Abstract
Food spoilage exacerbates global hunger and poverty, necessitating urgent advancements in food shelf life extension methodologies. However, balancing antibacterial efficacy for food preservation with human and environmental safety remains a significant challenge. Natural essential oils (EOs), known for their potent antibacterial and antioxidant properties, offer eco-friendly alternatives, yet their high volatility and instability limit practical applications. Herein, we conducted the encapsulation of EOs within biocompatible metal phenolic networks (MPNs) to create EOs@MPN nanocapsules. Subsequently, these nanocapsules were integrated into bio-nanocomposite films composed of natural soy protein isolate (SPI) and carboxymethyl cellulose (CMC). The resulting films exhibited robust mechanical properties (Tensile Strength >10 MPa) and significantly enhanced antioxidant activity (7-fold higher than pure films). Importantly, the synergistic combination of EOs and MPNs conferred enhanced antibacterial efficacy. Safety assessments confirmed the bio-nanocomposite films' high biodegradability (> 90 %) and negligible cytotoxicity, ensuring environmental sustainability and human health safety. In practical applications, the bio-nanocomposite films effectively delayed the surface browning of fresh-cut fruits for up to 48 h, demonstrating a pronounced synergistic antioxidative effect against oxidation. Moreover, tomatoes and blueberries packaged with the bio-nanocomposite films still maintained freshness for up to 12 days, offering promising strategies for extending the shelf life of perishable fruits. These findings underscore the potential of EOs@MPN-based bio-nanocomposite films as sustainable solutions for food preservation and highlight their practical viability in mitigating food spoilage and enhancing food security globally.
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More From: International Journal of Biological Macromolecules
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