Public interest in colorimetric films for food freshness monitoring has increased recently. In addition to extending the shelf life of packaged food products, packaging materials are also required to provide current information about the freshness of the food while ensuring food quality and safety. The current work aims to prepare smart biodegradable films based on biopolymer-containing color indicators to monitor the quality of Decapterus spp. The pH-sensing colorimetric film was developed from a chitosan biopolymer modified using polyvinyl alcohol (PVA) and glycerol, as well as methyl red, as an indicator of fish freshness. The effect of using PVA and stirring conditions (temperature and time) on film production was evaluated on its physical appearance, water vapor permeability, and mechanical properties. The results show that the use of PVA can increase the transparency of chitosan films. Incorporating PVA into the film results in brighter and clearer colors compared to films without PVA. The temperature used in the preparation of the film solution has an influence on the mechanical properties and the water vapor permeability. The increasing stirring temperature leads to the enhancement of Young's modulus and the barrier properties against water vapor and moisture, still concurrently impacting a decrease in the film's yield strength and strain. Additionally, the film also exhibits responsiveness to pH during fish spoilage, with a color change that occurs from pink to yellowish. This confirms that the pH-responsive film resulting from this research has great potential to be applied as a real-time indicator of fish freshness during storage.

Chan, R. B. Y. (2022). Packaging solutions for household food waste in the context of the food/beverage–packaging industry: A comparative review of empirical literature and industry press releases. Resources, Conservation and Recycling, 185, 106479.

Sharma, S., Barkauskaite, S., Jaiswal, A. K., & Jaiswal, S. (2021). Essential oils as additives in active food packaging. Food Chemistry, 343, 128403.

Yan, M. R., Hsieh, S., & Ricacho, N. (2022). Innovative Food Packaging, Food Quality and Safety, and Consumer Perspectives. Processes, 10(4), 747.

Gaspar, M. C. & Braga, M. E. M. (2023). Edible films and coatings based on agrifood residues: a new trend in the food packaging research. Current Opinion in Food Science, 50, 101006.

Shaikh, S., Yacoob, M., & Aggarwal, P. (2021). An overview of biodegradable packaging in food industry. Current Research in Food Science, 4, 503-520.

Bhaskar, R., Zo, S. M., Narayanan, K. B., Purohit, S. D., Gupta, M. K., & Han, S. S. (2023). Recent development of protein-based biopolymers in food packaging applications: A review. Polymer Testing, 124, 108097.

Ranjbar, M., Tabrizzad, M. H. A., Asadi, G., & Ahari, H. (2023). Investigating the microbial properties of sodium alginate/chitosan edible film containing red beetroot anthocyanin extract for smart packaging in chicken fillet as a pH indicator. Heliyon, 9(8), e18879.

Kongkaoroptham, P., Piroonpan, T., & Pasanphan, W. (2021). Chitosan nanoparticles based on their derivatives as antioxidant and antibacterial additives for active bioplastic packaging. Carbohydrate Polymers, 257, 117610.

Liu, Y., Wang, S., & Lan, W. (2018). Fabrication of antibacterial chitosan-PVA blended film using electrospray technique for food packaging applications. International Journal of Biological Macromolecules, 107 (A), 848–854.

Abdeen, Z. I., El Farargy, A. F., & Negm, N. A. (2018). Nanocomposite framework of chitosan/polyvinyl alcohol/ZnO: Preparation, characterization, swelling and antimicrobial evaluation. Journal of Molecular Liquids, 250, 335-343.

Perera, K. Y., Pradhan, D., Rafferty, A., Jaiswal, A. K., & Jaiswal, S. (2023). A comprehensive review on metal oxide-nanocellulose composites in sustainable active and intelligent food packaging. Food Chemistry Advances, 3, 100436.

Etxabide, A. Kilmartin, P. A., Maté, J. I., & Gómez-Estaca, J. (2022). Characterization of glucose-crosslinked gelatin films reinforced with chitin nanowhiskers for active packaging development. LWT, 154, 112833.

Dirpan, A., Hidayat, S.H., Djalal, M., Ainani, A.F., Yolanda, D.S., Kasmira, Khosuma, M., Solon, G.T., & Ismayanti, N. (2023). Trends over the last 25 years and future research into smart packaging for food: A review. Future Foods, 8, 100252.

Amin, U., Khan, M. K. I., Maan, A. A., Nazir, A., Riaz, S., Khan, M. U., Sultan, M., Munekata, P. E. S., & Lorenzo, J. M. (2022). Biodegradable active, intelligent, and smart packaging materials for food applications. Food Packaging and Shelf Life, 33, 100903.

Sobhan, A., Muthukumarappan, K., & Wei, L. (2021). Biosensors and biopolymer-based nanocomposites for smart food packaging: Challenges and opportunities. Food Packaging and Shelf Life, 30, 100745.

Liu, X., Chen, K., Wang, J., Wang, Y., Tang, Y., Gao, X., Zhu, L., Li, X., & Li, J. (2020). An on-package colorimetric sensing label based on a sol-gel matrix for fish freshness monitoring. Food Chemistry, 307, 125580.

Zhang, W., An, H., Sun, X., Du, H., Li, Y., Yang, M., Zhu, Z., & Wen, Y. (2023). Dual-functional smart indicator for direct monitoring fruit freshness. Food Packaging and Shelf Life, 40, 101192.

Pawde, S. V., Chaudhari, S. R., & Matche, R. S. (2023). Micro perforation based smart label to guide freshness of pasteurized milk packet. Food Control, 151, 109783.

Yumnam, M., Hatiboruah, D., Mishra, R., Sathyaseelan, K., Nath, P., & Mishra, P. (2023). A Smartphone-based optical sensor with polyaniline label for quantitative determination of freshness of freshwater fish fillets. Sensors and Actuators A: Physical, 114557.

Lv, X., Ma, H., Sun, M., Lin, Y., Bai, F., Li, J., & Zhang, B. (2018). A novel bacteriocin DY4-2 produced by Lactobacillus plantarum from cutlassfish and its application as bio-preservative for the control of Pseudomonas fluorescens in fresh turbot (Scophthalmus maximus) fillets. Food Control, 89, 22-31.

Shi, C., Qian, J., Zhu, W., Liu, H., Han, S., & Yang, X. (2019). Nondestructive determination of freshness indicators for tilapia fillets stored at various temperatures by hyperspectral imaging coupled with RBF neural networks. Food Chemistry, 275, 497-503.

Gopika, P. N., Radhakrishnan, P., Baiju, P., & MubeenaS, A. (2023). Fabrication Of Butterfly Pea Flower Anthocyanin-Incorporated Colorimetric Indicator Film Based on Gelatin/Pectin For Monitoring Fish Freshness. Food Hydrocolloids for Health, 100159.

Sobhan, A., Muthukumarappan, K., & Wei, L. (2022). A biopolymer-based pH indicator film for visually monitoring beef and fish spoilage. Food Bioscience, 46, 101523.

Wang, G., He, H., Xu, J., Wang, X., Zhang, T., Huang, S., Li, H., Zhao, P., & Liu, X. (2022). Preparation of fish freshness colorimetric indicator label based on the dye of BTB grafted on MOF carrier. Sensors and Actuators B: Chemical, 354, 131230.

FAO. (2022). The State of World Fisheries and Aquaculture 2022 Towards Blue Transformation, FAO, Rome, 10.4060/cc0461en.

Bhat, V. G., Narasagoudr, S. S., Masti, S. P., Chougale, R. B., Vantamuri, A. B., & Kasai, D. (2022). Development and evaluation of Moringa extract incorporated Chitosan/Guar gum/Poly (vinyl alcohol) active films for food packaging applications. International Journal of Biological Macromolecules, 200, 50-60.

Faisal, M. Gani, A., & Mulana, F. (2019). Preliminary assessment of the utilization of durian peel liquid smoke as a natural preservative for mackerel. F1000 Research, 8(240), 1-9.

Zahroh, F. F., Sugihartono, I., & Safitri, E. D. (2019). Young’s Modulus Calculation of Some Metals Using Molecular Dynamics Method Based on the Morse Potential. Computational and Experimental Research in Materials and Renewable Energy, 2(1), 19-34.

Annu, Ali, A., & Ahmed, S. (2021). Eco-friendly natural extract loaded antioxidative chitosan/polyvinyl alcohol based active films for food packaging. Heliyon, 7(2), e06550.

Diop, C. I. K., Beltran, S., Sanz, M-T., Garcia-Tojal, J., & Trigo-lopez, M. (2023). Designing bilayered composite films by direct agar/chitosan and citric acid-crosslinked PVA/agar layer-by-layer casting for packaging applications. Food Hydrocolloids, 344, 108987.

Tavares, K. M., Campos, A. d., Luchesi, B. R., Resende, A. A., Oliviera, J. E. d., & Marconcini, J. M. (2020). Effect of carboxymethyl cellulose concentration on mechanical and water vapor barrier properties of corn starch films. Carbohydrate Polymers, 246, 116521.

Souza, G. d., Belgacem, M. N., Gandini, A., & Carvalho, A. J. F. (2022). Synthesis and characterization of nanofibrilated cellulose films modified with blocked isocyanates in aqueous media and their barrier properties to water vapor and oxygen. Carbohydrate Polymer Technologies and Applications, 4, 100249.

Júnior, L. M., Silva, R. G. d., Vieira, R. P., Alves, R. M. V. (2021). Water vapor sorption and permeability of sustainable alginate/collagen/SiO2 composite films. LWT, 152, 112261.

Nishida, R., Hirota, N., & Nagai, K. (2023). Anti-cluster behavior and its mechanism during water vapor sorption in chitin and chitosan membranes. Carbohydrate Polymer Technologies and Applications, 5, 100312.

Zhuang, S., Hong, H., Zhang, L., Zhang, L., & Luo, Y. (2020). Spoilage-related microbiota in fish and crustaceans during storage: Research progress and future trends. Comprehensive Reviews in Food Science and Food Safety, 20(1), 252-288.

Tan, C., Hu, J., Gao, B., Zhang, B., Li, P., & Shang, N. (2023). Effects of the interaction between Aeromonas sobria and Macrococcus caseolyticus on protein degradation of refrigerated sturgeon fillets: Novel perspective on fish spoilage. LWT, 183, 114908.

Purnama, M. & Sudjadi, U. (2022). Mechanical study of 9CR-316SS-1MO for nuclear power reactor fuel cladding materials. International Journal of Innovation in Mechanical Engineering and Advanced Materials, 4(2), 38-45.

Martins, V. G., Romani, V. P., Martins, P. C., & Filipini, G. D. S. (2019). Innovative packaging that saves food. In C. M. Galanakis (Ed), Saving Food: Production, Supply Chain, Food Waste and Food Consumption (pp. 171-202). Academic Press.