Abstract

In the present study, common carp (Cyprinus carpio), a highly valuable worldwide commercial fish species, was used as a model. One sample group of fresh, skin-on carp fillets was placed in a bath of acidic electrolyzed oxidizing (AEO) water containing a solution of 100 mg/kg chloride ion concentration for 5 minutes. Another sample group was treated with acidic electrolyzed water and 0.5% lysozyme enzyme solution. Another set of samples were washed after the AEO water treatment. Within the study, a storage test was performed to examine the effect of the new combined treatment on the samples’ shelf-life and quality while kept at 2°C. During the storage period, chemical (chlorate) and microbiological (TVC, mesophilic anaerobic plate count, and Enterobacteriaceae count) tests and sensory evaluation were conducted. The combination of AEO water and lysozyme enzyme showed additional bactericidal efficacy on the surface of the carp fillets, which has never been reported before. Both the AEO water and the combined treatment effectively increased the shelf life of the samples, causing 2.4–3.1 log CFU/g difference compared to the control by the end of the 7-day storage. The measured residual chlorate content exceeded the legal threshold, but washing the samples resulted in values below the theoretical threshold limit. The applied preservation methods did not have an adverse effect on the organoleptic properties of the samples.

1. Introduction

Increasing the shelf life of a product, the safe manufacture of food products, and food safety are some of the biggest challenges of the food industry. An estimated 25% of food products become unfit for consumption due to microbial deterioration [1]. The short shelf life of fresh fish is caused by postmortem biochemical reactions and deterioration caused by microbes. Common carp (Cyprinus carpio) is the most important fish species of temperate-zone freshwater aquacultures [2, 3]. Due to the climate, water temperatures and the microflora of these waters the microorganisms count on the carps’ integument, gills and in their digestive system is higher compared to that of marine or cold water species [4]. There are traditional chemical and physical procedures for the preservation of fish; however, consumers have a legitimate demand to consume minimally processed foods, with the least change in nutritional value and organoleptic qualities [5].

Electrolyzed oxidizing (EO) water is a novel antimicrobial agent developed in Japan; but its industrial application is becoming increasingly widespread among food manufacturers [6]. It is relatively easy to produce. NaCl is dissolved in deionized water; then, the solution is electrolyzed in a closed cavity. As a result, acidic water (pH 2.3–2.7 and redox potential [ORP] > 1100 mV) is generated on the anode side of the membrane-separated space, in which chloride ion (Cl), hypochlorous acid (HOCl), and diluted hydrochloric acid are concentrated [7]. On the other side of the membrane-separated space, alkaline water (pH 10–11.5 and ORP < 800 mV) is generated, in which sodium ion (Na+) and sodium hydroxide (NaOH) are concentrated [8]. Acidic electrolyzed water (AEO) is an effective antimicrobial agent, but it can also be used to remove other kinds of contaminants [9]. The disinfection properties of AEW are mainly ensured by the high concentration of HOCl forming chlorine (°Cl) and hydroxyl (°OH) radicals [1012]. Due to its high oxidative reduction potential, EO water acts as an oxidative agent disrupting cellular functions, including DNA synthesis, permeable membrane structure, metabolic enzymes, and electron transport systems [13].

EO water has the following advantages. It is an effective disinfectant, easy to operate with, and relatively cheap, and due to the fast termination of the ionic state, it is also environmentally friendly. However, the main advantage of EO water is its safety [6]. Although EO water generated on the anode side of the membrane is a strong acid, it differs from hydrochloric acid or sulphuric acid as it is not corrosive on the skin, the mucous membrane, or other organic materials. According to previous research studies, the effect of EO water was significantly limited by the mucin-type glycoprotein layer covering the body of fish [14, 15]; therefore, it is suggested to develop a combined preservation method in which the synergistic advantages of different treatments are reflected, but the organoleptic properties of fish are not changed. The application of EO water combined with lysozyme as another antimicrobial agent is an approach that has never been tested before.

Lysozyme is a 14.6 kDa protein produced by mammals, which has long been known as an antimicrobial agent. As an enzyme, it is mainly effective against Gram-positive bacteria and less so against Gram-negative ones by breaking down the β (1–4) glycosidic linkages of murein [16]. In the food industry, it is used to extend the shelf life of cheese, sea foods, fruits, and vegetables [17], but it is usually combined with other bactericidal agents. In [18], the authors studied the synergistic effect of lysozyme and chitooligosaccharide on raw pork and raw minced pork. This combined treatment resulted in the total elimination of Escherichia coli, Pseudomonas fluorescens, and Bacillus cereus and the reduction of Staphylococcus aureus in meat. In [19], the authors used lysozyme combined with nisin to decrease the number of meat spoilage bacteria (Brochothrix thermosphacta B2 and Carnobacterium sp. 845). The researchers found that the combination would have a better antimicrobial effect on the treated fat and lean tissue than their separate use. The main limitation for the general use of lysozyme is that although it is efficient against Gram-positive bacteria, it is much less so against Gram-negative ones; therefore, it is beneficial to use it in combination with other substances [20]. Research indicates that the effect of lysozyme could be extended to Gram-negative bacteria and the lysozyme’s functional properties could be improved by a lysozyme-galactomannan conjugation [21]. Lysozyme’s enzyme activity can also be enhanced by certain substances, including EDTA and butylparaben, and by some natural antimicrobial agents [22, 23]. However, these chemicals are not suitable for food industry applications.

Research on the antimicrobial effect of EO water has not yet discussed the residual chlorate and chlorate derivatives on the treated foods. Due to the consumption of chlorate and perchlorate in food, the concentration of hemoglobin and hematocrit and the decrease of red blood cell count were detected; furthermore, thyroid dysfunction was observed [24, 25]. Since no specific maximum residue limit (MRL) was fixed under Reg. (EC) No. 396/2005, the default MRL of 0.01 mg/kg is applicable for chlorate to all food products included in Annex I to that regulation [26]. However, according to the scientific opinion of EFSA about the risks for public health related to the presence of chlorate in food, a theoretical 0.7 MRL would not change the potential risks related to chlorate [27].

This study aims to investigate the impact of the combination of AEO water and lysozyme on the shelf life of carp fillets to determine whether the combined treatment has an additional effect compared to using AEO alone, as well as evaluating whether the washing of the samples after the AEO water treatment can sufficiently reduce the chlorate and perchlorate levels along with the assessment of the capability of the application lysozyme enzyme to compensate loss of effectiveness resulting from the washing step.

2. Materials and Methods

2.1. Sample Preparation

In this study, scaly common carps (Cyprinus carpio) of average body weight of 2.5 kg were purchased from a local aquaculture, Öko 2000 Ltd. in Akasztó, Hungary. Carps were transported to the fish slaughtering and processing facility and kept alive for 48 hours in a 15°C pool with continuous air-spraying and daily 20% water change until the time of sample preparation. Overall, 38 carps were used for the experiments. The fish were stunned with electricity (300 mA, 50 V, and 50 Hz) for 30 seconds, slaughtered, bled, scaled, and gutted.

The carcasses were filleted then sliced into 100 g pieces of 6 × 14 × 2 cm on average and separated into six groups. For the control group, untreated slices were vacuum packaged in 180 × 230 mm, 90 µm thick PP foils. The second group was washed with tap water. The third group was treated by acidic (pH 2.5) electrolyzed active water with 100 mg/kg chlorine ion concentration. The active water was produced with a REDO Pure 250 active water generator.

The fish fillets were put into 25 liters of active water for five minutes and were stirred every minute (AEO). The fourth group was treated by acidic electrolyzed active water and then washed with tap water (AEO Washed). The fifth group was placed in acidic electrolyzed water and then their surface was sprayed with a 0.5% lysozyme enzyme solution (AEO + L). The sixth group was placed in acidic electrolyzed water and washed with tap water, followed by treatment with lysozyme enzyme solution (AEO Washed + L). The samples were drained and vacuum packaged in 180 × 230 mm, 90 µm thick PP foils and then stored at 2°C among ice flakes. Five samples per group were prepared for microbiological analysis, and twenty-five samples per treatment for sensory evaluation.

Microbiological analysis was conducted on days 0, 1, 2, 4, and 7. Residual chlorate and perchlorate tests were performed on days 0 and 4, and sensory evaluation was performed on day 0.

2.2. Microbiological Analyses

Microbiological tests were carried out on 0, 1, and 4 day of storage. Total viable count (TVC) was determined according to the ISO 4833–1:2013 by pour-plating with PC agar and incubating the plates at 30 ± 1°C for 72 ± 3 h. Enterobacteriaceae count was determined according to the ISO 21528–2:2017 standard, by pour-plating with VRBG agar, incubating the plates at 37 ± 1°C for 24 ± 2 h, and carrying out glucose fermentation and oxidase presence tests as confirmation. Mesophilic anaerobic plate count was determined by pour-plating with RCM media and incubating in CO2 atmosphere in the BACT-R Plus anaerobic system (Sobioda, France) at 30 ± 1°C for 72 ± 3 h. The results were expressed in log10 CFU/g.

2.3. Residual Chlorate and Perchlorate Content

The washed control samples and samples treated with acid water were examined for residual chlorate and perchlorate content on days 0 and 4 of storage. To determine the chlorate and perchlorate content 5 ± 0.05 g, homogenized samples were put into 50 ml centrifuge tubes, and isotope-labeled chlorate internal standards (ISTD) were added to it. Five millilitres of water with 1% acetic acid and 20 ml acetonitrile were added to the samples. Then, the samples were vigorously shaken by hand for 1 minute and put into an ultrasound bath for 5 minutes afterwards. Following the ultrasound bath, the samples were centrifuged at 4500 rpm for 10 minutes. One mL of the extract was put into a disposable autosampler vial and stored at 0–5°C until measurement. The chlorine content of the samples was assayed in triplicate by the LC-MS/MS method [28]. The results were expressed in mg/kg.

2.4. Sensory Evaluation

The purpose of the organoleptic examination was to determine whether the treatments caused an immediate change in the sensory properties of the fish meat. Twenty-five panelists (aged 25–50 years) familiar with sensory evaluation procedures were recruited. The sensory evaluation was conducted based on general appearance, color, odor, texture, and flavor using a 5-point hedonic scale: 1, dislike extremely to 5, like extremely. For sensory evaluation of general appearance, color, odor, and texture, fish samples of each treatment were removed from cold storage and equilibrated at room temperature (25°C) for 1 h before evaluation. For the evaluation of flavor, the fillets were put on an oiled baking pan and then fried for 10 minutes at 180°C in a Lainox VE 051P Combi Oven-Direct Steam equipment. Afterwards, the fillets were left in the oven for an additional 3 minutes until the sensory evaluation test started. The outcome of the microbiological storage test for the sample series was unknown, so for food safety reasons, the study was performed only on day 0.

2.5. Statistical Analysis

The statistical analysis of the results was performed with SPSS Statistics 22.0 (IBM Corp., Armonk, NY). Data were expressed as mean ± SD. Bacterial numbers in CFU/g were transformed into log10 for statistical analysis. The data of microbiological analysis, sensory evaluation, and chlorate and perchlorate content were expressed as mean ± SD. Significant differences in bacterial populations and sensory scores were evaluated at by analysis of variance (ANOVA) and Duncan’s multiple range test.

3. Results and Discussion

3.1. Microbial Analyses

The effects of AEO water (pH = 2.5, free available chlorine content of 100 mg/l) and its combined treatment with 0.5% lysozyme enzyme solution on TVC, Enterobacteriaceae count, and anaerobic mesophilic count were examined on days 0, 1, 2, 4, and 7 of storage. As shown in Table 1, the control samples TVC clearly reflects the shortness of the fish fillet’s shelf life in a normal vacuum package, reaching the 107 CFU/g value on day 2. N = 107 CFU/g is the value after which signs of deterioration start to appear [29], so it can be considered as the threshold of microbial spoilage.

In case of the unwashed samples, both AEO water and the combined treatment resulted immediately in a significant () reduction (2.0–2.5 logs) of the TVC compared to the control sample. This reduction was maintained during the storage. These results are in agreement with the data obtained following AEO water treatment of American shad [30] and common carp [4] samples reporting 1.5–2.0 log CFU/g reduction in TVC during the storage. Only a minor additional reducing effect was observed at the combined treatment until day 7 of storage. Although the optimum activity of lysozyme enzyme was reported to be at a pH of 5.3–6.4 [31], it has been demonstrated to be active over a wider pH range of 4–10 [32].

The immediate effect of lysozyme caused about 0.5 log CFU/g difference between the plate counts treated with electrolyzed oxidizing water and the ones with the combined treatment. This difference further increased during the seven days of storage. Washing the samples after the AEO water treatment did not result in the increase of the effectiveness of lysozyme enzyme. This allows the conclusion that the acidic conditions of the AEO water did not influence the potency of the lysozyme enzyme.

Washing the samples after the AEO water treatment showed to retain its effectiveness as significant differences were measured compared to the nonwashed samples. However, the EOW treatment followed by washing also successfully increased the shelf life of the carp samples, maintaining 1.4–2.2 log CFU/g difference compared to the control group. The contrast between the washed and unwashed samples shows the substantial role of the residual chlorine on the surface after the treatment, which was partially removed by washing. In [33], the authors reported the chlorate loss over time as one of the major limiting factor of AEO water mainly caused by the evaporation of dissolved chlorine gas. However, in closed vacuum packaged conditions, the chlorate loss is significantly reduced, increasing its bactericidal activity. Overall, all treatments have significantly improved the shelf life of the samples compared to the control group, the most effective treatment resulting in more than 5-day increase in shelf life.

The same trends were observed at the results of mesophilic anaerobic plate count (Table 2). Application of AEO water caused decrease in the total plate count by more than 1 order of magnitude during the storage. It is consistent with the results of previous studies performed on tilapia [34] and Atlantic salmon [35] inoculated with E. coli and L. monocytogenes, where a reduced number of bacteria were recorded due to the effect of active water on the surface of fish flesh and skin. Compared to the TVC, mesophilic anaerobic bacteria reached considerably lower plate counts. It is assumed that storage conditions influenced the differences in TVC and anaerobic mesophilic plate count changes. Since the samples were stored at 0–2°C, this favored the psychrotrophic microbes. Presumably, the proportion of anaerobic microbes in the samples was less cold-loving, so their growth during storage was slower compared to the TVC.

As shown in Table 3, AEO water immediately resulted in a 1.78 log CFU/g reduction in the Enterobacteriaceae count.

Although lysozyme enzyme was reported to have lower effectiveness against Gram-negative microorganisms [17], the application of lysozyme enzyme in the combined treatment showed additional bactericidal effect compared to the AEO water treatment. Furthermore, the application of lysozyme enzyme has sufficiently compensated the loss of effectiveness, originating from the washing step after AEO water treatment as, in general, no significant difference was observed between the AEO and AEO washed + L groups.

3.2. Residual Chlorate and Perchlorate Content

As the chlorate and perchlorate concentration of the samples after AEO water treatment was reported to be negligible in vacuum packaged conditions, it was measured immediately after the treatment [33]. As Table 4 shows, the residual chlorate and perchlorate contents of samples treated with AEO water were high, exceeding the permitted limit of chlorate of 0.01 mg/kg and also the MRL of 0.7 mg/kg suggested by EFSA [27].

However, the residual chlorate content of samples washed after the AEO water treatment was below the theoretical threshold limit value. According to the laboratory tests ordered by the European vegetable processors, it becomes clear that chlorate is already present in the drinking water; therefore, companies that do not use any chlorinated products in their process have also found chlorate residues close to or even exceeding the MRLs [36]. The difficulty of the compliance with the current legalization is represented on the chlorate concentrations measured on the control samples, exceeding the threshold limit after tap water washing.

3.3. Sensory Evaluation

The results of the sensory evaluation of the fish samples are presented in Table 5. There were no significant differences between all kinds of carp samples (), which indicated that applied treatment methods did not have a negative impact on the sensory quality of the carp samples. These results are in agreement with the data obtained following AEO water treatment of Pufferfish [37] and frozen shrimp samples [38], where the AEO water treatment did not have an adverse effect on the organoleptic properties.

4. Conclusion

The combination of AEO water and lysozyme enzyme showed additional bactericidal efficacy on the surface of the carp fillets, what has never been reported before. Compared to the AEO water treatment, the combined treatment caused further reduction in the number of spoiling microorganisms and effectively extended the shelf life of ultrafresh products by more than 5 days compared to the control group; thus its industrial application would have significant economic benefits. No combination of treatment showed to influence the organoleptic properties of the samples. The application of acidic water on its own or combined with other substances may prolong the shelf life of carp fillets from microbiological point of view, but the amount of residual chlorate exceeds the permitted limit value stored in closed vacuum packaged conditions. Although washing the samples after the acidic electrolyzed oxidizing water treatment resulted in lower effectiveness, the residual chlorate content of samples was below the theoretical threshold limit value. Furthermore, the application of lysozyme enzyme successfully compensated the loss of effectiveness caused by the washing step. Nevertheless, it is advisable to conduct further studies in order to optimize the method of acidic active water application with particular regard to its effect on extended shelf life and the quantity of residual chlorate exceeding the threshold limit.

Data Availability

The datasets used to support the findings of this study are included within the article.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Acknowledgments

This study was supported by the NVKP_16-1-2016-0023 project funded by the National Research, Development and Innovation Fund.