https://doi.org/10.52973/rcfcv-e33268

Received: 15/05/2023 Accepted: 06/06/2023 Published: 25/06/2023

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Revista Científica, FCV-LUZ / Vol. XXXIII, rcfcv-e33268, 1 – 6

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 articial 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 coecients

) and mean square errors (MSE), resulting in a network of 60 neurons

in a hidden layer (R

= 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), R

, 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 articial

intelligence could be a reliable and nondestructive technique for

evaluating meat quality throughout its storage time.

Key words: Beef meat; ANN modeling; color parameters; storage

time

RESUMEN

Entre los diversos métodos disponibles para determinar el tiempo

de almacenamiento de la carne congelada, incluidos los análisis

basados en propiedades físicas y químicas, el análisis sensorial,

en particular los cambios de color, es un aspecto importante de la

aceptabilidad de la carne por parte de los consumidores. En este

estudio, se empleó una red neuronal articial (ANN) para predecir

el tiempo de almacenamiento de la carne con base en el espacio

de color CIELAB, representado por los valores Lab* (L*), (a*) y (b*)

medidos por un sistema de visión articial a intervalos de dos meses

durante un período de hasta un año.La topología ANN se optimizó

en función de los cambios en los coecientes de correlación (R

)

y los errores cuadráticos medios (MSE), lo que resultó en una red

de 60 neuronas en una capa oculta (R

= 0,9762 y MSE = 0,0047). El

rendimiento del modelo ANN se evaluó utilizando criterios como

desviación absoluta media (MAD), MSE, error cuadrático medio

(RMSE), R

y error absoluto medio (MAE), que resultaron ser 0,0344;

0,0047; 0,0687; 0,9762 y 0,0078, respectivamente. En general, estos

resultados sugieren qu’el uso de un sistema basado en vision por

computadora combinado con inteligencia articial podría ser una

técnica conable y no destructiva para evaluar la calidad de la carne

durante su tiempo de almacenamiento.

Palabras clave: Carne de res; modelado ANN; parámetros de color;

tiempo de almacenamiento

Storage Time prediction of Frozen Meat using Articial Neural Network

modeling with Color values

Predicción del tiempo de almacenamiento de carne congelada usando modelado de redes

neuronales articiales con valores de color

Saliha Lakehal

* , Brahim Lakehal

University of Batna1, Institute of Veterinary Science and Agricultural Sciences, Department of Veterinary Sciences. Batna, Algeria.

University of Batna2, Institute of Hygiene and Industrial Security. Batna, Algeria.

*Corresponding author: saliha.lakehak@univ–batna.dz

Artificial Neural Network for Predicting Storage Time of Frozen Meat / Lakehal and Lakehal _______________________________________

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INTRODUCTION

Across the world, meat occupies a central place in diet. It is used

in the preparation of a variety of dishes, from the most traditional

to the most modern. It is associated with moments of pleasure and

celebration, with family or friends. In this regard, freezing meat is

a common and widespread practice in most families and is part of

their preservation habits. However, even when frozen, meat is not

an inert material; it is subject to changes in organoleptic properties

(texture, taste, appearance), nutritional properties (oxidation of lipids

and proteins), or structural changes during the freezing process itself

[1].Sensory analysis provides a fast and reliable non–destructive

alternative to analyze meat quality and shelf life. The main sensory

attributes analyzed in such analysis are texture, avor, and color.

When determining shelf life during sensory analysis, color proling

is of particular importance [2].

Color analysis is a vital component in assessing food quality, and it

can be performed through sensory evaluation by trained inspectors

or using instrumental methods such as colorimeters. However, the

subjectivity of human inspectors in evaluating color can lead to

discrepancies between observers. To overcome this limitation, the

International Commission on Illumination (CIE) proposed a standard

color space known as CIELAB in 1976 [3]. This color space denes

colors in terms of three coordinates: L* for brightness, a* for the

red–green component, and b* for the yellow–blue component. L*

ranges from 0 to 100, while a* and b* range from positive to negative.

The adoption of the CIELAB color space allows for a more reliable and

objective evaluation of food matrix colors. It is particularly useful for

detecting color changes during storage and processing, making it a

crucial tool for quality control in the food industry.

To predict meat storage time, mathematical models such as Logistic,

Baranyi, modied Gompertz, square–root, Arrhenius model, interaction

models, and generic models are used to analyze changes in bacterial

growth with temperature uctuations, according to Hansen et al. [4].

These mathematical models are precise and effective in forecasting

meat storage time. However, in recent years, articial neural networks

(ANNs) have become increasingly popular in predicting changes that

occur in meat quality and evaluation. For example, Zhu et al. [5] used

a neural network to predict various qualities of dry–cured ham based

on protein degradation. Similarly, Kaczmarek and Muzolf–Panek [6]

used the ANN modeling technique to simulate variations in TBARS

levels in the intramuscular lipid fraction of raw beef enriched with

plant extracts. Additionally, Xu et al. [7] presented a neural network–

based approach to anticipate changes in the quality of frozen shrimp

(Solenocera melantho). In their recent work, Kaczmarek and Muzolf–

Panek [8] used predictive models to monitor changes in the levels of

the thiol group (SH) in raw and thermally processed ground chicken

meat that had been enriched with selected plant extracts during

storage at different temperatures. Other researchers, including

Taheri–Garavand et al. [9] and Lalabadi et al. [10], have also used

various ANN models to analyze the quality, production optimization,

and sensory freshness of various food products. However, the use

of computer vision systems as a non–invasive method for quality

control of meat during its conservation is relatively new. For this

reason, the aim of this research is to ascertain the potential of color

values as a reliable method in the evaluation of frozen meat quality

and to develop an ANN–based model for predicting meat storage

time based on color values.

MATERIALS AND METHODS

Samples preparation

One hundred twenty samples weighing approximately 600 g were

selected from the beef biceps femoris muscle slaughtered at the

Municipal Slaughterhouse of Batna, in North Eastern Algeria, and the

beef used was less than two years old. These 120 samples were taken

24 h after the slaughter. The fresh meat samples were analyzed on the

same day, while the remaining samples were divided into six portions

corresponding to the six freezing periods (2, 4, 6, 8, 10, and 12 months),

with each period containing 20 samples. Noting that these samples

have been vacuum packed in bags made of polyamide and polyethylene

using vacuum packaging machine (Sealer Machine, China) and frozen at

–23 ± 1.5°C (CRF–NT64GF40, Condor, Algeria). Temperature monitoring

throughout the frozen storage period was conducted three times a day

using a thermometer (TIA 101, China). Prior to photography, each frozen

sample was thawed in a refrigerator (CRF–NT64GF40, Condor, Algeria)

at a cool and constant temperature of 4 ± 0.6°C for 24 h.

The computer vision system for image capture consisted of a box

and two lamps located 50 cm above the samples at an angle of 45°,

whose purpose was to obtain a uniform light intensity on the sample.

A digital camera (Canon DS126621,China) was also placed on top at a

distance of 30 cm from the sample. To reduce the background light,

the inner walls of the box are covered with an opaque black cloth [11].

Using Adobe Photoshop CS3, the color's clarity (L*), redness (a*), and

yellowness (b*) were numerically assessed (FIG.1).

Application of Articial Neural Networks for modeling

In order to create and utilize ANNs, certain characteristics were

chosen. While there are numerous types of ANNs to choose from,

a multilayer perceptron (MLP) was selected. FIG. 2 illustrates the

schematic representation of MLP networks consisting of three layers:

the input layer, hidden layer(s), and output layer [12]. Neurons in the

input layer display three color variables for frozen/thawed meat. The

output layer, which contains time storage, is complemented by one or

more neurons in the hidden layer. The number of nodes in these layers

is determined by trial and error, so there is no xed rule for how many

hidden layers or neurons are necessary (FIG. 2). The MATLAB interface

was used during the design phase and optimization. During this study,

well–known variable statistical indicators, namely R, MSE, MAD MAE,

and RMSE, were utilized to evaluate the network's eciency. To ensure

a good t between model approaches and target data points, the R

value was employed. Meanwhile, MSE is a dependable measure to

assess the accuracy of a developed procedure, especially when it

comes to predicting errors for an external set of samples. Additionally,

the MAD can be applied as a scale measure to account for individual

differences and elucidate any correlations. Finally, both MAE and

RMSE are used as evaluation metrics in prediction tasks to assess

the accuracy of the predictions. Lower values of both MAE and RMSE

indicate better prediction accuracy.

Statistical analysis

Statistical analysis was performed on the observed values using

variance analysis (ANOVA) with SPSS software version 22 (IBM SPSS

Statistics v22). The means were compared using the Tukey method.

The difference was considered signicant if the probability (P<0.05).

Otherwise, the difference was considered insignicant (P≥0.05).

FIGURE 1. Utilization of Adobe Photoshop CS3 software for image analysis

FIGURE 2. Schematic of the training process of the ANN

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RESULTS AND DISCUSSION

Color evaluation

The color of meat has a signicant inuence on its appearance and

market acceptability [13]. As shown in FIG. 3A, the L* value decreased

signicantly after 4 months of storage (P<0.05). Similar results have

been reported by Muela et al. [14] and Muela et al. [15], where the L*

values tended to decrease with prolonged storage time. The content

and chemical state of myoglobin are important factors in determining

meat color [15, 16]. Increased sensitivity to myoglobin oxidation

during freezing could darken the meat color, resulting in decreased L*

values [17, 18]. Other factors may also inuence meat color, especially

after long periods of storage, by promoting marked darkening with

decreased luminance (L*), such as dehydration of the meat surface

layer during long–term storage [20] or temperature uctuation during

the storage process [21].

By observing FIG. 3B, it was able to deduce that the (a*) values

showed a signicant decrease after 10 months of frozen storage

(P<0.05), which is consistent with the ndings of Hansen et al. [4]

who noted a decrease in (a*) values after 30 months of frozen storage.

Medić et al. [22], on the other hand, discovered decreasing (a*) values

up to the 4th month of frozen storage, but an increase at the 6th

month. Alonso et al. [23] suggested that denaturation of myoglobin

during freezing could be the cause of the decrease in (a*) values. In

contrast to the current results, Daszkiewicz et al. [24] did not detect

any differences in (a*) values of frozen Kamieniec sheep (Ovis aries)

meat samples for a period of 12 months.

The b* value was lowest in fresh samples and increased signicantly

with time, starting from the 6th month (P<0.05), reaching its highest

value at 12 months of storage (FIG.3C). Studies have reported similar

results, where meat (b*) value increased as the freezing period became

longer, such as Hansen et al. [4]; Vieira et al. [25]; Fernandes et al.[19] and

Coombs et al. [26]. It may be related to the accumulation of metmyoglobin

and the increase in lipid oxidation as freezing time increases[13, 27].

ANN prediction model

Constructing an ANN model requires careful consideration when

determining its topology. In this particular investigation, after

many tests of different models, : it was considered considered the

multilayer perceptron (MLP) with 60 hidden layers. FIG.4 shows the

symbolic notation of the ANN–optimized model. The optimal number

of neurons required to maximize R

and minimize MSE was identied

through careful evaluation. R

and MSE values varied with the number

of neurons up to 50, but adding 55 and 60 neurons produced the same

value of 0.97. Similarly, MSE values varied independently of the

number of neurons. A high correlation coecient of 0.97 indicates

a signicant correlation between the variables used in the model

development and optimization process (FIG. 4). The lowest MSE values

were obtained with 60 and 55 neurons, while neuron 1 had the highest

MSE of 0.070. Although the main goal of optimizing the topology is to

maximize R

and minimize MSE, the highest R

and lowest MSE were

FIGURE 3. Effect Effect of time freezing on meat colorof freezing on meat color

FIGURE 4. The variations in MSE and R

values in reacting to variations in the number of neurons in the hidden layer

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achieved with 60 neurons, with the MSE value of 60 neurons being

slightly lower than that of 55 neurons.

Previous studies have also shown similar results with a lower

number of neurons. For example, Zhang et al. [28] reported that MSE

values reached their minimum after adding 11 nodes to the hidden layer

when constructing an ANN model for the hydrolysis of Newfoundland

shrimp waste. The MSE values remained stable when adding additional

neurons. In another study, Liu et al. [7] used an ANN model to predict

changes in the quality of rainbow trout (Oncorhynchus mykiss) llets.

They built an ANN model and observed the lowest MSE values and

highest R

values using only 6 neurons.

The ANN model developed in this study includes 60 neurons in the

hidden layer. The model's performance is evaluated using several

measures, such as MAD, MSE, RMSE, R

, and MAE. All of which are

measures of error or precision. The values of these measures for the

test data are presented in TABLE I.

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The results show that the developed ANN model has been successfully

validated according to performance criteria, indicating that the model's

predictions are in good agreement with the observed data.

CONCLUSION

Using color values (L*, a*, and b*) to predict the storage time of

frozen meat through an articial neural network has been proven

to be an accurate method. The results of the study validate the

developed ANN model, as it has shown good agreement with observed

data based on performance criteria. Unlike physico–chemical and

microbiological analysis, color measurements are non–destructive, less

time–consuming, and do not require preliminary training for evaluation.

Hence, this study utilized color measurements to estimate the storage

time of frozen meat for a period of 12 months. It is important to note

that the combination of ANN models and color parameters as inputs

has great potential to accurately and quickly predict the storage time of

meat, providing a reliable method for predicting the shelf life of meat.

Conicts of interest

The authors declare no competing interests.

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TABLE I

Assessing the Effectiveness of Articial Neural Networks (ANN)

MAE R

RMSE MSE MAD

0.0078 0.9762 0.0687 0.0047 0.0344

MAE: Mean absolute Error, R

: Correlation Coecient, RMSE: Residual Mean Squared

Errors, MSE: Mean Squared Errors, MAD: Mean Absolute Deviation.

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