Funded under the National Recovery and Resilience Plan (NRRP), Mission 4 Component 2 Investment 1.3, Theme 10.
Smart and sustainable bio-based active food packaging (e.g., biopolymers from food waste/by- products upcycling, thin films and coatings incorporating bioactive compounds) (in connection with Spokes 3 and 4).
Development at a pilot scale of at least 2/3 smart and sustainable packaging solutions from upcycling of food waste/by-products (M36)
Testing of safety, efficacy sustainability and dynamic shelf-life of the developed smart and sustainable packaging solutions (M36).
Nowadays, smart and sustainable bio-based active food packaging materials represent a potential alternative to conventional plastic materials. Indeed, active packaging can extend the function of protection of foods, allowing a controlled interaction between the material, the food, and the environment if compared to the “no-active” bio-based material. The release of useful substances like antioxidants and antimicrobials or the absorption/removal of undesired gasses like oxygen can prolong the shelf life or improve food safety. Intelligent or smart packaging, like freshness indicators and sensors, monitors directly or indirectly the conditions of packaged foods, supporting the sustainability of the food chain. For instance, the enhancement of specific properties of micro and nanofibers from cellulose and chitosan, obtained by waste and biomass recovery, to immobilize bioactive compounds for active and intelligent packaging can offer greater protection to more sensitive foods, incentivizing a productive upcycling of waste-based food packaging economy.
The planned activities will cover two topics as follows:
1. Identification and production of organic compounds to be used in biobased packaging
Preparation of natural extracts from food by-products and waste, including orange peels, grape skins/pruning, grape pomace, polysaccharide feedstocks, Opuntia ficus-indica fruit peels, and cladodes, citrus, pomegranate, and apple wastes (supplemented with conifer waste), and microalgal biomasses grown on dairy wastewaters (CNR, UNICAT).
Mechanical or chemical production of micro/nano-fibrillated cellulose (MFC-NFC) from waste or biomasses (according to Tasks 2.1.1 and 2.1.2) and optimization of chemical-physical and morphological properties (UNIMI).
Production of bacterial nanocellulose (BNC) from agri-food waste and functionalization with natural antimicrobial peptides (CNR).
2. Design and formulation of structural matrices for new bio-packagings
Encapsulation of natural extracts with maltodextrins or cyclodextrins via spray dryer (UNICAT).
Fabrication of novel (edible) coatings and bio-based delivery systems (CNR).
Functional characterization of mono and multilayer bio-based structures incorporating active /intelligent bio-substances (characterized in Tasks 2.1.1 and 2.1.2.); preparation of hydro- and cryo-gels by covalent crosslinking of natural antioxidant and antimicrobial compounds (e.g., essential oils, amino acids, diacetyl, lysozyme) (CNR).
Fabrication of chitosan-based micro/nanofibers by chemical modification of chitin from insects (Task 2.1.2) (UNIMI).
Incorporation of cell-free supernatant and heat lysate from biocontrol lactic acid bacteria (Lactiplantibacillus plantarum) in model edible coatings/packagings (CNR).
Incorporation of phosphorescence-based O2 sensor devices in packaging systems (CNR).