3.1. Proximate Analysis, pH, and aw of the Original RGP
The initial characterization of the red grape pomace is essential to know the possible applications of the byproduct. Results are expressed on a wet basis (
Table 1) since the valorization treatment was applied on the wet byproduct; the valorized ingredient should also be distributed wet. In addition, some moisture content of food products is critical for microorganism inactivation after HHP. Generally, the proximate composition of pomace varies widely and this fact makes it difficult to compare results with reports in the literature. The content of moisture was analogous to data found by Jin et al. [
3] for RGP from cultivars of
Petit Verdot,
Merlot,
Cabernet Franc, and
Chambourcin (50.7–58.1 g 100 g
−1). The main component in RGP was the total fiber, a major component in RGP, which was higher than the results reported by Ramírez et al. [
19], Teles et al. [
27], and Xu et al. [
28]. The protein content (4.5 ± 0.2%) was below those obtained by Deng et al. [
29], Jin et al. [
3], and Xu et al. [
28]. These last authors confirm that samples of RGP after the fermentation and pressing showed a biomass of yeasts and bacteria resulting from high protein content. Seeds are the main source of fat in the pomace, and that factor determines the range of fat in the pomace. Fat content was similar to those reported by Theagarajan et al. [
30], Sousa et al. [
31], and Teles et al. [
27]. Conversely, pH 4.0 in RGP allows for greater anthocyanin stability; pH > 4.5 alters different anthocyanin structures, which leads to viable fungal and bacterial growth. Thus, several factors, such as the maturity of the grapes at harvest and the conditions of the winemaking processes, explain the variability in the composition of the wine pomace reported in the literature [
32]. The studies that analyzed the aw of grape pomace are few; however, Taşeri et al. [
33] identified a similar amount to ours in a grape pomace from the
Hamburg Muscat variety.
3.2. Effect of HHP Treatments of Volatile Compounds in RGP
A total of seven volatile compounds in the RGP after processing were isolated and quantified (
Table 2). Ethanol was the most abundant compound, followed by acetaldehyde and methanol. Most of them have their origin in a fermentation process, since in the cellar, during storage of RGP, spontaneous anaerobic fermentation occurs, and the yeasts transform water-soluble carbohydrates into alcohols, esters, carboxylic acids, and aldehydes. However, methanol is not a compound from fermentation, but derived from grape pectin through the activity of the pectin methylesterase enzyme. It is well known that microbial activity on grape pomace increases the production of this enzyme [
34].
As a general trend, HHP did not modify the values of volatile compounds. Ethanol presented similar values in the control and treated RGPs, so it was not modified after processing (p > 0.05). Since the pomaces analyzed came from red winemaking, their levels of ethanol and other alcohols are generally high, and their contents should be considered in the valorization of RGP as an ingredient for food production. Because of the high amount of alcohols, the RGP can modify the sensory attributes of the end-food; thus, as an attribute of its intense taste, the ingredient should be used at low doses.
In contrast, only two compounds were modified after HHP while the other remained unchanged. Methanol, the second most abundant alcohol, significantly increased after the application of the two cycles of HHP. This is an unexpected result, and in this case, the application of two cycles would not be recommended, since methanol levels are generally limited in food products due to its toxicity. This change is difficult to explain since the changes in volatile compounds in RGP after HHP have not been previously evaluated.
In contrast, the levels of 2-phenylethanol were significantly decreased after the application of two cycles (a), while in the other treatments the levels of this compound showed intermediate values. Since the samples were analyzed immediately after processing, the changes in volatile compounds were more likely associated with physical–chemical changes in the pomace than to the modifications at the microbiological level.
3.3. Microbiological Changes in High-Pressure-Treated RGP
When a three-way ANOVA was applied (
Table 3), only mesophilic microbe count, molds, and yeasts were influenced by (1) HPP treatment, (2) storage temperature, and (3) storage time.
Enterobacteriaceae counts were only affected by factors (1) and (3). Most factors showed significant interactions among them, especially P1 × P3, which was significant for the three microbial groups evaluated.
After HHP (day 1), no significant differences in aerobic mesophilic count were observed compared to the control, while yeasts and molds and
Enterobacteriaceae were significantly decreased later than processing (
Table 4). HHP efficiency is influenced by extrinsic and intrinsic aspects: pressure intensity, process temperature, holding time, aw, microorganism species, and microorganism species growth phase [
12]. A low minimal aw in the RGP could reduce the efficacy of the treatment on this product. However, the sublethal damage after HHP could enhance the impact of the treatments together with the days of storage [
35]. In fact, at the end of storage in the control RGP, we observed an increase in the mesophilic aerobic microorganism count, 4.4 log CFU g
−1 at room temperature and 1.5 log CFU g
−1 for the refrigeration condition. Mold and yeast counts increased 3 log CFU g
−1 at these temperatures. In contrast, such an increase was not found in the treated RGP that was kept for 270 days at refrigerated temperatures. The microbiological results for the RGP after HHP are within the microbiological criteria required by EC Regulation No. 2073/2005 and EC Regulation No. 852/2004 concerning the hygiene of food products. After using HHP, there were sublethal damages related to the incomplete loss of cytoplasmatic membrane function or injury to the outer membrane of the Gram-negative organisms. It does not lead to death of the cell, but is a potential survivor that may be selectively vulnerable to inhibitory mechanisms [
35].
Enterobacteriaceae had an important diminution during the storage. This can be explained by the sensitivity of this group of microorganisms to acidic pH [
32], which could be also enhanced during storage by acidification associated with the concentration of acids from the metabolism of the remaining microbial populations.
The application of two cycles of processing was evaluated to enhance the efficacy of the treatment for the inactivation of spores in RGP. The best-known mechanism for eliminating spores by HHP is achieved in two steps: first, pressures of 50 to 300 MPa are applied to germinate the spores and, then, thermal treatments and high pressures are carried out to kill the vegetative cells [
15]. In the case of RGP, there were similar reductions in log CFU g
−1 when HHP was applied on a single cycle (Control-HHP1: −2.4, Control-HHP1: −2.8), relative to a double cycle (Control-HHP3: −2.2, Control-HHP4: −2.5) for 270 days of preservation in refrigerated or temperature of the room, so that the utilization of two cycles would not offer any advantage. In contrast, Timón et al. reported that two cycles of 600 MPa/1 s were more effective than one single cycle in chicken burgers. Differences in the characteristics of the matrix (composition, pH, microbial population) could cause this opposite behavior [
18]. The low pH and water activity of RGP can likely explain these differences relative to other products. Also, Rocha et al. [
17] emphasized that the intensity of pressure and time have an important consequence of lethality against microorganisms. In conclusion, pressures higher than 300 MPa resulted in changes in cell membranes, which generated more injury with the increase in pressure and the time of exposition.
3.4. Instrumental Color Measurement of High-Pressure-Treated RGP
When a three-way ANOVA was applied (
Table 3), only CIE b* was affected by HHP. Lightness (CIE L*) and redness (CIE a*) were altered by the storage temperature. All parameters of color (CIE L, a*, b*) were significantly changed during the time of storage. Interactions between temperature and the time of storage were significant in the three parameters, and the interaction between HHP treatment and the storage time was important for CIE L* and a*.
In line with the previous statistical analysis, the CIE L* values were affected by HHP at any day of storage (
Table 5); moreover, significant increases were found in the control at 4 °C and in all samples at 20 °C during storage. In addition, no differences were noted among HPP assays (
p > 0.05) for the color parameter a*, although it was modified through time at both storage temperatures. There is no significant difference between the control and treated RGP for CIE b* after HHP on all sampling days, although b* values were slightly lower in the treated pomace (at day 1) than in the control. During storage, all groups (except HHP1 stored at 4 °C) showed a significant increase in b* after 270 days. The increment in CIE L* as CIE a* decreased during storage (270 days) and was more marked at 20 °C than at 4 °C. These results are in line with the interactions analysis for the factors of temperature and storage time (
Table 3).
Generally, pomace shows a dark red color, given the values of +a* and +b*, and reduced values of L* [
36]. The color of the RGP from
Tempranillo used in this study showed higher lightness and lower redness and yellowness than that reported by Xu et al. [
28] on skin pomace of red grape (L*: 25.4, a*: 15.0, b*: 6.8). This pomace also contained branches that could partly explain the color differences. In addition, the composition and concentration of anthocyanins in RGP or the winemaking procedure, the type of waste, and many other factors could cause these differences [
4].
According to our findings, Xu et al. [
28] treated skins of freeze-dried red grape pomace from three varieties,
Merlot,
Norton, and
Petit Verdot, at 600 MPa × 30 min. They verified the small influence of high hydrostatic pressure on the color of RGP. The cause of color retention after processing could be because the anthocyanins, the pigments responsible of red color, are stable under HHP treatment at moderate temperature [
37]; this would agree with the maintenance of CIE a* values after HHP in our RGP.
Regarding changes during storage, the increase in b* and decrease in a* would indicate a more intense yellowness and lower redness of the RGP, respectively. The degradation of anthocyanins during storage can explain this decrease in redness. In addition, the indirect oxidation of these compounds is also associated with the activity of the enzymes that produce enzymatic browning reactions and color changes [
37].
Depending on ΔE values, the color difference specifies the degree of color change among processed and unprocessed RGP, which can be valued as 0–1.5 “not noticeable”, 0.5–1.5 “slightly noticeable”, 1.5–3.0 “noticeable”, 3.0–6.0 “well visible” and 6.0–12.0 “great” (6.0–12.0) [
13]. ΔE values ranged from “not noticeable” to “noticeable” (0.3–2.3) changes (
Table S1, Supplementary Materials). The parameter ΔE processing ranged between 0.3 and 0.8, so changes after HHP could be considered “not noticeable” when one cycle was applied. When two consecutive cycles were applied, changes were “slightly noticeable”.
Variations after 30 days of storage (ΔE storage 1–30 d) were “not noticeable” (1 cycle) or “slightly noticeable” (2 cycles) at both storage temperatures. Changes from 90 to 180 days in storage (ΔE 1–90 d, ΔE 1–180 d) were more marked at 20 °C than at 4 °C. At 20 °C, changes started to be “slightly noticeable”. At 180 and 270 days, changes were higher in the control than in the HHP-treated samples, which demonstrate the efficacy of the HHP treatment to stabilize the product during long-term storage. In addition, color changes were more intense at 20 °C than at 4 °C, so at 20 °C changes were “noticeable” at room temperature at the end of storage while samples stored at 4 °C showed “slightly noticeable” changes. Therefore, concerning color changes in RGP immediately after processing compared the storage conditions, changes in color after processing would be “not noticeable” (0–0.5) and “slightly noticeable” (0.5–0.8), while during storage, changes in color were “slightly noticeable” at refrigeration and “noticeable” at room temperature. Therefore, concerning color changes in RGP after processing and storage: (1) HHP would be recommended for long storage periods, but the temperature of the processed product should also be evaluated; (2) room temperature storage should be adequate only for short storage times (30–90 days), while for refrigeration, the color stability is higher than at 20 °C and allows for at least 270-day storage times.
Patras et al. [
37] and Cao et al. [
38] reported intense color modifications (ΔE) in strawberry pulp during storage (ΔE ≤ 3) and purées from blackberry (2.2–3.7) treated at 400, 500, and 600 MPa. Color changes in fruit products are rarely generated by HHP processing [
39]. The instability of color in vegetables processed by HHP during their storage, however, is explained by the partial inactivation of enzymes and microorganisms after processing, which remained active during storage. These results are in line with the behavior of the RGP after processing, since slight color changes were found after the treatment, while changes during storage were more intense than after processing. As reported in these studies, ΔE during storage was higher than in ours, probably due to the greater stability of pomace compared with vegetable purées, the latter having high water or moisture content that facilitates chemical reactions or microbiological development (
Table S1).
3.5. Enzymatic Activity of Polyphenoloxidase (PPO) and Total Phenolic Compounds Content (PCC) of RGP Treated by High Hydrostatic Pressure
The three-way ANOVA (
Table 3) demonstrated that the PPO enzyme activity was not altered by HHP. Otherwise, this activity was influenced by storage parameters (time and temperature). PCC was modified by three factors: HHP, time, and temperature of storage. Interactions were not significant for the PPO while PCC showed significant interactions between HHP × temperature, temperature × time, HHP × temperature × time.
PPO activity was not modified after HHP (
p > 0.05), although this enzyme had a small rise from the control to the treated RGP (
Table 6). Neither the application of two consecutive treatments at the maximum pressure made any effect. Similarly, García-Parra et al. [
40] studied the effects of HHP on plum and indicated that the treatment in some cases produces relative increases in the PPO activity, probably due to a greater interaction between the enzyme and substrate.
At the end of storage, the PPO activity had decreased for all groups (control and HHP treatments), although reductions were stronger at room temperature. Regardless, it continued to be active after 270 days of storage at both temperatures, so large damage likely occurred in the phenolic compounds, which are the substrate of the enzyme, and would continue throughout the storage at room temperature.
In contrast, the PCC was maintained after two cycles (600 MPa–1 s/600MPa–1 s), while the other HHP treatments reduced their content (74–92%) (
Table 6). At day 30 and 270, HHP1 samples stored at 4 °C showed the lowest PCC. At 20 °C, no changes were observed between the control treatment and the RGP treated by HHP at 30, 90, and 270 days of storage, while at 180 days the control showed the lowest PCC. During storage at both temperatures, the control and HHP-treated samples showed large reductions in PCC. The reductions in PCC after 270 days of refrigeration were similar in the control and in the HHP-treated RGP. The PCC was preserved after 270 days of storage with respect to their initial content, ranging between 42 and 60%. Moreover, the reductions in PCC after 270 days of storage at 20 °C were very strong and only the 6% of the original content of the PCC in the control samples was preserved upon completion of storage, while in the treated samples by HHP, the percentage of retention ranged between 9 and 16% with respect to its initial content. Therefore, generally, after 9 months of storage, half of the phenolic compounds degraded at 4 °C while around 90% was lost at room temperature. The strong reduction in PCC during storage is contrary to making an ingredient from RGP with antioxidant or antimicrobial activity, which is the main objective of this study, since PCC is mainly responsible of the bioactivity in RGP [
41]. Consequently, the red grape pomace samples had a shelf life of 90 days under the refrigerated storage conditions, in increasing order, corresponding to PCC: control < HHP1 < 2 cycles (a) and (b) < HPP2. PPO was effectively inactivated by a thermal blanching at 100 °C before HHP in white wine pomace [
14], so that could also be a solution to inactivate the PPO of RGP.
Several studies have reported PCC (mg GAE 100g
−1 DB) for untreated samples from red grape pomace of varieties such as
Cabernet Sauvignon (1270–2670),
Merlot (1830–2500),
Pinot noir (1120–2140) [
29],
Cabernet franc (3610),
Petit Verdot (6480),
Chambourcin (1040) [
3],
Tempranillo (7762), and
Macabeu (3093 ± 266) [
6].
In the current study, HHP decreased or preserved the phenolic compounds in RGP immediately after the treatment, in contrast to previous results, which increased or maintained the extraction of PCC in the skins of
Dornfelder V. vinifera ssp. byproducts [
8,
9], the ‘Summer Black’ grape from
V. vinifera × V. lambrusca [
42] and freeze-dried grape pomace from
Tempranillo,
Petit Verdot, and
Merlot [
28]. Also, Corrales et al. (2008, 2009) [
8,
9] and Sheng et al. [
42] showed improvements in phenolic extraction from the grape skins throughout this treatment. This phenomenon is explained by changes in the structure of cellular matrices, especially in a matrix with dietary fiber content, leading the phenolic compounds extraction [
40]. PCC was unchanged or decreased in HHP-treated
Merlot,
Norton, and
Traminette skins from pomaces [
28], in accordance with our study.
The literature describes a close relationship between PPO activity and the stability of anthocyanins. Thus, the degradation of anthocyanins in processing berry products is the consequence of indirect oxidation of phenolic quinones by PPO and the peroxidase enzyme [
37]. This would explain the similar actions found between PPO activity and color fluctuations in the analyzed RGP. Changes in instrumental color during storage could be explained by the activity of PPO, forming brown and colorless pigments. In fact, instrumental color parameters showed significant (
p < 0.01) correlations (Pearson correlation coefficient) with PPO, which were negative for lightness and brownness (CIE L* r= −0.620; CIE b* r = −0.753) and positive for redness (CIE a* r = +0.327). Thus, the high activity of PPO produces reductions in brownness and lightness and increases in redness. Color modifications were more evident at room temperature than in refrigerated storage. However, the progress in the instrumental measurement of color was not as great as changes in PCC during storage. Probably, the important reduction in PCC was directly associated with the PPO activity in GP without blanching treatment, while the color changes are more related to the anthocyanin’s preservation, which is the secondary product of the reaction between the PPO and the phenolic compounds. This is an important concern for the valorization of pomace because these are the main bioactive portion of pomace, and they have antioxidant and antimicrobial activity, so their preservation is essential to maintain their biological activity [
14]. Therefore, these authors concluded that a correct process of stabilization includes a thermal blanching of fresh pomace, grinding, vacuum packaging, and HHP (600 MPa/5 min), giving value to the integral grape pomace, which is abundant in phenolic compounds that the food industry could use as an ingredient.
There are no shelf-life studies for fresh pomace treated with HHP. Studies have been carried out, however, on dried pomace (skins and seeds) such as that by Tseng and Zhao [
43] and Wang et al. [
44] for red grape byproducts (
Pinot and
Merlot) maintained for up to 16 weeks at 15 ± 2 °C for 9 months. All of them achieved a dry product with a stable PPC, but these parameters decreased after 4 months. For example, in the study by Tseng and Zhao [
43], the parameter values for
Pinot Noir pomace decreased: 56% for PPC, 58% for anthocyanins, 36% for antiradical scavenge activity (ARS), and 35% for total flavonol content. Hence, HHP could be applied to obtain a shelf-stable product that retains PCC and lasts at least 9 months to 1 year, since RGP is a stationary product.