Abstract
Anthocyanins, the most ubiquitous water-soluble phytopigments in terrestrial flora, have garnered substantial attention in sustainable food packaging research owing to their exceptional chromatic properties, pH-responsive characteristics, and putative health-promoting effects. Nevertheless, their inherent chemical lability manifests as rapid chromatic fading, structural degradation, and compromised bioactivity/bioavailability, ultimately restricting industrial implementation and incurring significant economic penalties. Recent advances in stabilization technologies through molecular encapsulation within polymeric matrices or nanoscale encapsulation systems have demonstrated remarkable potential for preserving anthocyanin integrity while augmenting multifunctionality. The integration of anthocyanins into advanced functional materials has emerged as a promising strategy for enhancing food safety and extending shelf life through smart packaging solutions. Despite their exceptional chromatic and bioactive properties, anthocyanins face challenges such as chemical instability under environmental stressors, limiting their industrial application. Recent advancements in stabilization technologies, including molecular encapsulation within polymeric matrices and nanoscale systems, have demonstrated significant potential in preserving anthocyanin integrity while enhancing multifunctionality. This review systematically explores the integration of anthocyanins with natural polymers, nanomaterials, and hybrid architectures, focusing on their roles as smart optical sensors, bioactive regulators, and functional components in active and smart packaging systems. Furthermore, the molecular interactions and interfacial phenomena governing anthocyanin stabilization are elucidated. The review also addresses current technological constraints and proposes future directions for scalable, sustainable, and optimized implementations in food preservation.