1. Introduction
Donkeys (
Equus asinus) were domesticated in Northeast Africa thousands of years ago [
1] and today are still working animals that contribute to million people life in developing countries. In Europe and specifically in Italy, donkeys have been employed as working animals until the Second World War; however, with the improvement of the mechanization in agriculture and with the mechanization and the emptying of rural areas in favour of urban ones, the importance and the number of donkeys dramatically decreased [
2]. Donkeys are perceived as a land protective, eco-friendly, and innovative activity; moreover, they contribute to the rural development. Actually, in the European Union, donkey farming has another appeal. Particularly, donkey rearing is now considered to have a renewed interest mainly for milk [
3,
4,
5] and meat production [
2,
6,
7].
The acceptance of donkey meat, likewise horse, have been conditioned by the productive destiny of the species. Although there are traditional dishes of asinine fresh meat, mainly in Northern Italy, nevertheless several foods, e.g., dry cured sausages, were originally obtained from animals that were slaughtered at the end of working live [
6,
8]. It is known that the flesh of equids is rejected, especially in the English-speaking world [
9,
10]; in fact, its consumption appears virtually absent in the United Kingdom, the United States and Australia [
11]. Actually, agriculture, meat and milk productions, social activities, and also tourism and leisure represented the principal types of uses of donkey in Europe [
12]. Donkey meat is particularly consumed in some southern European countries, such as Spain and Italy, where, although there is not a great accuracy in data collecting, it is well known that is used for some typical dishes. It has been recognized as a nutritive food for human consumption with good-quality proteins, vitamins, and minerals, low intramuscular fat content, and great iron concentration [
7]. Despite that the meat of equids has been perceived too as second-choice food over the past years (including in horse-consuming nations), its appeal is deeply evolved [
6,
13,
14,
15,
16,
17]. Consumer acceptability of meat can be influenced by many aspects, such as nutritional properties, tenderness and texture characteristics, colour, and marbling, particularly linked to visual appearance, and mostly sensory profile [
18,
19,
20]. All of these characteristics can be influenced by many factors and aging, applied in meat industry for years, had great implications on consumer acceptability [
18]. Meat sensory acceptability may depend on cultural factors, themselves linked to regional customs, particularly for donkey meat. Although it has been extensively studied in different species, focusing on improving meat flavour, sensory profile, and consumer perception, few studies focused on equids meat aging and its effects on sensory and aroma characteristics, and the most of them on horse meat [
18,
21,
22,
23,
24,
25], and no one on donkey meat. There is a lack of knowledge on aging technique and their effects on donkey meat characteristics and consumers’ perceiving. Flavour and sensory profile are key factors that are able to determine the consumer satisfaction and, consequently, the potential meat market [
26], and reactions, such as sugar reductions, lipid oxidation, and hydrolysis, are the principal mechanisms that are linked to aroma compounds formation during storage and cooking [
27]. On the other hand, aging is the way that leads the muscle transformation in meat, improving eating quality and leading to the release of substances (free amino acids, peptides, free fatty acids) themselves substrate for flavour compounds formation [
28]. Thousands of volatile compounds have been identified in cooked meat, some of them being able to affect sensory attributes and consumer perception of the meat, but no studies were conducted until now on donkey meat.
This study aims to start to fill the gap of knowledge on donkey meat and the vacuum aging effect on the Volatile Organic Compounds (VOCs), oxidative profile and status, and the sensory characteristics.
2. Materials and Methods
Ten Martina Franca donkeys’ male foals were involved in the trial. They were born from March to May 2017 and fattened until slaughter age (18 months) in the same farm. They were individually reared and fed with the same rations and feed supply.
At the age of 18 months, each animal was transported and slaughtered at a European Community-approved abattoir, in compliance with European Community laws on Animal Welfare in transport (1/2005EC) and the European Community regulation on Animal Welfare for slaughter of commercial animals (1099/2009EC) located at 22 km from the farm. The journey time was about 20 min. After slaughtering, carcasses were dressed following commercial dressing-out procedures at the abattoir [
29]. No electrical stimulation was used. Immediately after slaughter, carcasses were chilled at 4 °C in a chilling room for 24 h. Afterwards,
Longissimus thoracis (LT) muscle was extracted from each left half carcass, between the fourth and the ninth rib. Each muscle was divided into five sections, vacuum packaged, stored at 2 °C, and then randomly assigned to one of the different aging time (1, 3, 6, 9, and 14 days of aging); cranial and caudal sections were randomized across aging time. For packaging the Besser Vacuum
® film (Besser Vacuum, Dignano, Udine, Italy) was used. It is characterised by 65 µm thickness, 63 g/m
2 of weight, ≤65 cm
3/m
2 × day × bar of oxygen permeability at 23 °C and 0% of relative humidity and ≤3.5 g/m
2 × day of water vapor permeability at 23 °C and 85% of relative humidity. Ten samples were obtained and analysed at each aging time.
2.1. Chemical Composition
Chemical composition was performed exclusively on samples at first aging day. Moisture [
30], protein [
31], intramuscular fat [
32], and ash [
33] content were calculated according the International Organization for Standardization (ISO) methods. The samples were analysed in triplicate.
2.2. Volatile Compound Analysis
All of the procedures were performed at each aging time. Samples (5 g) of foal steaks were grilled at 130–150 °C for 5 min. on each surface, using an electrical griddle (Delonghi, Mod. CG660, Treviso, Italy). A heating treatment was considered complete when all the steaks reached an internal temperature of 70 °C measured with a copper constantin fine-wire thermocouple fixed in the geometrical centre of the sample (Model 5SCTT-T-30-36; Omega Engineering Inc., Norwalk, CT, USA). After cooking and cooling, the samples were minced while using a commercial grinder (Moulinex/Swan Holding Ltd., Birmingham, UK), vacuum-packed, and stored at −30 °C for no longer than two weeks until analysis.
2.2.1. SPME Extraction
The SPME tool from autosampler was loaded with a fused-silica fibre (10 mm length) coated with a 50/30 mm thickness of DVB/CAR/PDMS (divinylbenzene/carboxen/polydimethylsiloxane) (Supelco, Bellefonte, PA, USA). Before the analysis, the fibre was conditioned by heating in a SPME Fibre Conditioning Station at 270 °C for 30 min. For headspace SPME (HS-SPME) extraction, 1 ± 0.02 g of each sample was weighed in a 20 mL vial (Agilent Technologies, Santa Clara, CA, USA) and subsequently screw-capped with a laminated Teflon-rubber disc. The extractions were carried out at 37 °C for 30 min., after equilibration of the samples for 15 min. at the same temperature, ensuring a homogeneous temperature for sample and headspace.
2.2.2. Chromatographic Conditions
After the extraction procedure, the fibre was transferred to the injection port of the gas chromatograph–mass spectrometer (GC-MS) system (7890B GC-System; Agilent Technologies, Santa Clara, CA, USA and a mass selective detector 5977B MSD; Agilent Technologies, Santa Clara, CA, USA). The column that was used for volatile separation was a DB-624 capillary column (30 m, 250 µm i.d., 1.4 μm film thickness; J&W Scientific, Folsom, CA, USA). The chromatographic conditions and mass spectrometer parameters were previously described [
34].
2.2.3. Data Processing
After chromatographic analysis, all of the data were analysed with the software Mass Hunter Quantitative Analysis B.07.01. A new method from acquired scan data with library search was created. The integration was done with Agile2 algorithm, while peak detection was done with deconvolution. Compounds were identified by comparing their mass spectra with those that were contained in the NIST14 library (National Institute of Standards and Technology, Gaithersburg, MD, USA). The compounds were considered to be correctly identified when their spectra presented a library match factor >85%. After integration, peak detection, and identification of each compound, the Extraction Ion Chromatogram (EIC) from the Quantifier Ion was obtained from each peak. The results were expressed as area units of the EIC × 103 per gram of sample (AU-EIC × 103/g of sample).
2.3. Thiobarbituric Acid Reactive Substances (TBARS), Hydroperoxides and Protein Carbonyls Analyses
Raw minced samples (5 g) were placed in a 50-mL test tube and homogenized with 15 mL deionized distilled water (DDW). Homogenate (1 mL) was transferred to a glass tube for the TBARS determination and 0.05 mL of butylated hydroxytoluene (7.2% in ethanol) was added along with 1.950 mL of thiobarbituric acid (TBA)/trichloroacetic acid (TCA)/HCl (0.375% TBA, 15% TCA, and 0.25 N HCl). The sample solution was shaken and then incubated at 90 °C for 15 min. in a thermostatic bath. After this period, the samples were cooled to room temperature (15–30 °C) and then centrifuged at 2000×
g for 15 min. Supernatant absorbance at 531 nm was measured against a blank containing 2 mL of TBA/TCA/HCl solution in 1 mL of distilled water. The TBARS were calculated when comparing with a standard curve constructed with 1,1,3,3-tetramethoxypropane, and the concentration of lipid oxidation was expressed as milligrams of malondialdehyde (MDA) per kg of meat [
35].
For hydroperoxides quantification, 2 mL of homogenate (previously prepared for the TBARS determination) were added with 4 mL of CH
3OH and 2 mL of CHCl
3. The samples were vortexed for 30 s and added with 2 mL of CHCl
3 and 1.6 mL of 0.9% NaCl. The samples were shaken for 1 min. and then centrifuged at 3500×
g for 10 min. at 4 °C. Two millilitres of lipid extract were sampled from the lower chloroform phase and then processed with 1 mL of CH
3COOH/CHCl
3 and 50 μL of KI (1.2 g/L mL distilled water). Samples were stored for 5 min. in a dark room and added with 3 mL of 0.5% of CH
3COOCd and then vortexed and centrifuged at 4500×
g for 10 min. at 40 °C. Absorbance at 353 nm was measured against a blank tube in which meat homogenate was replaced by 2 mL of distilled water [
36]. The results were expressed in micromoles per gram according to Buege and Aust [
35].
Meat samples (2 g) were homogenized in 20 mL of 0.15 M KCl for 2 min. Two aliquots of homogenate (50 μL each) were added with 1 mL 10% TCA and then centrifuged at 1200×
g for 3 min. at 4 °C to measure protein oxidation. The first aliquot was used as a standard and added with 1 mL of 2 M HCl solution. The second aliquot was added with 1 mL of 2 M HCl containing 10 mM 2,4-dinitrophenyl hydrazine (DNPH). The samples were incubated for 1 h at room temperature (15 to 30 °C) and shaken every 20 min., and then 1 mL of 10% TCA was added. The samples were vortexed for 30 s and centrifuged three times at 1200×
g for 3 min. at 4 °C and the supernatant removed. Care was taken not to disrupt the pellet. The pellet was washed with 1 mL of ethanol:ethyl acetate (1:1), shaken, and centrifuged three times at 1200×
g for 3 min. at 4 °C and the supernatant removed. The pellet was then dissolved in 1 mL 20 mM sodium phosphate 6 M guanidine hydrochloride buffer. The samples were then shaken and centrifuged at 1200×
g for 3 min. at 4 °C. Carbonyl concentration was calculated on the DNPH treated sample at 360 nm with a Beckman Coulter DU800 (Beckman Instruments Inc., Brea, CA, USA) and expressed as nanomoles carbonyl per milligrams protein. Protein concentration was calculated according to the Biuret assay [
37,
38].
2.4. Superoxide Dismutase, Catalase and Glutathione Peroxidase Activity Evaluation
Two samples of 400 mg of raw meat were homogenized in a tissue homogenizer 4 mL saline at 4 °C. The homogenate was centrifuged at 4 °C for 20 min. at 7000× g and the supernatant was collected to determine the antioxidant enzyme activities. Plasma was analysed as it was.
Superoxide dismutase (SOD, EC 1.15.1.1) was evaluated by Misra [
39] method. The activity was determined from its ability to inhibit the autoxidation of epinephrine. The stimulation of epinephrine autoxidation by traces of heavy metals present as contaminants in the reagents or by the other metals under investigation was prevented by adding 10–4 M EDTA in the buffer in order to chelate these ions. One unit of SOD is defined as the amount of enzyme required to inhibit the rate of epinephrine autoxidation by 50%. The enzyme activity was expressed as U/mg protein.
Catalase (CAT, EC 1.11.1.6) activity was assayed by the method of [
40], by following the decrease in absorbance of H
2O
2 at 240 nm (e = 40 M
−1 cm
−1). One unit of enzyme activity is defined as the amount of enzyme that is required to degrade 1 micromole of H
2O
2 in 1 min. and it is expressed as U/mg protein.
Glutathione peroxidase (GPx, EC1.11.1.9.) activity was measured by method of [
41]. The reaction measured the rate of GSH oxidation by tert-butyl hydroperoxide, catalyzed by GPx. GSH was maintained at constant concentration by the addition of exogenous GR and NADPH, which converted the GSSG to GSH. The rate of GSSG formation was then measured by the change in the absorbance of NADPH at 340 nm (e = 6.2 mM
−1 cm
−1) and activity expressed as nanomoles of NADPH oxidized/min/mg protein.
2.5. Sensory Analysis
Sensory analysis was performed by an eight-person trained taste panel. The panels were selected for their sensory acuity using the British Standards Institution (BSI, 1993) methods. At each experimental time, samples were unpackaged and, after sampling five grams for VOC’s analysis and 5 g for enzymes and oxidative profile, were cooked as previously described for VOCs. Connective tissue and fat were trimmed, and the muscle cut into about 2 cm
3 blocks, which were wrapped in pre-labelled foils and placed in a heated incubator until given to the assessors. The samples were tasted in an order based on the designs outlined by MacFie, et al. [
42] for balancing the carryover effects between samples. The panel test was organized in four different sitting sessions for each panellist, at each aging time. During two sessions, each panellist received four samples for each session and, during the other two sessions, each panellist received six samples for each sessions, for a total of 20 samples for each panellist (two samples for each one of the ten donkeys) at each experimental aging time. The samples were randomised by the sensory panel software, in a different order for each panellist. Tested samples were scored on a 1–10 point scale for tenderness (1 = extremely tough to 10 = extremely tender), juiciness (1 = extremely dry to 10 = extremely juicy), overall licking (1 = extremely disliking to 10 = extremely licking), sweetness, unpleasant taste, meaty odour, and unpleasant odour, (1 = extremely weak to 10 = extremely strong).
2.6. Statistical Analysis
Data were tested for normal distribution and variance homogeneity by Shapiro–Wilk test. After were subjected to a nested one-way analysis of variance (ANOVA) while using the SAS program. The independent variable was the aging time (1, 3, 6, 9, and 14 days). The mean values and standard error of the means (SEM) were calculated. When a significant effect (p < 0.05) was detected, means were compared while using the Tukey’s test.
3. Results
Donkey meat chemical composition showed mean moistures values of 73.04 ± 1.58 g/100 g of meat, mean protein values of 18.06 ± 0.83 g/100 g of meat, mean intramuscular fat values of 1.52 ± 0.52, and mean ash values of 1.06 ± 0.19 g/100 g of meat (data not shown).
122 Volatile Organic Compounds (VOCs) have been identified from donkey (
Equus asinus)
Longissimus thoracis muscle during the aging process.
Table 1 shows the effect of aging time in the aromatic hydrocarbons (12 VOCs) and aldehydes (18 VOCs) of donkey meat steaks aged for 14 days under vacuum conditions. The total amount of aromatic hydrocarbons and the most abundant furan, 2-pentyl- showed decreased values at the sixth day of ageing compared to the 1st (
p < 0.01).
The total amount of aldehydes did not show significant differences (p > 0.05), although some singular and poor represented aldehydes showed few statistical differences with prro increasing trend during aging as Propanal,2-methyl-, butanal butanal, 3-methyl-, benzaldehyde, benzeneacetaldehyde, and 5-ethylcyclopent-1-enecarboxaldehyde (p < 0.01).
Table 2 summarizes the effect of aging time in the (linear) hydrocarbons (50 VOCs) of donkey meat steaks that were aged for 14 days under vacuum conditions. The total amount of hydrocarbons did not show significant differences (
p > 0.05), although only pentane and the 2-octene, (E)- showed poor variation during ageing (
p < 0.01).
Table 3 shows the effect of aging time in the ketones (16 VOCs) content of donkey meat steaks aged for 14 days under vacuum conditions. The total amount of ketones did not show significant differences (
p > 0.05). Only 2,3-pentanedione, 2-hexanone and 3-octanone, 2-methyl-, poorly representing in the total amount, showed significative variation during aging (
p < 0.01).
The effect of aging time in Alcohols (12 VOCs), carboxylic acids (3 VOCs), nitrogen compound (five VOCs), and sulphur compound (2 VOCs) content of donkey meat steaks aged for 14 days under vacuum conditions are reported in
Table 4. Ageing did not affect the alcohols production (
p > 0.05); differently, the total carboxylic acids and total nitrogen compounds were significantly affected by aging time (
p < 0.01) showing an increasing trend. Finally, the aging time did not affect the sulphur compounds (
p > 0.05).
The effect of aging time in TBARs, hydroperoxides, protein carbonyls, superoxide dismutase, catalase, and glutathione peroxidase values of donkey meat steaks aged for 14 days under vacuum conditions are reported in
Table 5. TBARs values at nine and 14 aging days are higher than those observed at three aging days (
p < 0.01). Differently, hydroperoxides and protein carbonyls did not show any variation during the storage time (
p > 0.01). Moreover, all of the antioxidant enzymes displayed an increase day by day during the aging time (
p < 0.01).
Table 6 presents the effect of aging time in sensory properties of of donkey meat steaks aged for 14 days under vacuum conditions. Sweetness, meaty odor, and overall liking tend to increase during the aging time with higher values at 14 aging days compared to one day (
p < 0.05). However, the other sensorial parameters did not show any significant difference due to aging time (
p > 0.05).
4. Discussion
There is a great variation in volatile compounds generation from meat [
44,
45], probably due to different reasons for their complexity in the formation and also to eventual interactions [
46]. The main source of VOCs is the lipid content. Most of the volatile compounds (acids, aldehydes, ketones, and alcohols) derived from lipid autoxidation and can themselves promote the formation of other components such as nitrogen and sulphur-containing compounds [
44]. Moreover,
rigor-mortis or
post-mortem glycolytic fluxes represented processes that are able to modify the volatile fraction of fresh meat [
47].
The largest share of aromatic hydrocarbons is represented by the furan-2-pentyl-, which probably affected the statistical trend of the family. Other chemical compounds were much less represented; moreover, the detection of several molecules (toluene, benzene, benzene, 1,3-dimethyl-) would appear to be a consequence of their presence in animal feedstuffs and diet [
48]. As suggested by several authors [
49,
50], the increase of aromatic hydrocarbons is mainly originated from lipid oxidation and has a relevant contribution to meat flavour, particularly a green bean/butter aroma is given by furan-2-pentyl-. The benzene is characterised with pleasant and distinct flavour, such as the sweeter 3-carene [
51]. The toluene was characterised by fruity and sweet aroma as showed in goat meat by Madruga, et al. [
52]. However, all of these VOCs are poorly represented in our study. Olivares, et al. [
53] reported that toluene and ethylbenzene, the last one significantly decreased by ageing in our work, were most likely derived from amino acid degradation than lipid oxidation. The most represented aromatic hydrocarbon was the furan, 2-pentyl-, showing more than 85% of the total aromatic hydrocarbons, and it probably affects the statistical differences of the entire VOCs family. In similar studies that were conducted on horse meat vacuum aged, Maggiolino, et al. [
54] and Tateo, Maggiolino, Domínguez, Lorenzo, Dinardo, Ceci, Marino, Della Malva, Bragaglio, and De Palo [
25] observed that VOCs formation and trend changed depending on muscle considered. In fact, vacuum aging in
Semimembranosus muscle only affected toluene, whereas in
Longissimus thoracis muscle the vacuum aging modified the benzene and 3-carene content. But more interesting is the total absence of the furan, 2-penthyl- that is, instead, the most produced in
Longissimus thoracis donkey meat. As said before, usually aromatic hydrocarbons derived from the lipid oxidation [
49,
50], but we observed a decreasing trend of total aromatic hydrocarbons VOCs. First of all, the lipid oxidation would be slightly depressed under vacuum aging [
45], probably also for the low permeability of the film, and this can explain why aromatic hydrocarbons did not increase during the aging process. The results reported about oxidation products, as TBARs and hydroperoxides, strengthened this hypothesis. They remain constant during the aging period, as reported in horse meat [
25], confirming that probably lipid oxidation is slightly depressed for both the short period and the packaging type [
45,
55], also considering the film low permeability.
The total amount of aldehydes was not significantly affected by ageing. On the contrary, the values of many aldehydes individually changed, following a heterogeneous trend. First of all, we must consider the limited number of animals that are involved in the trial. This aspect may have influenced the large variability of results with no statistical differences. However, the hexanal that represented about the 85% of the total aldehydes and also the most abundant VOC generate did not show any change during the vacuum aging. This result agrees with studies that were conducted on horse meat vacuum packaged [
25,
54], but also with other studies conducted on same species (horse) in different storage conditions [
56] and in different species and storage conditions as beef [
57], pork [
58], and lamb [
59], in which researchers reported that hexanal is the most abundant VOC. Hexanal, which gives the meaty, grassy, and fatty odours to the meat, as the most of aldehydes, derived from phospholipids and polyunsaturated fatty acids oxidation [
46,
60,
61], and the constant trend seems to validate the hypothesis of a reduced oxidative activity in meat vacuum stored. The authors reported a positive correlation between aldehydes formation and degree of oxidation, particularly with TBARs [
62], and the absence of variation of both oxidative parameters and aldehydes seems to consolidate this hypothesis.
Linear hydrocarbons identified are the most numerous, although some authors pointed out their unimportant role in meat flavour [
49], but not the most abundant, differently from that found by some authors in beef meat [
45]. As observed in horse meat [
25,
54], the heptane,2,2,4,6,6-pentamethyl- and the undecane are the most abundant, representing around 20% and 10% of total linear hydrocarbons in cooked donkey meat, respectively. Although it seems that linear hydrocarbons also derived by autoxidation processes, particularly of long-chain fatty acids, are principally formed after lipids thermal homolyses [
63], and therefore after heat treatments, as cooking. Only two linear hydrocarbons showed changes during aging time, pentane, and 2-octene, together representing less than 1% of total linear hydrocarbons, but the total hydrocarbons did not modify during the whole display. Our results can confirm the idea that oxidative processes are strongly reduced, probably due to the low oxygen permeability of the used film.
This study highlighted significant differences in three ketones: 2,3-pentanedione; 2-hexanone; and, 2-methyl-3-octanone, representing around 2% of the total ketones. In fact, the total ketones did not change during the aging process. Ketones are considered very important in giving flavour on cooked meat, in fact it is reported that are responsible of sweet, buttery, spicy, ethereal, caramel, cheese and fatty notes [
49,
54,
64]. The main substrate responsible of their formation is the intramuscular fat, deriving from fatty acids oxidation, and their formation and production are positively correlated with intramuscular fat content [
65]. However, this is not the only route of formation, because they can also derive from Maillard compounds [
66] and from lipolytic activity and alkane degradation by microbial metabolism (β-oxidation) [
67,
68]. The very probable lack of oxidative processes on intramuscular fat and fatty acids and, consequently, the probable inactivation of microbial activity and the equal cooking method adopted, can easily explain the absence of variation of total ketones compounds during the aging time. However, is really interesting to observe that ketones formed in donkey meat are more abundant than those that are reported in horse meat vacuum packed [
25,
54], more than triple, since the acetoin was the most abundant ketones and about four times more than those found in vacuum packed horse meat.
The total alcohols showed a constant trend, and 1-hexanol was the most abundant. Although other authors observed in horse meat that this compound is the most abundant [
25,
54], they observed a different trend during the vacuum aging, showing increasing values. These compounds also derive from lipid oxidation, particularly from the degradation of oleic and linoleic acid [
69], and their liberation depends on thermal treatment [
70]. The absence of variation can be due to a probable inhibition of the oxidation processes during the vacuum aging. These compounds seem to give flavour described as resin, flower, and green aroma [
51,
56], but they also have a high odour threshold limit, so they are often classified as not important flavour contributors to meat [
70].
Carboxylic acids and sulphur compounds did not show changes and were relatively poor generated, unlike what was observed for nitrogen compounds that tend to increase during the vacuum aging. Nitrogen compounds derived by the interaction of sulphur-free amino acids with sugars lead to the formation of these compounds, like e.g., pyrazines [
71]. These compounds are particularly important, because of their lower limit aroma threshold and the garlic and onion aroma that they can give to meat. Our results agree with those observed in beef meat during the vacuum aging [
64], since the authors noticed an increase in nitrogen compounds, justifying it with a plausible release of free amino acids during the aging process that enhance, in turn, Maillard reactions. This agrees with the protein carbonyls trend that is the result of protein oxidation, which, in turn, is responsible for the greater availability of free amino acids.
Similar to that reported in horse meat [
25], antioxidant enzymes activity tend to increase during aging process. Superoxide dismutase, catalase and glutathione peroxidase represented the
in vivo cell defence system against oxidative damage [
72]. They lose their activity after slaughtering [
73,
74] due to denaturation processes and hydrolysis carried out by intracellular proteinases, and usually are characterised by a decreasing trend during aging, also for a redistribution of these enzymes between cellular compartments due to the rupture of cell walls [
75,
76]. In this regard, Tateo, Maggiolino, Domínguez, Lorenzo, Dinardo, Ceci, Marino, Della Malva, Bragaglio and De Palo [
25] noticed that this result can be explained by the kind of measurement that is used for quantifying these enzymes in meat. It is expressed as quantity on mg of proteins and the protein degradation, that lead more free amino acids release, lead also to a reduction of the concentration measurement substrate, as result giving a higher concentration, but not a higher real enzyme availability.
It seems that sensory evaluation is poorly affected by vacuum aging, although there is a positive evaluation of the product at all aging days considered. Although aldehydes did not change during the aging process, their concentration is particularly high, more than that observed by other authors in different muscle in horse meat [
25,
54]. Their impact is significant on meat aroma [
77], probably due to their low threshold odour [
78], and this can justify the good values that were registered for meaty odour and overall licking. The increasing evaluation of sweetness could assert the idea that there is a major sugar components availability who themselves become available as a substrate, together with free amino acids, for the formation of nitrogen compounds.