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Bacterial cellulose-driven sustainable food packaging innovations: Biosynthesis, functionalization, and applications

Yibing Zhang, Da‐Wen Sun, Liang Xu

2025Trends in Food Science & Technology12 citationsDOIOpen Access PDF

Abstract

Background About one-third of the world’s food is lost and wasted in the supply chain each year. While the widespread utilisation of petroleum-derived plastic packaging has played a crucial role in mitigating losses of perishable food, its non-degradable characteristics pose a serious threat to global biodiversity and ecological systems. This urgent scenario necessitates the development of high-performance renewable materials with low-carbon emission profiles. Distinguished by its purity, mechanical strength, biodegradability, and adjustable structure, bacterial cellulose (BC) synthesised through microbial metabolism emerges as a promising candidate for sustainable packaging solutions. Scope and approach This review systematically introduced BC production methodologies and structural characteristics. BC exhibits remarkable intrinsic properties, including high mechanical strength, thermal stability, biocompatibility, and biodegradability, making it a frequently engineered substrate for food packaging. Recent breakthroughs in BC-based packaging preparation methods through both in-situ biosynthesis and ex-situ processing techniques were discussed. Furthermore, diverse BC-based packaging applications were presented, spanning films, coatings, and hydrogel/aerogel systems in the food field. Finally, the application prospects and challenges faced by BC-based packaging were summarized. Key findings and conclusions The green, sustainable, and environment-friendly BC has immeasurable potential to displace petroleum-derived plastic. Although a substantial amount of research on high-performance BC is not focused on the development of packaging materials, the findings may nonetheless lead to new alternatives for the food industry. Continued material innovation and technological improvements are expected to address plastic pollution and demonstrate significant potential for enhancing food shelf life, safety, and quality.

Topics & Concepts

Surface modificationCelluloseFood packagingBacterial celluloseBusinessBiosynthesisFood scienceChemistryChemical engineeringEngineeringBiochemistryEnzymeAdvanced Cellulose Research StudiesNanocomposite Films for Food Packagingbiodegradable polymer synthesis and properties
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