Storage Time prediction of Frozen Meat using Artificial Neural Network modeling with Color values

  • Saliha Lakehal University of Batna1, Institute of Veterinary Science and Agricultural Sciences, Department of Veterinary Sciences. Batna, Algeria
  • Brahim Lakehal University of Batna2, Institute of Hygiene and Industrial Security. Batna, Algeria
DOI: https://doi.org/10.52973/rcfcv-e33268
Keywords: Beef meat, ANN modeling, color parameters, storage time

Abstract

Among the various methods available to determine the storage time of frozen meat, including analyses based on physical and chemical properties, sensory analysis, particularly color changes, is an important aspect of meat acceptability for consumers. In this study, an artificial neural network (ANN) was employed to predict the storage time of the meat based on the CIELAB color space, represented by the Lab* (L*), (a*), and (b*) values measured by a computer vision system at two–month intervals over a period of up to one year. The ANN topology was optimized based on changes in correlation coefficients (R2) and mean square errors (MSE), resulting in a network of 60 neurons in a hidden layer (R2 = 0.9762 and MSE = 0.0047). The ANN model's performance was evaluated using criteria such as mean absolute deviation (MAD), MSE, root mean square error (RMSE), R2, and mean absolute error (MAE), which were found to be 0.0344, 0.0047, 0.0687, 0.9762, and 0.0078, respectively. Overall, these results suggest that using a computer vision–based system combined with artificial intelligence could be a reliable and nondestructive technique for evaluating meat quality throughout its storage time.

Downloads

Download data is not yet available.

References

Zhang Y, Ertbjerg P. On the origin of thaw loss: Relationship between freezing rate and protein denaturation. Food Chem. 2019;299:125104. doi: https://doi.org/gj9w9h

Beltrán JA, Bellés M. Effect of freezing on the quality of meat. Encycl. Food Secur. Sustain. 2018; 493–7. doi: https://doi.org/kgdb.

Korifi R, Le Dréau Y, Antinelli JF, Valls R, Dupuy N. CIEL*a*b* color space predictive models for colorimetry devices – Analysis of perfume quality. Talanta. 2013; 104:58–66. doi: https://doi.org/f4zswt

Hansen E, Juncher D, Henckel P, Karlsson A, Bertelsen G, Skibsted LH. Oxidative stability of chilled pork chops following long term freeze storage. Meat Sci. 2004; 68:479–84. doi: https://doi.org/fckgtk

Zhu N, Wang K, Zhang SL, Zhao B, Yang JN, Wang SW. Application of artificial neural networks to predict multiple quality of dry–cured ham based on protein degradation. Food Chem. 2021; 344:128586. doi: https://doi.org/kgdd

Kaczmarek A, Muzolf–Panek M. Article predictive modeling of changes in TBARS in the intramuscular lipid fraction of raw ground beef enriched with plant extracts. Antioxidants. 2021;10(5):730. doi: https://doi.org/kgdf

Xu Z, Liu X, Wang H, Hong H, Luo Y. Comparison between the Arrhenius model and the radial basis function neural network (RBFNN) model for predicting quality changes of frozen shrimp (Solenocera melantho). Int. J. Food Prop. 2017; 20:2711–23. doi: https://doi.org/kgdg

Kaczmarek A, Muzolf–Panek M. Prediction of thiol group changes in minced raw and cooked chicken meat with plant extracts–kinetic and neural network approaches. Anim. 2021; 11(6):1647. doi: https://doi.org/kgdh

Taheri–Garavand A, Fatahi S, Shahbazi F, de la Guardia M. A nondestructive intelligent approach to real–time evaluation of chicken meat freshness based on computer vision technique. J. Food Process Eng. 2019; 42:1–10. doi: https://doi.org/kgdj

Mohammadi Lalabadi H, Sadeghi M, Mireei SA. Fish freshness categorization from eyes and gills color features using multi–class artificial neural network and support vector machines. Aquac. Eng. 2020; 90:102076. doi: https://doi.org/kgdk

Tomasevic I, Tomovic V, Ikonic P, Lorenzo–Rodriguez JM, Barba FJ, Djekic I, Nastasijević I, Stajić S, Živković D. Evaluation of poultry meat colour using computer vision system and colourimeter: Is there a difference? Br. Food. J. 2019; 121:1078–87. doi: https://doi.org/kgdm

Lakehal B, Dibi Z, Lakhdar N, Dendouga A. Electrical equivalent model of intermediate band solar cell using PSpice. Sadhana. 2015; 40:1473–9. doi: https://doi.org/kgdn

Zhang R, Yoo MJY, Farouk MM, Delgado–Pando G. Quality and Acceptability of Fresh and Long–Term Frozen In–Bag Dry–Aged Lean Bull Beef. J. Food Qual. 2019; 2019:e1975264. doi: https://doi.org/kgdp

Muela E, Monge P, Sañudo C, Campo MM, Beltrán JA. Meat quality of lamb frozen stored up to 21 months: Instrumental analyses on thawed meat during display. Meat Sci. 2015; 102:35–40. doi: https://doi.org/f64fd7

Muela E, Sañudo C, Campo MM, Medel I, Beltrán JA. Effect of freezing method and frozen storage duration on instrumental quality of lamb throughout display. Meat Sci. 2010; 84:662–9. doi: https://doi.org/bpzjvz

Mancini RA, Hunt MC. Current research in meat color. Meat Sci. 2005; 71:100–21. doi: https://doi.org/dks36s

Leygonie C, Britz TJ, Hoffman LC. Impact of freezing and thawing on the quality of meat: Review. Meat Sci. 2012; 91:93–8. doi: https://doi.org/fzh375

Farouk MM, Swan JE. Effect of Rigor temperature and frozen storage on functional properties of hot–boned manufacturing beef. Meat Sci. 1998; 49:233–47. doi: https://doi.org/bktm5g

Fernandez X, Monin G, Culioli J, Legrand I, Quilichini Y. Effect of Duration of Feed Withdrawal and Transportation Time on Muscle Characteristics and Quality in Friesian–Holstein Calves. J. Anim. Sci. 1996; 74:1576–83. doi: https://doi.org/kgdq

Zhu LG, Brewer MS. Discoloration of fresh pork as related to muscle and display conditions. J. Food Sci. 1998; 63:763–7. doi: https://doi.org/bw7g8s

Li X, Zhang Y, Li Z, Li M, Liu Y, Zhang D. The effect of temperature in the range of − 0.8 to 4°C on lamb meat color stability. Meat Sci. 2017; 134:28–33. doi: https://doi.org/kgdr

Medić H, Djurkin Kušec I, Pleadin J, Kozačinski L, Njari B, Hengl B, Kušec G. The impact of frozen storage duration on physical, chemical and microbiological properties of pork. Meat Sci. 2018; 140:119–27. doi: https://doi.org/gdhwf9

Alonso V, Muela E, Tenas J, Calanche JB, Roncalés P, Beltrán JA. Changes in physicochemical properties and fatty acid composition of pork following long–term frozen storage. Eur. Food Res. Technol. 2016; 242:2119–27. doi: https://doi.org/kgds

Daszkiewicz T, Purwin C, Kubiak D, Fijałkowska M, Kozłowska E, Antoszkiewicz Z. Changes in the quality of meat (Longissimus thoracis et lumborum) from Kamieniec lambs during long–term freezer storage. Anim. Sci. J. 2018; 89:1323–30. doi: https://doi.org/kgdt

Vieira C, Diaz MT, Martínez B, García–Cachán MD. Effect of frozen storage conditions (temperature and length of storage) on microbiological and sensory quality of rustic crossbred beef at different states of ageing. Meat Sci. 2009; 83:398–404. doi: https://doi.org/dthjs3

Coombs CEO, Holman BWB, Collins D, Friend MA, Hopkins DL. Effects of chilled–then–frozen storage (up to 52 weeks) on lamb M. longissimus lumborum quality and safety parameters. Meat Sci. 2017; 134:86–97. doi: https://doi.org/kgdw

Estévez M. Protein carbonyls in meat systems: A review. Meat Sci. 2011; 89:259–79. doi: https://doi.org/dxcw6j

Zhang K, Zhang B, Chen B, Jing L, Zhu Z, Kazemi K. Modeling and optimization of Newfoundland shrimp waste hydrolysis for microbial growth using response surface methodology and artificial neural networks. Mar. Pollut. Bull. 2016; 109:245–52. doi: https://doi.org/gfkr59

Published
2023-06-25
How to Cite
1.
Lakehal S, Lakehal B. Storage Time prediction of Frozen Meat using Artificial Neural Network modeling with Color values. Rev. Cient. FCV-LUZ [Internet]. 2023Jun.25 [cited 2024May20];33(2):1-. Available from: https://www.produccioncientificaluz.org/index.php/cientifica/article/view/40442
Issue
Vol. 33 No. 2 (2023)
Section
Food Science and Technology

Copyright (c) 2023 Saliha Lakehal, Brahim Lakehal

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.