A Review of Freshness Indicator in Intelligent Packaging for Seafood

Document Type : Scientific Paper

Author

PhD student of Food Science and Technology, Faculty of Agriculture, Isfahan University of Technology, Isfahan, Iran

Abstract

Fish meat and body are considered sterile when the fish is alive. Fish spoilage can occur very quickly after catching and during various stages of the production chain, processing and subsequent storage conditions. Fish is a highly perishable commodity. Decay of fish begins as soon as the fish dies. In the tropics, if the fish is not properly cooled, it will spoil quickly within a few hours of being caught. Smart packaging is a system containing markers inside or outside the package thatprovides information about packaging and food. Some of the markers on the seafood packaging are designed to alert consumers to chemical changes that have occurred inside the product. Smart packaging can effectively show changes in food quality during storage.

Keywords

References

1. Ashie, I. N. A., Smith, J. P., Simpson, B. K., & Haard, N. F. (1996). “Spoilage and shelflife extension of fresh fish and shellfish,” Critical Reviews in Food Science & Nutrition, 36(1-2), 87-121.##
2. Emborg, J., Laursen, B. G., & Dalgaard, P. (2005). “Significant histamine formation in tuna (Thunnus albacares) at 2 C—effect of vacuum-and modified atmosphere-packaging on psychrotolerant bacteria,” International journal of food microbiology, 101(3), 263-279.##
3. Ghaly, A. E., Dave, D., Budge, S., & Brooks, M. S. (2010). “Fish spoilage mechanisms and preservation techniques,” American journal of applied sciences, 7(7), 859.‏‏‏##
4. Lakshmanan, P. T. (2000). Fish spoilage and quality assessment,” Indian Council of Agricultural Research, 26-40.##
5. Gomes, C., Castell‐Perez, M. E., Chimbombi, E., Barros, F., Sun, D., Liu, J., ... & Wright, A. O. (2009). “Effect of oxygenabsorbing packaging on the shelf life of a liquidbased component of military operational rations,” Journal of food science, 74(4), E167-E176.‏‏##
6. Pacquit, A., Frisby, J., Diamond, D., Lau, K. T., Farrell, A., Quilty, B., & Diamond, D. (2007). “Development of a smart packaging for the monitoring of fish spoilage,” Food chemistry, 102(2), 466-470.‏##
7. Golasz, L. B., Silva, J. D., & Silva, S. B. D. (2013). “Film with anthocyanins as an indicator of chilled pork deterioration,” Food Science and Technology, 33, 155-162.‏##
8. Pacquit, A., Lau, K. T., & Diamond, D. (2005, June). “Smart packaging for the monitoring of fish freshness,” In Opto-Ireland 2005: Optical Sensing and Spectroscopy (Vol. 5826, pp. 545-550). International Society for Optics and Photonics.‏##
9. Chun, H. N., Kim, B., & Shin, H. S. (2014). “Evaluation of a freshness indicator for quality of fish products during storage,” Food science and biotechnology, 23(5), 1719-1725.‏##
10. Kuswandi, B. (2012). “Jayus; Restyana, A.; Abdullah, A.; Heng, LY; Ahmad, M. A novel colorimetric food package label for fish spoilage based on polyaniline film,”Food Control, 25, 184-189.‏##
11. Wang, W., Li, M., Li, H., Liu, X., Guo, T., Zhang, G., & Xiong, Y. (2018). “A renewable intelligent colorimetric indicator based on polyaniline for detecting freshness of tilapia,”Packaging Technology and Science, 31(3), 133-140.‏##
12. Mo, R., Quan, Q., Li, T., Yuan, Q., Su, T., Yan, X., ... & Li, C. (2017). “An intelligent label for freshness of fish based on a porous anodic aluminum membrane and bromocresol green,”ChemistrySelect, 2(28), 8779-8784.‏##
13. Liu, J., Wang, H., Wang, P., Guo, M., Jiang, S., Li, X., & Jiang, S. (2018). “Films based on κ-carrageenan incorporated with curcumin for freshness monitoring,” Food Hydrocolloids, 83, 134-142.‏##
14. Zhang, M., Meng, X., Bhandari, B., Fang, Z., & Chen, H. (2015). “Recent application of modified atmosphere packaging (MAP) in fresh and fresh-cut foods,” Food Reviews International, 31(2), 172-193.‏##
15. Zhai, X., Shi, J., Zou, X., Wang, S., Jiang, C., Zhang, J., ... & Holmes, M. (2017). “Novel colorimetric films based on starch/polyvinyl alcohol incorporated with roselle anthocyanins for fish freshness monitoring,” Food Hydrocolloids, 69, 308-317.‏##
16. Ma, Q., Liang, T., Cao, L., & Wang, L. (2018). “Intelligent poly (vinyl alcohol)-chitosan nanoparticles-mulberry extracts films capable of monitoring pH variations,” International journal of biological macromolecules, 108, 576-584.‏##
17. Silva-Pereira, M. C., Teixeira, J. A., Pereira-Júnior, V. A., & Stefani, R. (2015). “Chitosan/corn starch blend films with extract from Brassica oleraceae (red cabbage) as a visual indicator of fish deterioration,” LWT-Food Science and Technology, 61(1), 258-262.‏##
18. Dudnyk, I., Janeček, E. R., Vaucher-Joset, J., & Stellacci, F. (2018). “Edible sensors for meat and seafood freshness,” Sensors and Actuators B: Chemical, 259, 1108-1112.‏##
19. Chen, H. Z., Zhang, M., Bhandari, B., & Yang, C. H. (2019). “Development of a novel colorimetric food package label for monitoring lean pork freshness,” LWT, 99, 43-49.‏##
20. Apriliyanti, M. W., Wahyono, A., Fatoni, M., Poerwanto, B., & Suryaningsih, W. (2018). “The Potency of betacyanins extract from a peel of dragon fruits as a source of colourimetric indicator to develop intelligent packaging for fish freshness monitoring,” E&ES, 207(1), 012038.##

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History

  • Receive Date: 21 June 2020
  • Revise Date: 21 July 2020
  • Accept Date: 21 November 2020

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