film surface. DMSO systems produced fibre-structured mats with high specific surface that significantly inhibited bacterial growth, whereas acetic acid systems produce bead-based mats that not had antimicrobial activity. The surface incorporation of the active compounds was considered for obtaining three-layered films PLA/starch/PLA (PSP) with improved functional properties and antimicrobial capacity. Superficially loaded films by both electrospinning or pulverisation, showed effective growth inhibition of E. coli and L. innocua, electrospun films being more effective than pulverised, suggesting greater ability to release the active compounds. Therefore, PSP laminates, with surface incorporation of ferulic or cinnamic acids, represent a good alternative to obtain active food packaging materials with the capacity to preserve food quality and extend shelf life. Nonetheless, further studies on the material stability and specific applications in real foods are necessary to determine the possible industrial application and economic viability of these materials.