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Article

Monitoring of the Surfactants in Surface Waters in Slovakia and the Possible Impact of COVID-19 Pandemic on Their Presence

by
Martina Lobotková
1,
Helena Hybská
1,*,
Eszter Turčániová
1,
Jozef Salva
1,*,
Marián Schwarz
1 and
Tatiana Hýrošová
2
1
Department of Environmental Engineering, Faculty of Ecology and Environmental Sciences, Technical University in Zvolen, T. G. Masaryka 24, 960 01 Zvolen, Slovakia
2
Department of Mathematics and Descriptive Geometry, Faculty of Wood Sciences and Technology, Technical University in Zvolen, T. G. Masaryka 24, 960 01 Zvolen, Slovakia
*
Authors to whom correspondence should be addressed.
Sustainability 2023, 15(8), 6867; https://doi.org/10.3390/su15086867
Submission received: 29 January 2023 / Revised: 31 March 2023 / Accepted: 18 April 2023 / Published: 19 April 2023
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Abstract

:
In order to keep the home and occupational environment clean and non-infectious, the consumption of cleaners and disinfectants, including cosmetics, is increasing. Excessive use of these products results in their accumulation in the aquatic environment. Conventional wastewater treatment plants are unable to effectively remove the emergent pollutants, including personal care products. This article is focused on the monitoring of the presence of personal care products in surface waters in two river basins in the Slovak Republic, in terms of the surfactant content. Ecotoxicological evaluation of the selected samples from the monitored river basins was performed by an acute toxicity test using the test organism Daphnia magna. The monitoring results indicate the presence of personal care products in the aquatic environment which poses an ecological and environmental risk. Monitoring in the Hron and Nitra river basins confirmed contamination with the surfactants, to which the measures related to the COVID-19 pandemic contributed. The content of the surfactants in personal care products is significant, and their impact on the aquatic environment is not sufficiently monitored.

1. Introduction

The impact of the wastewater discharged into recipients represents a serious global problem for the aquatic environment. The wastewater is a high-risk mixture of pollutants, which may endanger human health. In most cases, wastewater treatment plants only partially reduce the content of the specific pollutants, which mainly include new, unexplored, anthropogenic contaminants [1]. These are emerging pollutants whose properties are unknown in comparison with known conventional substances. They have a potential and confirmed impact on human health and the environment [2,3]. These are mainly substances that reach the recipients for a long time, but their importance and impact on the quality of the aquatic environment have not been investigated. Emergent pollutants can include persistent organic pollutants, pesticides and other biocidal preparations, flame retardants, e.g., based on polybrominated compounds, preservatives and other products used not only in the food industry, pharmaceutical products and personal care products, etc. [4,5]. Emergent pollutants have attracted worldwide attention due to their highly toxic effect, very low degradation, long-term exposure and extensive distribution in the environment [6]. Currently, the detection of their presence poses new challenges in the field of pollution control in all components of the environment. In order to improve the level and increase the quality of environmental analysis, they are beginning to be determined in waste, surface and drinking water in the whole world [2,7].
A special group of emergent pollutants consists of pharmaceuticals and personal care products (PPCPs). These include, e.g., medications, nutritional supplements, cleaners and disinfectants, cosmetics and other products that companies normally use to remove dust particles, impurities and organic substances (such as blood, secretions, etc.). They ensure the cleanliness and reduce the infectivity of the home and work environment [1,8,9,10,11,12]. Their presence in water can cause a change in sensory, physical and chemical properties and affect biological processes in water [13]. Emergent pollutants are usually hardly biodegradable compounds, which limit the passage of airborne O2 into the water and negatively affect the biocenosis of the environment [14,15]. Their presence can cause increased solubility of organic substances in water, which would not normally dissolve [16,17,18].
According to Zhang et al. [19], the increased consumption and intensity of the use of PPCPs (cleaners, disinfectants and cosmetics) was caused by the global pandemic caused by the COVID-19 virus. Consumption of contact surface cleaning products (door and window handles, floors, food preparation and serving areas, worktops, public toilets, touch screens, keyboards and other work equipment) and personal care products (soaps, creams, shampoos and others) has increased significantly. Previous studies pointed out their release into the environment, in which serious biological damage occurs, such as persistence in the form of bioaccumulation in the environment, thus damaging the fauna and flora [20,21,22].
Each cleaner and disinfectant has a specific composition and characteristics, which are indicated on the label or in the Material Safety Data Sheet (MSDS), which is freely available to consumers. Based on the compositions, which are listed in the MSDS of the individual products, these components can be classified into the following groups: surfactants, alcohols, acids and bases, sodium salts, peroxides and hydrogen peroxides, oxides and additives. Surfactants have the highest percentage of representation.
Surfactants are pollutants whose primary function is to reduce surface tension at the phase interface, which will facilitate the wetting and dispersion of impurities in the liquid that do not mix with it. The main advantages of surfactants are washing, wetting, emulsifying, dispersing, stabilizing and foaming effects [23]. Of the total amount of the existing surfactants, up to 55% are commonly used in households; in the cosmetics and pharmaceutical industries, it is about 10%. Surfactants are also used in the agriculture, textile, food and paper industries, etc. Wastewater concentrates all cleaning, disinfecting and cosmetic products, which cause problems at the wastewater treatment plant (WWTP) [11,19,24].
In Slovakia, the wastewater treatment process is standardly aimed at achieving the quality of the discharged treated water in terms of selected physico-chemical indicators resulting from Slovak legislation (Regulation of the Government of the Slovak Republic No. 269/2010 Coll., which sets requirements for achieving good water status—BOD5, CODCr, insoluble matter, nitrogen and phosphorus). The content of PPCPs in the aquatic environment is not one of the monitored indicators. Their presence poses an ecological and environmental risk to the aquatic environment [25]. PPCPs can affect enzymatic, metabolic and other mechanisms in aquatic animals and plants, leading to negative effects on their physiological functions, endocrine system, metabolism and reproduction. Their action can cause chronic toxicity (mutagenicity, carcinogenicity) [22]. Surfactants are difficult to degrade; they cannot be effectively removed. PPCPs have the highest content of surfactants in their composition.
The presence of PPCPs can also be determined by the content of surfactants in the water environment. The maximum permissible concentrations of anionic surfactants in water are as follows: surface water = 1.0 mg/L and water intended for irrigation = 2.0 mg/L [26].
This article deals with the monitoring of the surfactant content as an indicator of the presence of PPCPs in surface water before (2019) and during the COVID-19 pandemic (2020) in Slovakia in two river basins. The ecotoxicity of the monitored waters was assessed using a bioassay with Daphnia magna. The essence of the study is to point out the fact that the COVID-19 pandemic has caused an increase in surfactants in the water environment, which poses a risk to the environment.

2. Materials and Methods

2.1. Field Mapping and Study Area

For sampling, monitoring sites were chosen within two river basins in Slovakia—the river basin Hron and the river basin Nitra. Samples from surface streams were not only taken directly from these two rivers (Hron and Nitra) but also from smaller streams that flow into them and thus contribute to their characteristic properties.
Globally, it is a locality of central Slovakia (Trenčín, Nitra and Banská Bystrica Self-Governing Region). From the point of view of the global climate classification, the territory of Slovakia belongs to the northern temperate climate zone with a regular alternation of four seasons and changeable weather with a relatively even distribution of precipitation throughout the year.
Water abstraction from surface water was carried out on days that were meteorologically constant (no precipitation activity was recorded; temperatures were without fluctuations). The collection was carried out in the period of spring 2019 and 2020, between March and April, and it was carried out at two points. The results presented in the tables and figures are represented as averages of these measurements. Selected monitoring sites are recorded in Figure 1A,B—Nitra river basin and Hron river basin, respectively.

2.2. Determination of Anionic Surfactant Content

Cationic surfactants make up only an insignificant share of total surfactants. For that reason, we focused on the content of anionic surfactants. The determination of anionic surfactant content is based on the reaction of a water sample with methylene blue. Anionic surfactants in alkaline media form colored ionic associates with methylene blue, which are extracted with chloroform. The absorbance of the samples at 650 nm was evaluated. The WTW CINTRA 20 spectrophotometer was used [27].
In Slovakia, the method STN EN 903: 1999 is standardized. In this method, chloroform is given as the solvent. For that reason, chloroform was also used in this study. Its use was in accordance with all safety measures, including its disposal after use.
To calculate the concentration of surfactants in samples, more calibration curves were used. We present one of them as an example. The calibration curve for the calculation of surfactant content was prepared at regular intervals. The calibration curve was prepared for the standard: sodium n-dodecane sulfonate (C12H25NaO3S) (Figure 2). The detection limit resulting from the standard STN EN 903:1999 is 0.05 mg/L.

2.3. Ecotoxicological Tests

Acute toxicity test on Daphnia magna: principle of the test is an assessment of percentage of immobilized individuals after 48 h from the beginning of exposure of a tested sample to test organisms of Daphnia magna [28,29]. Conditions of the preliminary test, including control of meeting test conditions with a reference substance, are shown in Table 1.
Daphnia magna was used as the test organism. Its age must be less than 24 h. During the test, the following must be ensured: suitable temperature and suitable pH of the aquatic environment. The control sample is prepared from the solutions listed in Table 1. The test lasts 48 h. At the end of the test, the percentage of immobilized organisms is evaluated. The control of the accuracy of the work is evaluated on the basis of a reference substance, the result of which is shown in Table 1, line “reference substance”. This condition has been met.
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Figure 1. (A) Monitoring sites—river basin Hron (QGIS Desktop 3.12.2). (B) Monitoring sites—river basin Nitra (QGIS Desktop 3.12.2) [30]. Explanations: Sites of river basin Hron: 1—Pohorelá; 2—Polomka; 3—Brezno; 4—Valaská; 5—Podbrezová; 6—Lopej; 7—Predajná; 8—Nemecká; 9—Brusno; 10—Slovenská Lupča; 11—Šalková; 12—Poníky; 13—Čerín; 14—Dolná Mičiná; 15—Harmanec; 16—Banská Bystrica; 17—Tajov; 18—Králiky; 19—Kordíky; 20—Malachov; 21—Badín; 22—Kremnička; 23—Vlkanová; 24—Hronsek; 25—Sliač; 26—Kováčová; 27—Zvolen; 28—Vígľaš; 29—Budča; 30—Banská Štiavnica; 31—Kozelník; 32—Hronská Dúbrava; 33—Ladomerská Vieska; 34—Sklené Teplice; 35—Hliník nad Hronom; 36—Dolná Ždaňa; 37—Vyhne; 38—Bzenica; 39—Žarnovica; 40—Hodruša-Hámre; 41—Voznica; 42—Rudno nad Hronom; 43—Nová Baňa; 44—Tekovská Breznica; 45—Hronský Beňadik. Sites river basin Nitra: 1—Kľačno-Horný koniec; 2—Kľačno-Dolný koniec; 3—Nitrianske Pravno; 4—Poluvsie; 5—Nedožery-Brezany; 6—Kanianka; 7—Bojnice; 8—Prievidza; 9—Handlová; 10—Ráztočno; 11—Jalovec; 12—Chrenovec-Brusno; 13—Veľká Čausa; 14—Opatovce nad Nitrou; 15—Nováky; 16—Nitrianske Rudno; 17—Diviacka Nová Ves; 18—Nitrica; 19—Chalmová; 20—Skačany; 21—Veľké Uherce; 22—Partizánske; 23—Bošany; 24—Uhrovec; 25—Biskupice; 26—Horné Naštice; 27—Rybany; 28—Krušovce; 29—Prázdnovce; 30—Topoľčany; 31—Solčany; 32—Nitrianska Streda; 33—Chrabrany; 34—Čeladince; 35—Oponice; 36—Hrušovany; 37—Koniarovce; 38—Jelšovce; 39—Čakajovce-Zbehy; 40—Lužianky 1; 41—Lužianky 2; 42—Nitra; 43—Čechynce; 44—Veľký Cetín; 45—Vinodol.
Figure 1. (A) Monitoring sites—river basin Hron (QGIS Desktop 3.12.2). (B) Monitoring sites—river basin Nitra (QGIS Desktop 3.12.2) [30]. Explanations: Sites of river basin Hron: 1—Pohorelá; 2—Polomka; 3—Brezno; 4—Valaská; 5—Podbrezová; 6—Lopej; 7—Predajná; 8—Nemecká; 9—Brusno; 10—Slovenská Lupča; 11—Šalková; 12—Poníky; 13—Čerín; 14—Dolná Mičiná; 15—Harmanec; 16—Banská Bystrica; 17—Tajov; 18—Králiky; 19—Kordíky; 20—Malachov; 21—Badín; 22—Kremnička; 23—Vlkanová; 24—Hronsek; 25—Sliač; 26—Kováčová; 27—Zvolen; 28—Vígľaš; 29—Budča; 30—Banská Štiavnica; 31—Kozelník; 32—Hronská Dúbrava; 33—Ladomerská Vieska; 34—Sklené Teplice; 35—Hliník nad Hronom; 36—Dolná Ždaňa; 37—Vyhne; 38—Bzenica; 39—Žarnovica; 40—Hodruša-Hámre; 41—Voznica; 42—Rudno nad Hronom; 43—Nová Baňa; 44—Tekovská Breznica; 45—Hronský Beňadik. Sites river basin Nitra: 1—Kľačno-Horný koniec; 2—Kľačno-Dolný koniec; 3—Nitrianske Pravno; 4—Poluvsie; 5—Nedožery-Brezany; 6—Kanianka; 7—Bojnice; 8—Prievidza; 9—Handlová; 10—Ráztočno; 11—Jalovec; 12—Chrenovec-Brusno; 13—Veľká Čausa; 14—Opatovce nad Nitrou; 15—Nováky; 16—Nitrianske Rudno; 17—Diviacka Nová Ves; 18—Nitrica; 19—Chalmová; 20—Skačany; 21—Veľké Uherce; 22—Partizánske; 23—Bošany; 24—Uhrovec; 25—Biskupice; 26—Horné Naštice; 27—Rybany; 28—Krušovce; 29—Prázdnovce; 30—Topoľčany; 31—Solčany; 32—Nitrianska Streda; 33—Chrabrany; 34—Čeladince; 35—Oponice; 36—Hrušovany; 37—Koniarovce; 38—Jelšovce; 39—Čakajovce-Zbehy; 40—Lužianky 1; 41—Lužianky 2; 42—Nitra; 43—Čechynce; 44—Veľký Cetín; 45—Vinodol.
Sustainability 15 06867 g001aSustainability 15 06867 g001b
Sustainability 15 06867 g002 550
Figure 2. Calibration curve for determining the content of surfactants.
Figure 2. Calibration curve for determining the content of surfactants.
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Table
Table 1. The test conditions for Daphnia magna [28,29,31].
Table 1. The test conditions for Daphnia magna [28,29,31].
Test OrganismDaphnia magna Straus, individuals younger than 24 h since birth (no feeding)
Biotest Conditions21 ± 2 °C; 7.80 ± 0.20; laboratory conditions
Test Samplefreshly collected surface water, without additions and modifications
Control Samplediluting water prepared from the solutions of CaCl2·2H2O (1), p.a., MgSO4·7H2O (2), p.a., NaHCO3 (3), p.a., KCl (4), p.a.; by the addition of solutions (1)–(4) per 10 mL and adding demineralized water to a volume of 1 L
Reference SubstanceK2Cr2O7, EC50 = 0.82 mg/L (confidence interval 0.3–1.5 mg/L)
Test Duration48 h
Preliminary Test20 daphnia/undiluted sample (10 mL), same conditions for control
Validity of the Testimmobilization ≤ 10%, change in concentration of dissolved oxygen O2 ≤ 2.0 mg/L
Monitored Response% of immobilized individuals

3. Results and Discussion

The determined contents of surfactants in the surface water samples from the monitoring sites were evaluated according to the Regulation of the Government of the Slovak Republic No. 269/2010 Coll. The limit value for surface water is 1 mg/L of the surfactants. Microsoft Office Excel and MATLAB® (R-2021) were used for processing and evaluating the results.

3.1. River Basin Nitra

The determined surfactant concentration values are shown in Figure 3 and Table 2. The graph shows that the concentration of the surfactants was exceeded in several places even in the period before the COVID-19 pandemic. It is interesting that the Nitra river has increased concentrations of the surfactants in samples from Kľačno (1), above which it springs.
We state that the increased concentration of the surfactants in this area indicates an increased presence of the septic tanks (the households without a connection to the public sewerage). The concentration of the surfactants is also above the limit at other sampling points (2–4). The reason may be the remnants of industrial activity (mining) in Horná Nitra, which is mentioned as a possible source of environmental contamination in the State of the Environment Report (2022). In the State of the Environment Report, it is stated that the Nitra river has long been considered a polluted river, which is mainly affected by mining activities in the town of Prievidza (brown coal mining). In addition to mining activities, the food and chemical industries (plastic production) are characteristic. There is a thermal power plant with the associated production of building materials too [32].
The increased concentration of the surfactants is also due to the fact that they are larger cities, with an extended infrastructure and population, but not all households are drained into the sewerage. Excessive surfactant concentrations are also recorded in the area around the city of Nitra (37–40), again, especially in municipalities that do not have a sufficiently built sewerage network.
During the COVID-19 pandemic (spring 2020), the number of monitoring sites with above-limit surfactant concentrations increased by 20%. The highest concentrations of the surfactants were in the range of 1.0–5.3 mg/L (the limit value for surfactants in surface waters is 1 mg/L; the highest value was at sampling point no. 40). The Nitra river showed an above-limit concentration of the surfactants from monitored site (33) to the end of the monitoring section (45), which represents 13 consecutive monitoring points on the approximate length of the Nitra river 55.2 km (river km 94.3–river km 39.1).

3.2. River Basin Hron

The surfactant concentrations determined in the samples from the monitored sites in the Hron river basin are shown in Figure 4 and Table 3.
From the period before the COVID-19 pandemic (spring 2019), the samples at the monitoring sites (1–6) were negative, which is also in line with the information provided in the State of the Environment Report [32], where it is stated that Hron has very pure water in this part. The assessment of water quality in the Report on the State of the Environment is based on the mandatory monitored parameters from the applicable legislation (Regulation of the Government of the Slovak Republic No. 269/2010 Coll., which sets requirements for achieving good water status). The character changes in the cities of Brezno and Podbrezová, where the engineering, metallurgical and petrochemical industries are concentrated. The lower part of the monitoring section concentrates the pharmaceutical industry (Slovenská Ľupča), wood processing and paper production, the food industry (Banská Bystrica and Zvolen) and aluminum production (Žiar nad Hronom) [32]. Information from the Report is consistent with our results: the composition of the water varies in the localities of the cities (7–10), where the quality of the flow is affected by the presence of industrial activities. Elevated surfactant concentrations occur in samples from larger sites along the river, such as, e.g., monitoring sites (16, 27, 30 and 33). We expect that it is not only the industrial activities and population that have an impact but also the several smaller inflows from areas where the sewerage system is not sufficiently built.
The second monitoring period (spring 2020) shows an increase in the number of the monitored samples with above-limit surfactant concentrations, from 22 to 33 monitoring sites with an increased surfactant concentration, which represents an increase of 22.22% (from 48.88% before the pandemic to 73.33% during the COVID-19 pandemic).
In the section from the monitored site (3) to site (45) (river km 225.10–river km 82.10 of the Hron river), the permitted concentration of the surfactants was exceeded in each monitored site. Streams as tributaries to the Hron river basin in this part (monitored sites 10, 14, 20, 24, 33, 38 and 40) in terms of the surfactant content did not exceed the permitted limit. The highest surfactant concentrations in this period were at the monitored sites (16), where the permitted surfactant concentration was exceeded by 4.3 mg/L, (7), where it was exceeded by 4.0 mg/L, and (29 and 34), where it was exceeded by 3.8 mg/L.
From the quality monitoring of the surface waters, in terms of the surfactant concentration, follows that before the COVID-19 pandemic in the Nitra river basin, 55.55% of the samples exceeded the maximum limit value resulting from the Regulation of the Government of the Slovak Republic no. 269/2010 Coll (<1.0 mg/L). During the pandemic, the number of positive samples in the Nitra river basin increased by 20% in terms of the surfactant content. The number of positive samples from monitoring sites in the Hron river basin increased from 48.88% to 73.33%. Contaminated waters pose a potential ecological and environmental risk.
We state that the increase in the surfactant concentration is related to the overuse and consumption of PPCPs due to more intensive disinfection and cleaning of public spaces, the working environment and households in order to prevent the spread of the infectious disease. The pollution caused by the presence of PPCPs has also been addressed in several studies, which confirm that the use and release of PPCPs into the environment currently have an intensive impact on the quality of the biotic environment, on which these products have a negative impact and pose an ecological and environmental risk [20,21,33,34,35].
In order to indicate the effect of the water in the monitored surface waters on aquatic organisms, a preliminary ecotoxicological test was performed using aquatic crustaceans Daphnia magna.
Available literature [36,37,38,39], and many studies within the world [40,41,42,43,44], states that test organisms that are trophic-level consumers, namely test organisms Daphnia magna, are the most sensitive to the presence of a toxicant in the sample. With the ecotoxicity test, we wanted to point out the dependence of the immobilization of the test organism on the concentration of surfactants in the selected samples. The results of the performed preliminary test are shown in Table 4.
The results of the preliminary tests of the selected samples from both river basins confirmed that the presence of the surfactants causes immobilization of the test organism Daphnia magna from a concentration of 0.7 mg/L. However, the permitted limit for the presence of surfactants in surface waters is 1 mg/L. The results of the preliminary test provide a quick overview of the ecotoxicity of the water and also of the need for further testing of the surface waters in terms of their quality.
The use of a bioassay is a good indicator of pollution, and its use is becoming more frequent. The test organisms Daphnia magna have also been confirmed in other studies to be sufficiently sensitive to the presence of substances in water. We chose the Daphnia magna test organisms on the basis of knowledge and experience from other authors [31,45,46,47,48]. The proof is their use in quality biomonitoring, for example, drinking water [49]. In the rivers where biomonitoring was carried out (with Daphnia magna) and the content of surfactants was monitored, no extraordinary event related to pollution was recorded, and therefore we predict that this pollution is caused by the increased use of surfactants based on recommendations in the fight against the spread of COVID-19. The presence of chemical substances, including surfactants, affected the quality of both sewage and surface water. The measures taken due to the pandemic have limited the conduct of research in many studies. For this reason, there are few such relevant studies with which the results could be compared [50].
According to Slovak legislation, surfactants are not among the basic indicators of surface water quality. The monitoring of the presence of surfactants is usually carried out at the time of an emergency, in order to determine the extent of the contamination of the river. In other cases, the determination of the surfactant content is for information only and is performed one to two times a year in the minimum range of the monitoring points on river basin sections. The exceeded limit concentrations of the surfactants in surface waters, which are also confirmed by the positivity of the results of the immobilization tests of Daphnia magna, indicate the need to include the surfactant indicator among the more frequently monitored surface water quality indicators.

4. Conclusions

The monitoring, in terms of the surfactant content, shows that the monitoring points in the Hron river basin in 2019 did not meet the criterion resulting from the Regulation of the Government of the Slovak Republic no. 269/2010 Coll. up to 48.88%, and in 2020 (during the COVID-19 pandemic), there was an increase of 24.45%. The number of unsatisfactory water samples in water samples from the Nitra river basin increased from 55.55% (2019) to 75.55% (2020) in terms of the surfactant content. Selected surface water samples tested by the acute toxicity test with the test organism Daphnia magna indicate that the increased consumption of PPCPs during the COVID-19 pandemic caused up to 92.86% of the positive samples tested. The monitored samples are an ecological and environmental risk for the aquatic environment. In the analyzed surface water samples, in addition to surfactants, other indicators resulting from the Regulation of the Government of the Slovak Republic No. 269/2010 Coll., which sets requirements for achieving good water status, were simultaneously monitored. Limit values were not exceeded during this period. Surfactants are not among the basic monitored indicators, and therefore we conclude that it is surfactants that are pollutants primarily contributing to the ecotoxicity of water. Based on these facts, we recommend including surfactants among the basic indicators monitored in surface waters.
Khordagui et al. [51] also reported the negative impact of surfactants on the aquatic environment also described. In order to reduce the negative impacts of human activity on the environment, innovative methods of wastewater treatment are coming to the fore. An example is root wastewater treatment plants, which can also remove the present emergent pollutants, including surfactants. Lobotková et al. [31] concluded the positive impact of the built wastewater treatment plants. In addition, it is necessary for the human population to use less harmful personal care and hygiene products and replace them with ecological ones.

Author Contributions

Conceptualization, M.L. and H.H.; methodology, H.H.; software, J.S. and T.H.; validation, H.H.; formal analysis, E.T.; investigation, M.L.; resources, M.L. and H.H.; data curation, T.H. and M.L.; writing—original draft preparation, M.L., H.H. and E.T.; writing—review and editing, M.L. and E.T.; visualization, J.S. and T.H.; supervision, H.H. and M.S.; project administration, H.H. and M.S. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Technical University in Zvolen under the project VEGA 1/0022/22 Evaluation Methods of Emergent Pollutants by Means of Microcosms (60%) and by Comprehensive Research of Determinants for Ensuring Environmental Health (ENVIHEALTH), grant no. ITMS 313011T721, supported by the Operational Programme Integrated Infrastructure (OPII) funded by the European Regional Development Fund (40%).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data that support the findings of this study are available from the corresponding authors upon reasonable request.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Montes-Grajales, D.; Fennix-Agudelo, M.; Miranda-Castro, W. Occurrence of personal care products as emerging chemicals of concern in water resources: A review. Sci. Total Environ. 2017, 595, 601–614. [Google Scholar] [CrossRef] [PubMed]
  2. Liu, B.; Zhang, S.-G.; Chang, C.-C. Emerging Pollutants—Part II: Treatment. Water Environ. Res. 2018, 90, 1792–1820. [Google Scholar] [CrossRef] [PubMed]
  3. Gavrilescu, M.; Demnerová, K.; Aamand, J.; Agathos, S.; Fava, F. Emerging pollutants in the environment: Present and future challenges in biomonitoring, ecological risks and bioremediation. New Biotechnol. 2015, 32, 147–156. [Google Scholar] [CrossRef]
  4. Lapworth, D.J.; Baran, N.; Stuart, M.E.; Ward, R.S. Emerging organic contaminants in groundwater: A review of sources, fate and occurrence. Environ. Pollut. 2012, 163, 287–303. [Google Scholar] [CrossRef] [PubMed]
  5. Mcclellan, K. Pharmaceuticals and personal care products in archived US biosolids from the 2001 EPA national sewage sludge survey. Water Res. 2010, 44, 658–668. [Google Scholar] [CrossRef] [PubMed]
  6. Gorito, A.M.; Ribeiro, A.R.; Almeida, C.M.R.; Silva, A.M. A review on the application of constructed wetlands for the removal of priority substances and contaminants of emerging concern listed in recently launched EU legislation. Environ. Pollut. 2017, 227, 428–443. [Google Scholar] [CrossRef] [PubMed]
  7. Deblonde, T.; Cossu-Leguille, C.; Hartemann, P. Emerging pollutants in wastewater: A review of the literature. Int. J. Hyg. Environ. Health 2011, 214, 442–448. [Google Scholar] [CrossRef]
  8. Di Marcantonio, C.; Chiavola, A.; Paderi, S.; Gioia, V.; Mancini, M.; Calchetti, T.; Frugis, A.; Leoni, S.; Cecchini, G.; Spizzirri, M.; et al. Evaluation of removal of illicit drugs, pharmaceuticals and caffeine in a wastewater reclamation plant and related health risk for non-potable applications. Process Saf. Environ. Prot. 2021, 152, 391–403. [Google Scholar] [CrossRef]
  9. Khan, M.T.; Shah, I.A.; Ihsanullah, I.; Naushad, M.; Ali, S.; Shah, S.H.A.; Mohammad, A.W. Hospital wastewater as a source of environmental contamination: An overview of management practices, environmental risks, and treatment processes. J. Water Process Eng. 2021, 41, 101990. [Google Scholar] [CrossRef]
  10. Gosset, A.; Polomé, P.; Perrodin, Y. Ecotoxicological risk assessment of micropollutants from treated urban wastewater effluents for watercourses at a territorial scale: Application and comparison of two approaches. Int. J. Hyg. Environ. Health 2019, 224, 113437. [Google Scholar] [CrossRef]
  11. Dey, S.; Bano, F.; Malik, A. 1-PPCP contamination—A global discharge inventory. In Pharmaceuticals and Personal Care Products: Waste Management and Treatment Technology; Elsevier: Amsterdam, The Netherlands, 2019; ISBN 978-0-12-816189-0. [Google Scholar] [CrossRef]
  12. Ebele, A.J.; Abdallah, M.A.E.; Harrad, S. Pharmaceuticals and personal care products (PPCPs) in the freshwater aquatic environment. Emerg. Contam. 2017, 3, 1–16. [Google Scholar] [CrossRef]
  13. Triquet, A.C.; Amiard, C.J.; Mouneyrac, C. Aquatic Ecotoxicology; Academic Press: Cambridge, UK, 2015; ISBN 978-0-12-800949-9. [Google Scholar]
  14. Palencia, M.; Lerma, T.A.; Garcés, V.; Mora, M.A.; Martínez, J.M.; Palencia, S.L. Chapter 21—Removal of emergent pollutants of waters. In Eco-Friendly Functional Polymers; Elsevier: Amsterdam, The Netherlands, 2021. [Google Scholar]
  15. Rathi, B.S.; Kumar, P.S.; Show, P.-L. A review on effective removal of emerging contaminants from aquatic systems: Current trends and scope for further research. J. Hazard. Mater. 2020, 409, 124413. [Google Scholar] [CrossRef] [PubMed]
  16. Prasad, M.N.; Vithanage, M.; Kapley, A. Pharmaceuticals and personal care products: Waste management and treatment technology emerging contaminants and micro pollutants. In Emerging Contaminants and Micro Pollutants; Elsevier: Amsterdam, The Netherlands, 2019; ISBN 9780128161890. [Google Scholar] [CrossRef]
  17. Trousil, V. Paracetamol and Ibuprofen removal from aqueous solutions by ozonation and photochemical processes. Environ. Prot. Eng. 2018, 44, 17. [Google Scholar] [CrossRef]
  18. Gomes, J.; Costa, R.; Quinta-Ferreira, R.M.; Martins, R.C. Application of ozonation for pharmaceuticals and personal care products removal from water. Sci. Total. Environ. 2017, 586, 265–283. [Google Scholar] [CrossRef] [PubMed]
  19. Zhang, Z.; Zhou, Y.; Han, L.; Guo, X.; Wu, Z.; Fang, J.; Hou, B.; Cai, Y.; Jiang, J.; Yang, Z. Impacts of COVID-19 pandemic on the aquatic environment associated with disinfection byproducts and pharmaceuticals. Sci. Total Environ. 2021, 811, 151409. [Google Scholar] [CrossRef]
  20. CHen, B.; Han, J.; Dai, H.; Jia, P. Biocide-tolerance and antibiotic-resistance in community environments and risk of direct transfers to humans: Unintended consequences of community-wide surface disinfecting during COVID-19? Environ. Pollut. 2021, 283, 117074. [Google Scholar] [CrossRef]
  21. Ghafoor, D.; Khan, Z.; Khan, A.; Ualiyeva, D.; Zaman, N. Excessive use of disinfectants against COVID-19 posing a potential threat to living beings. Curr. Res. Toxicol. 2021, 2, 159–168. [Google Scholar] [CrossRef]
  22. Morone, A.; Mulay, P.; Kamble, S.P. Removal of PPCP´s from wastewater using advanced materials. Waste Manag. Treat. Technol. 2019, 173–212. [Google Scholar] [CrossRef]
  23. Sirotiak, M.; Blinová, L.; Hlavatovičová, A. Personal healthcare products in the environment—Environmental and safety aspects. In Integral Safety of Environs; Strix et SSŽP: Žilina, Slovakia, 2017; ISBN 978-80-89753-17-8. [Google Scholar]
  24. Trajano, G.T.; Vasconcelos, O.M.S.R.; Pataca, L.C.M.; Mol, M.P.G. Anionic surfactants monitoring in healthcare facilities—A case of Belo Horizonte City, Brazil. Environ. Monit. Assess. 2022, 194, 1–12. [Google Scholar] [CrossRef]
  25. Palmer, M.; Hatley, H. The role of surfactants in wastewater treatment: Impact, removal and future techniques: A critical review. Water Res. 2018, 147, 60–72. [Google Scholar] [CrossRef]
  26. Regulation of the Government of the Slovak Republic No. 269/2010 Coll., Which Sets Requirements for Achieving Good Water Status. Available online: https://www.slov-lex.sk/pravne-predpisy/SK/ZZ/2010/269/20221115 (accessed on 1 April 2023).
  27. STN EN 903: 1999; Water Quality. Determination of Anionic Surfactans by Measurement of the Methylene Blue Index MBAS. Czech Office for Standards, Metrology and Testing: Praha, Czech Republic, 1999.
  28. OECD 202 I: 2004; Daphnia sp. Acute Immobilisation Test. OECD Publishing: Paris, France, 2004.
  29. STN EN ISO 6341: 2013; Water Quality. Determination of the Inhibition of the Mobility of Daphnia Magna Straus (Cladocera, Crustacea). Acute Toxicity Test. ISO: Geneva, Switzerland, 2013.
  30. Lobotková, M. Výskum Hodnotenia Účinnosti Čistenia Odpadových vôd Pomocou Biotestov. Ph.D. Thesis, Technical University in Zvolen, Zvolen, Slovakia, 2022. [Google Scholar]
  31. Lobotková, M.; Hybská, H.; Samešová, D.; Turčániová, E.; Barnová, J.; Rétfalvi, T.; Krakovský, A.; Bad’o, F. Study of the Applicability of the Root Wastewater Treatment Plants with the Possibility of the Water Recirculation in Terms of the Surfactant Content. Water 2022, 14, 2817. [Google Scholar] [CrossRef]
  32. State of the Environmental Report 2022. Bratislava: Ministry of Environment of the Slovak Republik. Available online: https://www.enviroportal.sk/spravy/detail/11203 (accessed on 5 June 2020).
  33. Sanjuan-Reyes, S.; Gómez-Oliván, L.M.; Islas-Flores, H. COVID-19 in the environment. Chemosphere 2020, 263, 127973. [Google Scholar] [CrossRef] [PubMed]
  34. Yari, S.; Moshammer, H.; Asadi, A.F.; Jarrahi, A.M. Side effects of using disinfectants to fight COVID-19. Asian Pac. J. Environ. Cancer 2020, 3, 9–13. [Google Scholar] [CrossRef]
  35. Tadevosyan, N.S.; Poghosyan, S.B.; Khachatryan, B.G.; Muradyan, S.A.; Guloyan, H.A.; Tshantshapanyan, A.N.; Hutchings, N.J.; Tadevosyan, A.E. Residues of xenobiotics in the environment and phytotoxic activity in Armenia. J. Environ. Sci. Heal. Part A 2019, 54, 1011–1018. [Google Scholar] [CrossRef]
  36. Kijovská, L. Ekotoxikológia vo Vodnom Hospodárstve Slovenska; STU: Bratislava, Slovakia, 2013; ISBN 978-80-227-3944-3. [Google Scholar]
  37. Hybská, H. Toxikológia a Ekotoxikológia: Návody na Cvičenia; Technical University in Zvolen: Zvolen, Slovakia, 2011; ISBN 978-80-228-2298-5. [Google Scholar]
  38. Beseda, I.; Schwarz, M.; Sokol, J.; Gáper, J.; Cejpek, K.; Blaho, J.; Bitušík, P.; Ladomerský, J.; Kontrišová, O.; Kočík, K.; et al. Toxikológia a Ekotoxikológia; Technical University in Zvolen: Zvolen, Slovakia, 2010; ISBN 978-80-228-2108-7. [Google Scholar]
  39. Fargašová, A. Ekotoxikologické Biotesty; Perfekt: Bratislava, Slovakia, 2009; ISBN 978-80-8046-422-6. [Google Scholar]
  40. Aydın, S.; Ulvi, A.; Aydın, M.E. Monitoring and ecological risk of illegal drugs before and after sewage treatment in an area. Environ. Monit. Assess. 2022, 194, 1–19. [Google Scholar] [CrossRef]
  41. Pereao, O.; Akharame, M.O.; Opeolu, B. Effects of municipal wastewater treatment plant effluent quality on aquatic ecosystem organisms. J. Environ. Sci. Heal. Part A 2021, 56, 1480–1489. [Google Scholar] [CrossRef]
  42. Sobrino-Figueroa, A. Toxic effect of commercial detergents on organisms from different trophic levels. Environ. Sci. Pollut. Res. 2016, 25, 13283–13291. [Google Scholar] [CrossRef]
  43. Liang, J.; Ning, X.-A.; Kong, M.; Liu, D.; Wang, G.; Cai, H.; Sun, J.; Zhang, Y.; Lu, X.; Yuan, Y. Elimination and ecotoxicity evaluation of phthalic acid esters from textile-dyeing wastewater. Environ. Pollut. 2017, 231, 115–122. [Google Scholar] [CrossRef]
  44. Ra, J.S.; Kim, H.K.; Chang, N.I.; Kim, S.D. Whole Effluent Toxicity (WET) Tests on Wastewater Treatment Plants with Daphnia magna and Selenastrum capricornutum. Environ. Monit. Assess. 2006, 129, 107–113. [Google Scholar] [CrossRef]
  45. Lechuga, M.; Fernández-Serrano, M.; Jurado, E.; Núñez-Olea, J.; Ríos, F. Acute Toxicity of Anionic and Non-Ionic Surfactants to Aquatic Organisms. Ecotoxicol. Environ. Saf. 2016, 125, 1–8. [Google Scholar] [CrossRef]
  46. Dave, G.; Herger, G. Determination of Detoxification to Daphnia Magna of Four Pharmaceuticals and Seven Surfactants by Activated Sludge. Chemosphere 2012, 88, 459–466. [Google Scholar] [CrossRef] [PubMed]
  47. Renzi, M.; Grazioli, E.; Blašković, A. Effects of Different Microplastic Types and Surfactant-Microplastic Mixtures Under Fasting and Feeding Conditions: A Case Study on Daphnia Magna. Bull. Environ. Contam. Toxicol. 2019, 103, 367–373. [Google Scholar] [CrossRef] [PubMed]
  48. Hodges, G.; Roberts, D.W.; Marshall, S.J.; Dearden, J.C. The Aquatic Toxicity of Anionic Surfactants to Daphnia Magna—A Comparative QSAR Study of Linear Alkylbenzene Sulphonates and Ester Sulphonates. Chemosphere 2006, 63, 1443–1450. [Google Scholar] [CrossRef] [PubMed]
  49. Soldán, P. Improvement of online monitoring of drinking water quality for the city of Prague and the surrounding areas. Environ. Monit. Assess. 2021, 193, 1–12. [Google Scholar] [CrossRef]
  50. Nason, S.L.; Lin, E.; Eitzer, B.; Koelmel, J.; Peccia, J. Changes in Sewage Sludge Chemical Signatures During a COVID-19 Community Lockdown, Part 1: Traffic, Drugs, Mental Health, and Disinfectants. Environ. Toxicol. Chem. 2021, 41, 1179–1192. [Google Scholar] [CrossRef]
  51. El-Khordagui, L.; Badawey, S.E.; Heikal, L.A. Application of biosurfactants in the production of personal care products, and household detergents and industrial and institutional cleaners. In Green Sustainable Process for Chemical and Environmental Engineering and Science; Elsevier: Amsterdam, The Netherlands, 2021; pp. 49–96. [Google Scholar]
Sustainability 15 06867 g003 550
Figure 3. Average surfactant concentrations (mg/L) in surface waters in the Nitra river basin.
Figure 3. Average surfactant concentrations (mg/L) in surface waters in the Nitra river basin.
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Figure 4. Average surfactant concentrations (mg/L) in surface waters in the Hron river basin.
Figure 4. Average surfactant concentrations (mg/L) in surface waters in the Hron river basin.
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Table
Table 2. Statistical data of the samples from surface waters in the Nitra river basin.
Table 2. Statistical data of the samples from surface waters in the Nitra river basin.
Spring 2019Spring 2020
SitesSampleAverageSDSampleAverageSD
1212
10.30.20.20.06360.10.10.10.0283
22.72.62.70.12733.13.23.10.0919
31.61.31.50.23332.22.32.20.0778
41.41.71.50.21212.42.52.40.0778
50.40.30.40.02121.00.91.00.0566
61.21.21.20.01412.72.62.60.0566
70.90.80.90.10612.62.52.60.0424
81.21.31.30.09903.73.63.60.0566
93.83.63.70.16974.14.24.10.0707
101.31.91.60.42430.70.80.70.0636
111.00.90.90.08490.60.60.60.0141
120.70.80.70.09190.30.30.30.0424
131.00.90.90.05660.70.70.70.0141
141.51.41.40.09191.71.71.70.0141
150.80.60.70.10611.41.41.40.0071
163.93.63.80.16264.44.24.30.1131
170.40.20.30.12020.60.60.60.0071
183.93.53.70.30415.05.15.00.0354
190.10.30.20.14143.13.33.20.1202
200.90.40.70.36060.60.70.70.0283
210.60.40.50.09900.80.80.80.0636
221.00.91.00.06361.82.01.90.0849
231.01.21.10.13442.32.32.30.0141
243.43.03.20.27583.74.03.80.2192
252.11.92.00.14852.32.32.30.0636
260.30.10.20.14850.80.80.80.0424
272.72.52.60.14854.74.64.60.0636
280.30.20.30.02831.31.31.30.0566
290.80.50.70.17680.60.70.70.0495
301.61.41.50.17684.03.83.90.1414
310.70.50.60.16971.11.01.00.0566
321.00.90.90.06360.50.40.50.0778
331.31.11.20.17681.61.71.60.0636
340.70.60.60.07781.21.31.30.0566
352.62.32.40.17683.63.73.60.0636
360.50.80.60.24751.11.01.10.0354
371.11.11.10.03542.32.22.30.0636
381.10.91.00.19801.11.11.10.0212
393.93.63.80.17684.94.94.90.0283
404.03.63.80.27585.35.25.30.0141
410.70.50.60.15563.73.53.60.1344
420.90.60.80.17682.52.62.50.0778
431.11.01.00.05661.21.31.30.0424
441.51.31.40.16971.61.71.60.0636
451.00.91.00.06361.11.21.20.1061
Table
Table 3. Statistical data of the samples from surface waters in the Hron river basin.
Table 3. Statistical data of the samples from surface waters in the Hron river basin.
Spring 2019Spring 2020
SitesSampleAverageSDSampleAverageSD
1212
10.00.20.10.00000.10.10.10.0000
20.10.20.10.04240.10.10.10.0141
31.01.11.00.05663.13.33.20.1556
40.60.50.60.07071.01.01.00.0283
50.30.20.30.12021.91.91.90.0354
60.20.20.20.03541.01.11.10.0636
72.82.72.80.09195.05.05.00.0636
83.12.83.00.20514.14.34.20.1273
90.70.60.70.03542.12.12.10.0424
101.41.01.20.24040.60.60.60.0424
110.80.40.60.31110.60.60.60.0212
120.20.50.40.17681.11.11.10.0354
130.40.80.60.28991.01.01.00.0283
140.10.30.20.11310.70.80.70.0354
151.10.70.90.30411.41.51.50.0778
162.32.02.20.21215.25.45.30.1273
171.11.01.00.05661.11.21.20.0283
180.71.00.80.20511.51.51.50.0283
190.40.30.40.07780.60.70.60.0354
200.60.40.50.11310.60.60.60.0283
211.92.01.90.11313.43.23.30.1626
220.80.50.60.18381.61.81.70.0990
232.92.72.80.12023.23.33.20.0778
241.00.30.70.46670.90.90.90.0424
251.51.31.40.15564.04.24.10.1485
262.61.92.30.53032.52.72.60.1131
271.00.80.90.10610.90.90.90.0071
281.20.91.10.21211.21.21.20.0566
293.03.03.00.02124.75.04.80.1980
301.91.61.70.24041.92.01.90.0636
311.61.21.40.23331.92.01.90.0778
320.50.90.70.26161.31.21.30.0424
330.30.20.20.11310.70.70.70.0212
342.82.32.50.35365.04.74.80.2192
351.61.01.30.43132.22.12.10.1131
361.11.01.00.02831.41.51.40.0778
371.91.71.80.14143.73.63.60.0778
380.30.10.20.16260.60.60.60.0424
391.41.41.40.01411.72.01.80.2192
401.00.70.90.17680.10.10.10.0141
411.01.11.10.03541.31.31.30.0354
420.70.60.60.05661.01.01.00.0212
430.90.50.70.25461.11.01.10.0495
441.802.01.90.15563.13.23.10.0636
450.901.11.00.15561.91.91.90.0636
Table
Table 4. Ecotoxicological evaluation of selected surface water samples.
Table 4. Ecotoxicological evaluation of selected surface water samples.
LocalitySpring 2019Spring 2020
Concentration
of the Surfactants (mg/L)		Test with Daphnia magnaConcentration
of the Surfactants (mg/L)		Test with Daphnia magna
River basin Nitra
(1)0.2-0.1-
(5)0.4-1.0+
(7)0.9+2.6+
(18)3.5+5.1+
(28)0.3-1.3+
(42)0.9+2.5+
(45)1.0+1.2+
River basin Hron
(6)0.2-1.1+
(19)0.4-0.7+
(25)1.3+4.0+
(34)2.5+4.7+
(37)1.7+3.6+
(41)1.1+1.3+
(44)1.8+3.1+
Explanations: (-) negative preliminary test (immobilization percentage <50%); (+) positive preliminary test (immobilization percentage >50%) [28,29].
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Lobotková, M.; Hybská, H.; Turčániová, E.; Salva, J.; Schwarz, M.; Hýrošová, T. Monitoring of the Surfactants in Surface Waters in Slovakia and the Possible Impact of COVID-19 Pandemic on Their Presence. Sustainability 2023, 15, 6867. https://doi.org/10.3390/su15086867

AMA Style

Lobotková M, Hybská H, Turčániová E, Salva J, Schwarz M, Hýrošová T. Monitoring of the Surfactants in Surface Waters in Slovakia and the Possible Impact of COVID-19 Pandemic on Their Presence. Sustainability. 2023; 15(8):6867. https://doi.org/10.3390/su15086867

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Lobotková, Martina, Helena Hybská, Eszter Turčániová, Jozef Salva, Marián Schwarz, and Tatiana Hýrošová. 2023. "Monitoring of the Surfactants in Surface Waters in Slovakia and the Possible Impact of COVID-19 Pandemic on Their Presence" Sustainability 15, no. 8: 6867. https://doi.org/10.3390/su15086867

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