Abstract
In this study, pH indicative films were successfully synthesized from hydrogels made by blending 1% poly(vinyl alcohol) (PVA) and 1% chitosan (CS) with anthocyanin (ATH) and sodium tripolyphosphate (STPP). Particularly, ATH extracted from red cabbage was used as the pH indicator, while STPP was utilized as the cross-linking agent to provide better mechanical properties of the cast films. FT-IR spectra confirmed the existence of the ATH in the cast films. Moreover, the tensile strength, the elongation-at-break, and the swelling indices of the cast films were measured. In general, these properties of pH indicative films were profoundly influenced by the compositions of PVA/CS and the STPP dosage applied in the hydrogels. For example, the tensile strength could change from 43.27 MPa on a film cast from pure PVA hydrogel to 29.89 MPa, if 35% of the PVA hydrogel was substituted with CS. The cast films were applied as a food wrap that could be used to monitor visually the quality of the enwrapped food via the color change of the film upon the variation in pH values of the enwrapped food. In practice, a sequential change in color was successfully observed on the pH indicative films partially enwrapping the pork belly, indicating the spoilage of the meat.
Highlights
The United Nations adopted 17 Sustainable Development Goals (SDGs) as part of the 2030 Agenda for Sustainable Development on September 25 2015
The anthocyanin (ATH) used in this work was extracted from red cabbage (Brassica oleracea), a produce harvested from the Lâm Đồng Province of Vietnam, following the solvent extraction method reported by Fuleki and Francis [25]
The pH indicative films of poly(vinyl alcohol) (PVA)/CS/ATH have been successfully cast from hydrogels by blending
Summary
The United Nations adopted 17 Sustainable Development Goals (SDGs) as part of the 2030 Agenda for Sustainable Development on September 25 2015. The invention of synthetic polymers has resulted in the mass production of plastic bags and thin-film wraps that are widely applied as food packaging materials. These plastic films have relatively low gas permeability. As such, they often serve as passive barriers to moisture, oxygen and microorganisms to protect the enwrapped food from spoilage. Several SDGs have been proposed to encourage more sustainable consumption and production patterns as well as more sustainable development of our world. Renewable packaging substitutes, e.g., plastics from renewable biomass sources, are under extensive development to replace the synthetic components in food packaging [1,2,3,4]
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