3.1. Proximate Composition
Table 1 shows the proximate composition of ground beef and moisture content decreased as the concentration of MOLP increased, and there was a significant difference (
p ≤ 0.05) in the decreasing rates. The control samples had a higher moisture content compared to treated samples throughout the storage period. Serdaroglu [
30] reported low moisture content of oat flour-treated beef patties due to an increase in total soluble solids. Therefore, high total soluble solids might have contributed to low moisture content of treated ground beef during cold storage days. Hawashin et al. [
31] reported similar results, whereby the inclusion of destoned olive cake powder decreased the moisture content of raw beef patties.
The ash content of formulated samples significantly increased (
p < 0.05) in comparison with the control with the increase of MOLP concentration from day 0 to day 15. The ash content increased within same sample as storage days increased, with this potentially being due to the fact that MOLP is very rich in minerals such as iron, calcium, potassium, and magnesium [
32]. These findings are consistent with those of Alabi et al. [
33], who found that ash content of Hubbard broiler chicken meat supplemented with a diet of aqueous MO leaf extract significantly improved.
The protein content of treated ground beef samples significantly increased (
p < 0.05) with the increase of MOLP levels in comparison with the control sample. The protein content increased with the inclusion of MOLP within the same sample ranging from 20.09 for F0 sample in day zero to 22.15% in F4 sample in day 15. This suggests that MOLP is an excellent source of all essential amino acids, which are the building blocks of protein. The increase in protein content might have been due to antioxidant fractions found in moringa leaves [
34]. A similar trend was reported by Subha et al. [
35], whereby MOLP improved the protein content of rohu fillets in comparison with the control sample. Moreover, high protein content of treated ground beef might be attributed to the maturity stage of MO leaves, since young leaves tend to have a higher protein content than older leaves [
36].
The findings of this study are the same as those of Aberra Melessea et al. [
37], who demonstrated that the inclusion of different levels of
Moringa stenopetala leaf powder improved the protein content of Arsi-Bale goat meat. Higher crude protein content of the MO products is beneficial to consumers, especially growing children who require protein in higher amounts.
The fat content of treated samples decreased slightly but was still higher than those of the control from day 0 to day 15 within the same sample. This is because MOLP has a small amount of fat (2.3%) [
38]. However, there was no significance difference (
p < 0.05) in samples during days 0, 5, 10, and 15. Low fat content of treated ground beef samples ensures that beef maintains its quality. Too much fat undergoes oxidative degradation, resulting in rancidity, thereby decreasing the shelf stability of ground beef. Therefore, the control sample is more susceptible to spoilage than treated ground beef. The low fat content of treated ground beef samples may be due low fat content of MOLP [
39]. Contrastingly, Nkukwana et al. [
40] reported no significant difference in fat content of chicken breast meat supplemented with MO leaf meal.
3.2. Polyphenolic Compounds
The total phenolic content (TPC) of treated ground beef was significantly higher (
p < 0.05) in comparison to the control from days 0, 5, 10, and 15 with increase in the concentration of MOLP, as shown in
Table 2. This is associated with the level of TPC per unit volume of MOLP. Das et al. [
41] indicated that the TPC of MOLP is 48.36 mg/g. The increase in TPC values of ground beef with increase in MOLP concentration is attributed to MOLP being a good source of antioxidants. The phenolic compounds found in medicinal plants such as moringa are of significant interest because they are associated with biochemical and pharmacological properties such as anticarcinogen and antioxidant effects [
42]. Similar results were also reported by Negi and Jayaprakasha [
43] and Naveena et al. [
44], wherein the inclusion of pomegranate peels and pomegranate rind powder extracts increased the TPC of raw chicken patties.
The total flavonoid content (TFC) of treated ground beef samples was significantly higher (
p < 0.05) from days 0, 5, 10, and 15 within the same sample, with an increase in concentration of MOLP compared to the control sample. The TFC ranged from 8.11 in control sample (F0) during day zero to 21.84 mg/g for F4 sample in day 15, respectively. Mature MOLP is rich in flavonoid content [
16]. Increase in TFC of treated ground beef shows the strong ability of MOLP to serve as a donor of hydrogen, reducing agents and singlet oxygen scavenger to inhibit lipid oxidation in meat [
45]. Therefore, phenolic compounds as well as flavonoids probably enhanced the antioxidant activity of ground beef. Mahmound et al. [
23] reported similar results, whereby inclusion of orange peel improved the TFC of beef burger.
3.3. Lipid Oxidation and pH
Figure 1 shows the TBARS values of ground beef treated with MOLP during cold storage. The inclusion of MOLP decreased the TBARS values from days 0 to 15. The decrease of TBARS in treated ground beef might be due to polyphenols in MOLP, which adsorbs and neutralises free radicals, leading to the prevention of fat oxidation [
46]. Fat oxidation and generation of volatile metabolites might be attributed to the increase in TBARS of ground beef during storage days [
47,
48]. However, samples treated with MOLP displayed delay in lipid oxidation at the end of storage day compared to the untreated sample (control).
Several studies have documented the positive relationship between reduced lipid oxidation and polyphenol content or antioxidant activity of plant extracts [
1,
49]. The association of natural substances such as polyunsaturated fatty acids with catalysts such as iron ion from the tissue of ground beef might have contributed to high values of TBARS in control sample throughout the storage days [
50]. Such storage will ultimately promote the breakdown of heme compounds, thereby liberating the low-molecular-weight iron compounds in ground beef that are assumed to be accountable for lipid oxidation. Das et al. [
51] reported similar results, wherein the inclusion of pre-blended carnosine decreased the TBARS values of ground buffalo meat during storage days. Moreover, the same authors reported that certain bacteria such as
Pseudomonas ovalis,
Micrococcus freudenseichii, as well as strains of
Streptomyces also contribute to lipid oxidation by producing compounds such as aldehydes, ketones, peroxides, and carbonyls or other similar compounds.
There were significant differences of pH values (
p < 0.05) in all samples throughout storage days, except at day zero. Between days 0, 5, 10, and 15, the pH increased from 5.49 to 5.61, 5.74 to 5.44, 6.48 to 5.85, and 6.87–6.28, respectively, during storage days, as indicated in
Figure 2. The high pH values of ground beef during storage might be attributed to the proliferation of Gram-negative bacteria such as
Pseudomonas,
Moraxella, and
Acinetobacter, which resulted in the accumulation of metabolites [
52]. Moreover, the rise of pH values throughout cold storage might have been due to bacteria utilising amino acids after the loss of stored glucose during the breakdown of proteins. This results in the build-up and generation of ammonia formation, which gives rise to the pH values of ground beef throughout the cold storage days [
53].
According to Wapi et al. [
54], meat with a pH greater than normal of 5.8 is more prone to spoilage and results in lower shelf-life. Moreover, the higher meat pH results in less myoglobin, with the meat muscle becoming firm due to the high water holding capacity. Similar results were reported by Verma and Sahoo [
55], wherein the incorporation of pre-blended tocopherol acetate increased the pH of ground chevon meat during refrigerated storage. Das et al. [
56] also reported similar findings of a gradual rise in pH values of ground and cooked chevon meat incorporated with curry leaf (
Murraya koenigii) during the cold storage period of 20 days.
3.4. Microbiological Quality
The inclusion of MOLP did not affect the microbial properties of the ground beef during cold storage. The results show that the microbial population significantly increased during the storage days. Treated ground beef samples had lower microbiological counts at day 0 and increased with storage time from day 5 to 15, as indicated in
Table 3. This could be attributed to the low dosage of MOLP, which was not enough to impart an antimicrobial effect on microbial growth. However, treated ground beef samples had lower microbial count during storage days in comparison with the control. The decrease in microbial count could be attributed to MOLP being an excellent source of phytochemicals such as flavonoids and phenolic acids, which are used as antimicrobials agents [
57].
Moringa oleifera has a strong antimicrobial activity, with this being in line with the work of Okorondu [
58], which notes that MO quantitative phytochemical screening showed that it contains alkanoids, flavonoids, cyanogenic glycosides, tannins, and saponins that can be successfully used to reduce and eventually destroy microbes in appropriate dosages.
Moreover, internal factors such as high protein and fat content, together with various external factors such as temperature and oxygen, which influence the behaviour of bacteria in food system as well as acting synergistically with preservatives such as antimicrobials, might also have contributed to the low microbial count in treated ground beef samples [
59].
Neall [
60] reported a wide spectrum of antimicrobial action in MO that works against most bacteria (Gram-positive and Gram-negative). Increasing MO level had a good influence because the antimicrobial mechanisms of phenol compounds rely on their level. Moreover, the coliform bacteria group, yeast, and mould could be reduced by decreasing free water. This is caused by the increased water binding ability of MOLP, which retards their growth [
61]. The inclusion of MOLP in ground beef significantly (
p ≤ 0.05) decreased the coliforms in comparison with the control sample, demonstrating the protective role of MOLP, which could improve the safety of ground beef during cold storage. Nevertheless, these results are in line with those reported by Muthukumar et al. [
62] and Krishnan et al. [
63]. They found that microbial growth increased during the storage period of ground pork patties and raw chicken meat treated with MOLP and spice extracts, respectively.
3.5. Colour Properties
During the storage days, the colour values of ground beef samples were influenced by the inclusion of MOLP in all treatments, as presented in
Table 4. The lightness values of treated ground beef samples increased from days 0 to 15 with an increase of MOLP concentration. For the control sample, lightness values decreased with the passage of time. The low L * value in the control sample might be attributed to the high levels of redness in meat and muscle pigment. Naveena et al. [
45] reported a reduction in the L * value of chicken patties with the inclusion of pomegranate peel powder extract. In addition, Rojas and Brewer [
64] observed an increase in the L * value of frozen vacuum-packaged pork and beef during the frozen storage period of 4 months, although it later stayed constant due to the inclusion of natural antioxidants. Moreover, the inclusion of MO seed flour increased the L * values of beef patties [
65].
The a * (stability of the red colour) values significantly increased (
p < 0.05) with the increase of MOLP concentration in treated ground beef samples. The control sample had lower a * values throughout the storage period. Low a * values of control sample during storage is related to oxidised myoglobin, metmyoglobin formation, and lipid oxidation of meat products [
53]. Krishnan et al. [
63] reported the probability of oxidation of pigment that catalyses lipid oxidation and produces free radicals that might oxidise the iron atom as well as denature the myoglobin molecules, causing a decrease in meat colour. Nevertheless, different factors can influence the stability of meat colour but the formation of metmyoglobin due to free radicals is the main cause of this phenomenon [
66]. These results are similar to those of Liu et al. [
67] and Kim et al. [
50], wherein the inclusion of plant extracts improved the a * values of beef patties.
There was reduction of b * (yellowness) in the control sample in comparison with samples treated with MOLP during storage. The yellowness increased with an increase in concentration of MOLP but decreased with storage. The increase in yellowness of treated ground beef might have been due to the presence of carotenoids in MOLP [
68]. However, these results are different from those of Shah et al. [
53] and Muthukumar et al. (2014), who reported that the inclusion of MOLP decreased b * values of beef patties and raw pork during storage.
The chroma significantly increased with the addition of MOLP in comparison with the control sample, but decreased with storage. The increase in chroma values of treated ground beef might have been due to an increase in a * values with the addition of MOLP [
69]. Therefore, the addition of MOLP improved colour intensity of ground beef. Nkukwana et al. [
40] reported similar results, wherein the addition of MO leaf meal increased the chroma values of chicken breast meat.
The H * (hue angle) value of the control sample was significantly (
p < 0.05) higher than ground beef treated with MOLP. This implies that a high concentration of MOLP decreased the hue angle of raw ground beef. Therefore, MOLP shifted the hue angle to below the average in the control sample. These findings show a similar trend to that reported by Dzib et al. [
70], wherein the inclusion MO meal decreased the H * value of the Mexican hairless pig meat. Low a * and C * values and high H * values indicate meat discolouration due to their positive association with concentration of metmyoglobin in meat and meat products [
71].
The total colour difference (ΔE) of the control sample was significantly higher (
p < 0.05) than ground beef samples treated with MOLP. However, there was no significant difference (
p > 0.05) between treated ground beef samples during storage. The total colour difference is noticeable when it is beyond 2 [
72]. On the basis of this information, the control sample had a measurable colour difference from 5, 10, and 15 days of storage, and the treated sample (0.8%) showed a noticeable difference at day 10. Other treated samples (0.2, 0.4, and 0.6%) did not show any measurable colour difference up to 15 days of storage, indicating that the addition of 0.2, 0.4, and 0.6% of MOLP does not change the colour of ground beef during storage. Nkukwana et al. [
40] reported similar results, wherein the inclusion of MO leaf meal did not have significant effects on the total colour difference of chicken breast meat.
3.6. Cooking Properties
Table 5 shows the cooking properties of the control sample and treated ground beef. The inclusion of MOLP significantly (
p ≤ 0.05) influenced the cooking properties of ground beef. The cooking yield, moisture, and fat retention of treated ground beef significantly (
p ≤ 0.05) increased in comparison with control samples from day 0 to 15. The increase in cooking yield of treated ground beef might be attributed to MOLP’s absorption of fat and water and its ability to maintain moisture in the matrix of ground beef [
73]. In addition, the increase of ground beef pH due to the inclusion of MOLP likely accounts for the increase in cooking yield.
Low cooking yield of the control sample during storage might be attributed to the reduction in the protein solubility as well as post-mortem enzymatic hydrolysis of ATP [
51].
Improved moisture retention of treated ground beef samples could have been due to increased water absorption ability of protein powder and dissociation of proteins in the MOLP [
74]. The inclusion of MOLP improved moisture and fat retention, with this potentially demonstrating the presence of a stronger structure of meat matrix in ground beef with the high concentrations of MOLP [
75].
The increase in fat retention of treated ground beef samples could be attributed to swelling of starch and fibre. Moreover, the fat absorbed by the fibre might interconnect with protein matrix to prevent fat from migrating from ground beef [
76]. Similarly, the fat and moisture retention of beef patties improved due to high water and oil binding capacity of MO meal flour [
77]. Similar results were also recorded by Al-Juhaimi et al. (2016), wherein the inclusion of MO seed powder improved the cooking properties of beef patties.
3.7. Sensory Properties
Table 6 shows the effect of MOLP on the sensory analysis of raw ground beef stored at 4 ± 1 °C for 5 days and cooked in the oven for 30 min at 130 °C. Sensory properties such as colour, taste, springiness, and overall acceptability significantly decreased with the inclusion of MOLP, except for tenderness and juiciness. Similar results of decrease in sensory values of low-fat ground pork patties treated with carrageenan were reported by Kumar and Sharma [
78] and were attributed to the decrease in moisture loss and surface dehydration during storage. The increase in moisture retention of the treated ground beef during cooking might be attributed to higher tenderness and juiciness. However, the control sample received a higher overall acceptability score, although there was no significant difference (
p > 0.05) between samples F1, F2, and the control sample in all sensory attributes. This is attributed to the inclusion of only a small amount of MOLP (0.2 and 0.4%).
Low values of colour scores in treated ground beef may be associated with the green colour of MOLP, which arises from its chlorophyll content. The significantly lower taste acceptability of treated ground beef (F3 and F4) samples may be attributed to the bitter taste of MOLP. Bitterness in MOLP is due to the presence of the glucosinolate–myrosinase system, which is responsible for the bitter tastes in Brussels sprouts, kale, and collard greens [
79]. Glucomoringrin and glucosoonjnain have been identified as the principal glucosinolates in MOLP, and therefore the activity and specificity of myrosinase is responsible for the bitterness [
80]. The results suggest that the bitter taste is retained with the increase in MOLP concentrations. Moreover, inclusion of MOLP in ground beef resulted in unfamiliar odours. Our findings are similar to those reported by Jayawardana et al. [
81], whereby consumers preferred the appearance, colour, odour, and taste of control sample chicken sausages added with 0.04% Butylated hydroxytoluene and 0.25% or 0.50 MOLP, with concentrations above 0.50% negatively affecting the sensory attributes.