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Review

Occurrence and Fate of Emerging Pollutants in Water Environment and Options for Their Removal

1
Department of Environmental Engineering and Management, “Cristofor Simionescu” Faculty of Chemical Engineering and Environmental Protection, “Gheorghe Asachi” Technical University of Iasi, 73 Prof. Dimitrie Mangeron Blvd., 700050 Iasi, Romania
2
Academy of Romanian Scientists, 3 Ilfov Street, 050044 Bucharest, Romania
*
Author to whom correspondence should be addressed.
Water 2021, 13(2), 181; https://doi.org/10.3390/w13020181
Submission received: 13 October 2020 / Revised: 7 January 2021 / Accepted: 9 January 2021 / Published: 13 January 2021
(This article belongs to the Special Issue Environmental Fate of Contaminants in the Aquatic Environment)

Abstract

:
Emerging pollutants (EPs) are chemicals known to cause major impacts on the terrestrial, aquatic life and human health as a result of their chronic and acute toxicity. Although lots of studies on EPs behavior in the aquatic environment are currently available in literature, an urgent requirement exists to complete toxicological studies and develop and implement efficient and ecological methods for their removal. This paper raises some relevant problems related to water environment pollution with EPs, the risks they can generate for aquatic life and humans and opportunities to reduce the effects of pollution by EPs removal. Categories of emerging chemicals of concern in the environment, their sources, fate and impacts, with some examples are discussed. Organic UV filters are shortly presented as a relative new EPs category, with a focus on the need to develop extensive experimental studies on their environmental occurrence, fate and removal. Furthermore, sources for the aquatic environment resulting from discharging EPs directly into rivers from wastewater treatment plants are examined. The incidence of environmental and human health risks related to EPs is also considered. The removal of EPs from the environment as a solution to risk mitigation is addressed, with emphasis on several non-conventional processes involving biological removal of EPs. The paper provides a critical look at the current challenges posed by the presence of emerging pollutants in the aquatic environment, with critical comments and recommendations for further research to reduce the impact of EPs on water and human health and improve the performance of developed methods for their removal.

Graphical Abstract

1. Introduction

Environmental pollution has become one of the most challenging and everyday problem. With the industrialization and urbanization, the degradation of the environmental quality has evolved worryingly. Diverse categories of pollutants, as persistent inorganic (e.g., heavy metals) and organic (pharmaceuticals, pesticides, endocrine disrupting agents, personal care products, etc.) are a serious problem at global level, since they can affect both flora and fauna and human health [1,2,3].
Water, an essential resource for life on Earth, is one of the most vulnerable environmental compartments; consequently, water pollution has become a matter of utmost interest and concern worldwide. The 3rd World Water Forum in Kyoto, Japan has drawn attention since 2002 to the fact that every day about 2 million tons of pollutants of various categories (sewage, industrial and agricultural waste) are discharged into water around the world, a quantity that almost equals the weight of the terrestrial population, thus generating nearly 1500 km3 of wastewater [4,5]. In this study, we present the current state of the art on the occurrence, fate, risks and removal of emerging pollutants in water and the challenges for improving existing technologies to remove emerging pollutants as a basis for sustainable water resources management.
Studies published in literature emphasize that pollutants in the aquatic environment are characterized by an interesting dynamic regarding their categories, which change over time. It is, therefore, necessary to intensify research efforts and resources invested in identifying all possibilities to reduce the impacts and risks generated by water pollution, with implicit effects on human health, because persistent pollutants possess the capacity to get involved in food chain. The improvement of the detection techniques of some substances in the aquatic environment in recent decades has led to the identification of an increasing number of pollutants and their transformation products, which were not previously known in water bodies [6,7]. These compounds are recognized as emerging pollutants, which include products used daily in households, industry and other anthropogenic activities (surfactants and degradation products, pharmaceuticals and personal care products, gasoline additives and plasticizers, etc.). Literature studies suggest that current mechanisms for collecting specific information on the dynamics of emerging pollutants in water need to be updated and refined to avoid risks for water quality, flora and fauna in river basins [3,4]. This is necessary as the Water Framework Directive [8] requires member states to establish national programs containing watching lists for emerging pollutants (EPs); these pollutants require additional attention because of the risks mentioned above which they can generate at any time. The issue of emerging pollutant is a permanent challenge, because the monitoring costs are not negligible at all and can enforce limits on the number of monitored substances. Really, the establishment of extensive databases on emerging pollutants is an open issue, as they would provide data on the properties of EPs and their metabolites and for motivating member states to include EPs in water quality surveys [4]. These approaches would be prerequisites for the development of appropriate water treatment and sustainable methods for the removal of these pollutants from the environment, fundamental for human and environmental health protection [3,4,9].
This paper reports a critical analysis on the occurrence, fate and properties of EPs, highlighting laboratory and field studies on the removal of these contaminants from aquatic environments and identifies possible limitations and gaps in the implementation of EPs removal technologies. Then, information is provided on the factors that may contribute to or adversely affect the processes discussed. Finally, current knowledge gaps, future research directions and critical understanding of state of the art on single treatment processes and/or combinations of biological and physical processes in hybrid systems for increasing the efficiency of EPs removal are shown.

2. Emerging Pollutants in Water Environment

As a result of the continuous development of anthropogenic activities (industry, agriculture, health), the production and use of chemicals known as “emerging pollutants” and/or “contaminants of emerging concerns” have increased. The first EPs were discovered in early 1800s in aquatic environments [10]. The presence of emerging pollutants in the environment is the result of the uncontrolled urbanization, development of industry, health care activities essential to support human well-being, agriculture and transport and include a wide range of substances produced by humans, considered indispensable for the modern society [3,11]. EPs are synthetic persistent organic chemicals, which are not normally monitored in the environment, but which can create adverse effects on the environment and human health. According to the NORMAN database, (www.norman-network.net), there are more than 700 compounds grouped in 20 classes of emerging pollutants: “surfactants, antibiotics and other pharmaceuticals, steroid hormones and other endocrine–disrupting compounds (EDCs), fire retardants, sunscreens, disinfection byproducts, new pesticides and pesticide metabolites, naturally–occurring algal toxins”, etc. [4,12]. Figure 1 evidences some groups of emerging pollutants that can be found in the environment.
There are numerous studies and research on the occurrence, sources behavior, impacts and risks of EPs in the environment [3,14,15,16], but currently, comprehensive data on their toxicity are not available. This is due to poor information, triggered by the complex characteristics of the emerging pollutants in the environment, related to their physico-chemical properties, causing unexpected behavior in water, soil and air [3,17]. EPs can be found in water in concentrations over a wide range, of the order of ng/L–g/L, and their effects on living organisms are associated with toxicological effects, endocrine disruption, acute and chronic toxicity, resistance of microorganisms to antibiotics, threats on human health [4,18].
There is another group of pollutants denoted as “contaminants of emerging concern”, which are “well-known chemicals that have been used for decades (some of which are persistent or pseudopersistent) in different applications and, cumulatively released into the environment, and the by-products of their environmental degradation, that are now being recorded in surface and groundwater resources, as well as in soils and sediments”. This term of “contaminants of emerging concern” is habitually used when there is very little information about the magnitude and frequency of risks posed by this category of pollutants in the environment and human health [17,19,20].
Although some emerging pollutants have existed in the environment for several years, their qualitative and quantitative occurrence have been analyzed only recently, and they might be hazardous for ecosystems [3,21]. The new analytical techniques (e.g., liquid chromatography coupled to mass spectrometry [LC-MS], tandem MS [MS2] or LC-MS2 and others) recently developed and applied made promising the detection of extremely low concentrations (μg L−1 or ng L−1) of these compounds in liquid and solid matrices. By applying these techniques, it was possible to detect and quantify around 3000 biologically active chemical compounds in the environment [22,23,24,25].
Many EPs are not subject to standards and regulations due to lack of information on the effects of chronic exposure. Pharmaceutical products (CECs), personal care products (PPCPs) and flame retardants are some of the most commonly detected EPs in the environment [3,17] (Table 1). Compounds that affect the endocrine system (EDC) are some of the most explored emerging pollutants (Figure 1); more than 200 individual compounds have been identified, and a number are monitored so far [3]. Currently, more than 3 million tons of phthalates are produced in the world, as chemical compounds that have also been used for over half a century as plasticizers in plastics or as fixing agents in cosmetics [26,27,28].
Among emerging pollutants, a category of wide interest is represented by pharmaceuticals, due to the large volume used to treat a wide variety of diseases and their very diverse physico-chemical and biological characteristics. Almost all classes of drugs, a large part of a persistent nature, have been detected in effluents [29]. Pharmaceutical compounds (entailing different classes: hormones, anti-inflammatory, anti-epileptic, statins, antidepressants, beta-blockers, antibiotics, contrast agents, etc.), after administration are largely excreted in the original form or as metabolites and can be found in urban wastewater, hospital sewers and surface waters [2,30,31,32]. They can also reach groundwater or even drinking water, as well as the soil from irrigation water. Antibiotics in the environment seem to spread in increasing quantities, encompassing a growing diversity of compounds. Recent studies found that antibiotic concentrations in some rivers of the world exceed the “safe” levels up to 300 times [33,34,35]. According to the World Health Organization, the biggest threat to global health, food security and development is antibiotic resistance. An increasing number of infections and diseases are difficult to be treated, as antibiotics used to treat them become less effective as a result of environmental pollution [36,37].
In the category of emerging pollutants, the micropollutants (EMPs) are “anthropogenic chemicals that occur in the (aquatic) environment well above a (potential) natural background level due to human activities but with concentrations remaining at trace levels (i.e., up to the microgram per liter range)” [38]. Although found at very low concentrations in aqueous solutions (from pg/L to μg/L), EMPs can induce severe toxicological effects, usually after long-term exposure.
EPs can be categorized considering their physico-chemical properties [4] as: organics with polarity (e.g., pharmaceuticals, industrial chemicals, pesticides); contaminating particles (e.g., nanoparticles and microplastics).
Once in the environment, sewage, surface water or treated effluents, EPs are more polar, acidic and alkaline than natural chemicals, making them dangerous at some concentrations. Lots of EPs are hydrophobic being dynamic through food chain, so they can accumulate in the lipid-rich tissues or can influence the endocrine system of animals and humans by direct or indirect exposure [3,39,40] (Figure 2).
A category of organic compounds that was recently included in the list of EPs is represented by ultraviolet radiation screening compounds or organic UV filters [42]. Although they can be considered as personal care products (PCPs), these compounds need special attention, since the increasing production and use of organic UV filters has made them a new category of environmental pollutants. These compounds are used extensively in the composition of sunscreen products, since they possess the ability to absorb solar radiation due to their large molar absorption coefficient in the UVA (320–400 nm) and UVB ranges (280–320 nm) [43]. Therefore, UV filters can protect consumers from the harmful effects of solar radiation and also increase the light stability of personal care products such as skin creams, hair sprays, cosmetics, hair dyes, shampoos, body lotions, etc. Their widespread use and monitoring have shown that these compounds can accumulate in the human body (being extremely lipophilic), in the environmental compartments and ecosystems [44,45]. Moreover, some preliminary animal studies have shown that some UV filters are endocrine disruptors [46,47]. Other risks associated with their presence in the environment are very little known.
UV filters enter surface water owing to the large numbers of swimmers and sunbathers during recreational activities. The beaches are the most exposed, and water in gulfs or seas can contain different UV filters from solar protection creams, such as ethylhexyl methoxycinnamate, EHMC; octocrylene, OC; butyl methoxydibenzoylmethane, BM-DBM; benzophenone-3, BP3, etc., and their monitoring anticipates hundred kilograms per year as potential of water contamination with UV filters [45]. They were identified in rivers, lakes, sea water, groundwater, sediments and biota. However, the major pollution source is represented by the effluents from the wastewater treatment plants (WWTPs). As in the case of the other categories of EPs, WWTPs are not very effective in the removal of organic UV filters. Ramos et al. provided an extensive overview on occurrence and fate of a large category of UV filters in different wastewater treatment plants [48].
If the concentration of these compounds in the aquatic environment reaches relevant levels, the quality of wastewater effluents is significantly reduced and the reuse of treated wastewater becomes limited [2,15,49]. For this reason, their occurrence and negative impacts on the aquatic environment and human health need to be fully investigated. Analysis of these compounds in complex matrices such as wastewater requires sensitive and very specific methods, as, in fact, in the case of other EPs (such as liquid chromatography coupled with tandem mass spectrometry (LC-MS/MS)).
Presently, the European legislation provided the maximum allowed concentration for each UV filter in cosmetic products (Regulation no. 1223/2009 of the European Parliament and of the Council of 30 November 2009 on cosmetic products, [50]). A number of 27 UV filters are allowed in the EU, in concentrations between 2-15%. Some organic UV filters can be converted in transformation products (TP) as a result of photodegradation under the action of solar radiation or by biodegradation in the environment, and for these reasons they are not detected during monitoring [51]. As in the case of the other categories of EPs, further experimental studies should be elaborated on the fate of UV filters mixtures in the environment.
Additionally, European legislation includes other provisions on emerging pollutants, such as: the REACH (Regulation (EC) No 1907/2006 of the European Parliament and of the Council of 18 December 2006 concerning the Registration, Evaluation, Authorisation and Restriction of Chemicals) [52]; regulation laying down the procedures for the authorization and supervision of medicinal products for human and veterinary use (Regulation of the European Parliament and of the Council amending Regulation (EC) no. 726/2004 laying down Community procedures for the authorization and supervision of medicinal products for human and veterinary use and establishing an European Medicines Agency) [53]. Under the Water Framework Directive (WFD) (Directive 2000/60/EC of the European Parliament and of the Council of 23 October 2000 establishing a framework for Community action in the field of water policy), EU member states monitor emerging substances that require this action as a consequence of the high frequency of occurrence and the potential risk to human health and the environment, on the basis of which a monitoring list of EPs is drawn up [8].

3. Challenges of Emerging Pollutants

3.1. Sources of Pollution and Fate of EPs in the Environment

Emerging pollutants, a wide range of compounds with some specific physico-chemical properties, raise numerous problems related to their removal from the environment. For example, the treatment of surface water and wastewater that contain emerging pollutants should take into account both the interactions between pollutants and those with various environmental conditions, such as seasons’ succession, intensity of solar radiation, temperature, hydraulic resistances, etc. Lots of the emerging contaminants can be found in different areas where they have never been used, because of their properties, such as persistence during long distance transport and bioaccumulation [3,54,55,56].
Emerging pollutants can occur in the environment from various point or diffuse sources, and then reach the soil, atmosphere or water bodies through several ways or mechanisms that depend largely on EPs properties (polarity, volatility, persistence, etc.) and the environmental compartments characteristics [4]. EPs and some of their metabolites are released into the environment over several routes from industry, households, hospitals, lands, etc., (Figure 3) and enter surface and ground waters [14,57].
EPs can become easily pollutants of river ecosystems where insufficient treated effluents from wastewater treatment plants (WWTP) are discharged (Figure 4). They can (bio)accumulate in sediments and river flora and fauna due to their persistence, since their biodegradation, chemical degradation and photodegradation (in absence of light) can occur at very small rates. Hence, their disappearance from water environment is almost negligible [58,59]. Although, certain microbial populations are able to struggle the biocide effect of EPs and feasibly alter them, increasing their degradation rate. There are few studies investigating the natural biodegradation of EPs such as hormones, some detergents or pharmaceuticals. Usually, these studies are performed in the laboratory, but it is not certain that the experimental systems replicate well the real environmental condition, while the implementation of these results at large-scale is not sufficiently clarified yet [3,4,59]. Therefore, the development of studies and research for finding and exploiting microbial populations tailored for different categories of EPs or even targeted for certain compounds is a task with great perspectives for researchers.

3.2. Environmental and Health Risks Associated with Emerging Pollutants

The incidence of environmental and human health risks related to EPs is due to their toxicity. EPs are considered highly toxic, since nanogram per liter (ng/L) concentrations can exhibit relative effects to both humans and aquatic organisms, such as hormonal interference in fishes, genotoxicity, carcinogenicity in lab animals, endocrine disruption and immune toxicity [60,61]. It is not known and/or it is difficult to estimate the long-term impacts of the majority of EPs on the environment and human health and this is still a concern, while the awareness on their behavior and hazard/ecological risks is really insufficient. Literature recommends the application of specific tools for assessing the toxicity effects of emerging pollutants: environmental risk assessment (ERA), quantitative analysis of the structure-activity relationship (QSAR), the relationship between physico-chemical properties and environmental behavior and fate (PPEF), assisted by software tools [4,29,62,63,64].
The existing studies on the risks caused by emerging pollutants in the environment and, in particular, in water have taken into account their toxicity on aquatic flora and fauna (fish, algae, daphnia) but have also focused on the risks to human health, especially in water recovery and reuse systems (Table 2). However, given the low concentrations of these pollutants in liquid flows, data collection on the toxicity parameters and human exposure are, thus, real scientific challenges [65,66].
In this context, guidelines have been developed by the United States Environmental Protection Agency [67] and the World Health Organization (WHO), which provides methods for assessing the risk of EPs to human health and ascertaining factors of exposure to various chemicals. In the European Union, protocols and methodologies have been developed for the analysis of risks generated by chemicals, starting from 1980 (for “new chemicals”), then, at the beginning of the 1990s, pharmaceutical products were considered [54]. One of the most important developments regarding the registration and evaluation of the authorization of chemicals is represented by the REACH regulation [52].
Literature on ecological and human health risks has focused, as a priority, on classes of contaminants in wastewater and surface water [68]. Additionally, some studies addressed the EPs accumulation in sediments, which are usually seen as a sink for EPs and toxicity [69,70]. Moreover, sediments can become a source of contamination with EPs for aquatic flora and fauna if the particles forming the sediments are remobilized and suspended in the moving liquid flow (e.g., during floods) (Figure 4). EPs associated with solid particles can become potentially bioavailable to benthic organisms, and if the level of bioaccumulation is high enough, they can generate acute and chronic exposure and spread to higher trophic levels [71,72,73].
In river water, EPs can undergo possible transformations into less toxic, but also, even more toxic products can be adsorbed on sediments where they accumulate or are transported to other water bodies, where sensitive or protected flora and fauna can exist, or in groundwater that often serves as a source of drinking water [72]. There, EPs will manifest their toxic effects, depending on their category and mixtures (Table 3). If EPs are in mixtures, the toxic effects can cumulate and generate synergistic or antagonistic interactions, leading to the so-called cocktail effect, so that the difficulty of risk analysis increases [4,16,62]. In this context, the precautionary principle needs to be applied consistently to ensure a clean and healthy environment for future generations, which is why further studies on the risks induced by EPs (as a result of their specific environmental behavior, toxicity and impacts on the environment and human health) become essential.
Often, the origin of EPs and the risks generated by them are difficult to detect, as long as they can originate from diffuse sources of pollution such as sewer leaks and discharges, storm water runoff in urban areas and on agricultural land, etc. (Figure 3, Figure 4 and Figure 5). To estimate the risks generated by EPs from various sources towards various receptors, it is necessary to identify them and determine the acute and chronic doses and exposures. The information needed for risk estimation and analysis is obtained in research laboratories developing studies in environmental chemistry, toxicology and ecotoxicology that can generate original data and complete sets of tests according to existing regulations. These steps can facilitate the identification and characterization of sources (hazards), pathways (transport and fate of EPs), receptors and consequences, including human exposure (pollutant linkage) [62,74].
Currently, the environmental risk assessment (ERA) is performed by calculating the value of the ratio between the predicted environmental concentration (PEC) and the predicted no effect concentration (PNEC) for a certain single substance [75,76]. Somewhat recently, the development of pharmacokinetic models based on physiological biotransformations in the entities affected by EPs (PBPK) allowed the description of EPs intake, distribution, metabolism and excretion [4,77]. However, in most cases, addressing the relationship of some EPs with the environment and the associated risk, the pathway from source to receptor is difficult to clarify, especially for new substances, because this pathway depends on many factors related to the substances themselves, the source (hazard), environmental conditions and potential treatments to which EPs are subjected (Figure 5).
Solving these problems as quickly as possible would facilitate the best decisions for risks management. Besides, the estimation and analysis of risks generated by mixtures of EPs impose new strategies, which should reproduce the reality as accurately as possible, because, if only one substance from the mixture is taken into analysis or each substance separately, the toxicity of the mixture can be underestimated or overestimated [76]. In literature, two types of problems are addressed regarding this matter [78]:
-
Evaluation of mixture toxicity, when the results are valid only for that mixture and cannot be extrapolated to other exposure scenarios;
-
Evaluation taking into account the components of the mixture, when the results can be interpreted in two ways: by cumulating the toxicities of the components or considering the independent action of each component of the mixture leading to a common toxicological effect.
However, these two approaches cannot describe the real effects of EPs mixtures, some studies showing that estimating toxicity by testing mixtures can lead to a higher toxicity than the actual value, while individual estimations can result in a lower toxicity than the actual one [76,78].
Risk assessment and analysis are relevant issues for EPs research, since they can allow the management of pollutants in a “risk-based” approach, by providing the support for decisions making on the appropriate remediation options, both in terms of risk reduction and cost effectiveness and efficiency, in an integrated way (Figure 6). Integrated risk assessment facilitates risk communication to stakeholders for analysis and making decisions regarding risk mitigation [57,62,71].

3.3. Short Overview on the Assessment of Risks Generated by Emerging Pollutants

Ecological and human health risks of EPs are assessed in view of generating decision-making support to ensure the protection of ecological systems, in particular the aquatic environment, as well as human health. The subjects of human health risk assessment are individuals who may come into direct or indirect contact with toxic pollutants, either through the consumption of drinking water or the intake of contaminated food or vegetable products irrigated with reclaimed water insufficiently purified. At the level of the European Commission, it is emphasized that, if chemical exposure is assessed, it is necessary to take into account the cumulative effect of previous emissions, which can generate residual or background concentrations [79].
One of the most widely applied approach for assessing the ecological risk of detected EPs is the risk quotient (RQ) method. RQ is calculated according to Equation (1) [80,81]:
R Q = M E C P N E C
where MEC represents the measured environmental concentration; PNEC is the predicted no-effect concentration.
RQs essentially constitute an index for quantification of the environmental risk of chemicals and involve comparison of the environmental concentrations of pollutants with the concentrations that should ensure an absence of adverse effects on target organisms, based on empirical data” [82,83].
When the risk analysis is performed for the aquatic environment emphasized, it is imperative to evaluate the concentrations detected in the environment and the chronic toxicity of EPs for aquatic organisms, in view of RQ determination [84]. PNEC results by dividing the value of acute (short-term) or chronic (long-term) toxicity by an assessment factor (AF) [79]. Acute toxicity can be considered as the median lethal concentration (LC50) or mean effective concentration (EC50), in which case AF = 1000. Chronic toxicity is given by no observable effect concentration (NOEC), in which case AF can be 100, 50, 10 depending on the trophic levels [85,86]. In this context, the risk level can be (i) low, when RQ ≤ 0.1; (ii) medium, when 0.1 < RQ < 1; (iii) high, when RQ ≥ 1 [87].
RQ calculated with Equation (1) refers to the toxicity of EPs based on measured environmental concentrations, but does not take into account variations in concentrations over time that would expose aquatic organisms to levels of toxicity above the tolerability limits, especially in case of compounds with long-term presence in water bodies. In this circumstance, there is the problem of differentiated risk analysis for frequently detected EPs and, respectively, for occasionally detected EPs, i.e., the consideration of a frequency factor in the calculation of RQ. In this context, Zhou et al. [84] proposed a new risk quotient (RQf) based on the average value of RQ and the frequency of MECs exceeding PNEC and applied in the assessment of the potential risks posed by the detected substances. The RQf value can be calculated according to Equations (2) and (3):
R Q f = R Q × F = M E C P N E C × F
F = N O 1 N O 2
where RQf is the frequency-based risk quotient, in fact, an optimized risk quotient resulted after the frequency of MECs, which exceed PNEC was considered; F is the frequency of MECs exceeding PNEC; NO1 represents the number of samples with concentrations higher than PNECs; NO2 represents the total number of samples. RQf was classified in 5 groups as shown in Table 4.
Risks assessment to human health associated with EPs is based on the responses of some biological species to the dose–response relationship for a certain range of EPs concentrations. Although their effects on humans have not been too much explored, the adverse effects on human health are quantified mainly based on models. These models need to be validated in order to quantitatively estimate the ability of EPs to produce major changes to human health and what types of risks are significant [88]. The non-carcinogenic risk due to EPs ingestion can be assessed using the hazard index (HI), calculated for different exposure pathways (inhalation, ingestion, dermal contact, etc.) (Equation (4)) [86]:
H I i n g e s t i o n = C D I i n g e s t i o n R f D
where CDI represents the chronic daily intake of the EPs by ingestion (mg/(kg·day)), and RfD is the reference dose for the EPs (mg/(kg·day)).
For HI > 1, adverse health effects can occur, while for HI < 1, the effects are insignificant.
The CDI value can be estimated according to Equation (5) [80]:
C D I = C × I R × E F × E D B W × A T
where C is the concentration of EPs in water; IR means the rate of polluted water intake (determined as 1.41 L/day for an adult and 0.87 L/day for a child); EF is the frequency of exposure (365 days/year); ED is the exposure period (70 years for an adult, 6 years for a child); BW is body weight (70 kg for an adult, 20 kg for a child); AT is the average lifespan (25,550 days for an adult, 2190 days for a child (according to [79]).
RfD can be calculated according to Equation (6) [80]:
RfD = LD50 × 4 × 10−5
In most cases, human exposure does not occur in relation to only one pollutant, but mixtures of chemicals are involved. For this reason, researchers have developed methods for assessing the risks to human health associated with exposure to various sets of pollutants.
The total potential non-carcinogenic risks produced by different paths can be assessed by the cumulated hazard index (HIcum), as expressed by Equation (7) [19]:
H I c u m = H I i n g e s t i o n + H I d e r m )
Similarly, for HIcum > 1, there are adverse effects on human health [19].
Fabrega et al. [89] have calculated the Integrated Risk Index of Chemical Aquatic Pollution (IRICAP) (Equation (8)):
I R I C A P = h a z a r d i n d e x × c h e m i c a l c o n c e n t r a t i o n n u m b e r o f c h e m i c a l s
To calculate IRICAP, the hazard index of each individual compound was multiplied by the normalized water concentration at each sampling point, and then being summed and the final amount divided by the number of pollutants. Concentrations are normalized for each chemical (according to Equation (9)), to avoid any overestimation for each chemical.
C n o r m = C i C min C max C min
In order to mitigate the risks generated by EPs in the environment and for human health, various management options can be applied when specific analyses reveal that an emerging pollutant can be considered as producing unacceptable risks [90]. First, it is essential to prevent risks by applying sustainable, ecological industrial practices and technologies for the synthesis of environmentally friendly products, mostly biodegradable. On the other hand, it is necessary to develop efficient wastewater treatment technologies able to reduce the amounts of EPs that can reach natural water bodies.

4. Removal of EPs from the Environment as Solution for Risks Mitigation

As a result of the continuous rising of awareness on the occurrence and threatens produced by EPs in the environment, their treatment and removal have become increasingly challenging concerns for researchers and practitioners [4,74,91]. Due to some of their properties mentioned above, EPs that commonly occur in industrial and municipal wastewater treatment plants are difficult to be removed by applying conventional treatment technologies [21,92]. Therefore, the application of efficient treatment processes is imperative to favor the discharge of effluents with low impact on aquatic systems and the environment in general.

4.1. Short Analysis of Processes Applied for EPs’ Removal

Research has generated progress for EPs removal to overcome the problems of traditional treatment plants. This would ensure an efficient management of effluents developed to comply with the regulations in force on the discharge of treated effluents. In this context, efficient methods for advanced treatment of effluents polluted with EPs are developed, which include physico-chemical and biological processes (sand and media filtration; chlorination; advanced oxidation processes, AOPs; adsorption using granular activated carbon, zeolite or other clay materials; hydrolysis processes; constructed wetland (CW); membrane bioreactors, phytoremediation, biosorption), as illustrated in Figure 7 [93,94,95].
The application of activated sludge process to remove emerging pollutants is usually recommended to reduce high organic loads, but it is not suitable for removing EPs, especially at very low concentrations or traces of pollutants [96]. In addition to the low EC removal efficiency, the traditional activated sludge process is associated with the production of a very large amount of activated sludge, which is treated as waste [97].
EPs are currently removed from water by adsorption or oxidation processes or a combination of biological and advanced treatment processes [98,99]. Although conventional and advanced oxidation processes proved to be effective, they have the disadvantage that can lead to the formation of intermediates, which are often unidentifiable or difficult to identify and can sometimes be more toxic than the initial compounds. From this point of view, adsorption is beneficial, since it does not generate unwanted by-products, and the loaded adsorbed can be then properly treaded. Emerging pollutants with high polarity, such as a large part of pharmaceuticals, can be removed by biological degradation and mineralization achieved by specific microorganisms, respectively [14,100]. Table 5 describes certain advantages and challenges of some processes applied to remove EPs.

4.2. Progresses in Biological Treatments Applied for the Removal of Emerging Pollutants

In recent decades, numerous studies have been dedicated to the development of innovative, sustainable technologies for the removal of EPs from wastewater, which is the most relevant source of pollution of the aquatic environment with EPs. Of these, biological processes have stimulated the interest of specialists for application to degrade some EPs, although certain extreme recalcitrant contaminants are still difficult to (bio)degrade or even impossible to remove. However, efficient innovative processes can be combined in hybrid systems, which can overcome the deficiencies in existing biological technologies.

4.2.1. Removal of EPs in Constructed Wetlands

Conventional wastewater treatment processes with activated sludge can be applied for wastewater treatment containing EPs, but in combination with advanced processes (tertiary treatment such as ozonization, photodegradation, biodegradation), which increase the efficiency of the treatment. The disadvantage of this combination of processes is that they are energy consuming and involve high costs, being disadvantageous especially for small communities. Constructed wetlands (CWs) can be a promising alternative as tertiary but also as primary and secondary treatment systems (for organics and nutrients removal) due to low energy, operational and maintenance costs and good treatment efficiency [101,102,103]. Although studies in recent years on the elimination of EPs (especially pharmaceuticals and personal care products) in constructed wetlands have been intensified, the vast majority are developed on a small scale (laboratory, pilot), and little information is available on the exploitation of constructed wetlands on a large scale [103,104]. Table 6 presents some results regarding the treatment efficiencies of wastewater containing different EPs in various CW configurations.
A number of factors can affect the efficiency of removing EPs in constructed wetland, some of them are described below:
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CWs configuration: different operating modes (subsurface, surface, vertical or horizontal flows) are generated in CWs and are important for the elimination of EPs from wastewater through highly oxygen-dependent processes [104]. In this context, the planted vegetation (emerged or submerged and fixed or free-floating) demonstrated significant role in EPs removal; however, the role of plants at microcosm scale, in treating effluents containing emerging pollutants in the constructed wetland system is still a topic of debate [108,118].
-
Season of the year: efficiencies during summer operation were generally found higher than those resulted during winter, following higher biodegradation kinetics, plant biomass, variations in influent concentration [106,119]. However, a few studies show that the elimination of some personal care products (PCPs) in CWs is not affected by temperature [108]. Therefore, the mechanism by which the season influences the elimination of some EPs and the extent to which this influence occurs requires additional and rigorous studies, especially on the processes that can eliminate EPs, either degradative (biodegradation) or non-degradative (adsorption, absorption by plants).
-
Parameters of the influent to be treated: the results obtained by various researchers [102,103] show that CWs can achieve good elimination efficiencies for Biological Oxygen Demand (BOD5) (81.5–95.6%), Chemical Oxygen Demand (COD) (57.2–84.0%) and Total Suspended Solids (TSS) (81.7–96.4%), while the removal of ammonia (17.4–67.0%) and Total Phosphorous (TP) (5.3–84.1%) was variable and much lower. However, these results depend on the type, configuration and scale of CWs operation. A rigorous analysis of literature data on the influence of water composition on treatment efficiency can reveal that there is a large dispersion of results, which requires integrated studies and extensive collaborations among research groups, based on robust experimental programs so as to diminish the contradictions between the results.
-
Oxygen availability: experimental studies conducted in different cases have established a positive correlation between the concentration of dissolved oxygen in the CWs wastewater influent and the elimination efficiency of emerging pollutant [108].

4.2.2. Removal of EPs by Membrane Biological Reactors

The removal of pollutants from wastewater using biological membrane reactor systems (MBR) is considered an efficient one, e.g., by about 15–42% when compared to the activated sludge system. MBR cannot completely remove EPs alone, so that it is combined usually with ozonation, activated carbon, photodegradation, etc., for polishing the removal [120]. MBR integrates biological and physical processes: the activated sludge treatment and membrane filtration, which can assure good removal efficiencies. Biodegradation, photodegradation, volatilization, sludge absorption of pollutants can occur at long retention times that also allow the elimination of nitrogen and the growth of nitrifying bacteria, which can improve the performance of the process [121,122]. An important advantage is that MBR can operate at relatively low costs, while membrane fouling is a disadvantage [122].
Anaerobic membrane bioreactors (AmMBR) are new and innovative technologies for the treatment of influents with fluctuating pollutant concentrations [123]. AmMBR is based on the anaerobic digestion technology, being characterized by stability and microbial abundance, with good toxic resistance, which ensures a high efficiency of EPs biodegradation. AmMBR can also generate biogas (as renewable bioresource) in significantly larger quantities than the conventional anaerobic biodegradation system, so that it is increasingly used to remove EPs from liquid effluents [97,103]. While in the conventional anaerobic process the efficiency of biogas generation is dependent on methanogenic bacteria, solids retention time (SRT) and hydraulic retention time (HRT) [124], in AnMBR, there is a high and stabilized cell concentration built on reasonably high hydraulic load and adequate mixing as a result of totally decoupling HRT from SRT, since membranes hinder biomass being washed out [125,126].
As in the conventional MBR, the membrane fouling in AnMBR is a disadvantage, since it reduces the flow through the membrane and, therefore, makes it necessary to ensure larger membrane areas per reactor volume, with increased capital costs, which limits AnMBE application on a larger scale [97,127].
There is a combination of factors that control the membrane fouling, such as [125,126,128]:
-
Bioreactor operating conditions (organic loading rate, influent water quality and variability, sludge retention time, hydraulic loading rate, pH, temperature, toxicity of EPs);
-
Membrane properties (surface morphology and chemistry, pore size and porosity);
-
Hydrodynamic conditions: cross flow velocity, shear stress, gas sparging flow rate and bubbles properties, backwashing potential)
-
Process performance (membrane flux, pressure drop, effluent quality, economic aspects);
-
Biological properties (biomass concentration, distribution of solid particles, presence of polysaccharides, colloidal particles and soluble microbial products)
-
Chemical system characteristics (presence of cations and anions)
The performance of AnMBR can become flexible by selecting the adequate configuration of membrane module as follows (Figure 8) [97,129,130,131,132,133]:
-
Side stream:
The crossflow filtration involves a tangential flow rate, which stimulates the membrane fouling and large energy consumption;
Easy removal and cleaning of membrane.
-
Submerged:
Can treat high strength industrial wastewater (pharmaceutical and textile wastewaters) [134];
Membrane fouling can occur being quite difficult to clean.
-
External submerged:
The membrane module is submerged in an external compartment;
Shear force of water flow is intense, which reduces membrane fouling.
-
Anaerobic dynamic membrane bioreactor:
Low membrane module cost, easy control of membrane fouling;
Low energy consumption, sludge and biogas production.
-
Anaerobic electrochemical membrane bioreactor:
A microbial electrolysis cell (MEC) combined with membrane filtration;
Electrically conductive, porous, nickel-based hollow-fiber membranes (Ni-HFMs).
-
Anaerobic osmotic membrane bioreactor:
A forward osmosis (FO) membrane;
Salt accumulation and membrane fouling can diminish permeate flux.
A wide variety of EPs can be removed in the AnMBR system, but with various efficiencies, which depend on a number of factors, including the composition of the influent, pollutant, HRT, etc., as is shortly presented in Table 7.

4.2.3. Removal of EPs by Biosorption

Adsorption is the one most applicable and hopeful methods for removing organic and inorganic micropollutants from liquid effluents. The adsorption is a surface process, in which the pollutant and the adsorbent interact through physical and chemical forces. To achieve high adsorption efficiencies, the process is optimized based on experiments that provide information on the influence of factors such as pollutant concentration, adsorbent dose, nature of adsorbent and pollutant, pH, contact time, temperature, presence of other pollutants. Additionally considered are the equilibrium conditions described by adsorption isotherms, which can be represented by models such as Langmuir, Freundlich, Tempkin, Henderson, Halsey, Smith, Elovich, liquid film diffusion, intra-particle diffusion and Lagergren. Adsorption kinetics play an important role in the design of adsorption systems, using kinetic parameters, free energy, enthalpy, entropy and activation energy.
There are frequent studies in literature that discuss the application of various materials as adsorbents for the removal of EPs from polluted liquid streams (Figure 9). New adsorbents were found and studied in the last years together with existing adsorbents, in terms of their capability to immobilize different EPs from aqueous solutions (sorption efficiency, mechanism of interactions involved and the best fit model) [29,92,138] (Figure 10).
A distinctive adsorption process is biosorption—a biological treatment technology that arouses a growing interest nowadays, since a wide range of materials from biomass can play the role of adsorbent. Biosorption can be considered, in general, an effective alternative for the elimination of broad categories of persistent pollutants (inorganic and organic) in the treatment of secondary or tertiary effluents [29]. Biosorption offers some advantages such as low costs due to the abundance of biomass, the possibility of regeneration and recovery of exhausted sorbents and relatively high selectivity compared to conventional techniques (ion exchange, membrane separation, coagulation, etc.) [100,139]. Some advantages of biosorption are shown in Figure 11.
From an economic perspective, biosorption feasibility is dependent on the nature of biomass (vegetable, microbial, algae, etc.), the biosorption capacity of sorbents, the possibilities to modify the sorbent surface to improve the sorption capacity and the chance to regenerate the exhausted biosorbent [140]. Another important aspect, from both economic and ecological points of view is related to the use of biomass waste (from agriculture, food industry, wood industry, etc.) as a source of biosorbents. The removal efficiency of some EPs by biosorption was analyzed by Ahmed et al. [100], as shown in Table 8, for live cultured and harvested white rot fungus (T. versi-colour) in parallel with inactivated biomass by sodium azide, as reported by Nguyen et al. [141]. However, there are a number of unknowns that need to be elucidated regarding the ability and selectivity of the biosorption process to remove EPs from multicomponent mixtures. Additionally, living microbial cells used as biosorbents are difficult to immobilize on a solid support due to their poor mechanical properties [142].

4.2.4. Hybrid Treatment Schemes

The efficiency of removing EPs from aqueous media is dependent on the applied removal process and the chemical compound and can show different values, even for the same compound, as can be seen in Table 9. For example, the diclofenac can be removed with an efficiency of 97% by living microorganisms’ uptake (fungi in this case) or of 55% when treated in horizontal subsurface flow constructed wetland (HSSF-CW). Carbamazepine is removed with low efficiency by biological processes, not exceeding 22% when treated with HSSF-CW (Table 9).
To streamline the elimination of a greater diversity of EPs, some hybrid treatment schemes have recently been applied, and significant improvements were noticed in the treatment efficiency [100].
Hybrid systems are able to ensure maximum removal efficiency of EPs, achieved in a first step by biological processes, followed by physico-chemical processes, which complete the treatment (Table 10). Such hybrid processes may be, for example [100,101]:
Activated sludge process + membrane separation/filtration systems (reverse osmosis, ultrafiltration) + gamma radiations;
Constructed wetlands coupled with waste stabilization ponds (removal of pharmaceuticals, beta-blockers), or biodegradation, or/and sorption, or/and volatilization, or/and hydrolysis, or/and photodegradation;
Membrane bioreactor (MBR) + membrane separation/filtration systems (reverse osmosis, nanofiltration) (removal of pesticides, pharmaceuticals, beta-blocking drugs);
Membrane bioreactor (MBR) + UV oxidation, or adsorption on activated carbon, or ozonation followed by ultrasounds;
Ozonation + biological activated carbon (drugs: antibiotics, antidepressants, beta blockers, endocrine disrupting chemicals, pesticides);
Flocculants + activated sludge + ultrafiltration (endocrine disrupting chemicals, pesticides, beta blockers);
Ultrafiltration + activated carbon + ultrasounds (antibiotics);
Surface flow constructed wetland (SFCW) + horizontal flow constructed wetland (HFCW) (drugs: beta blockers, stimulants).
Overall, the hybrid systems show attractive potential for the EPs removal, but complete removal was not always observed. Therefore, it is necessary to extend research and experiments, up to large scale, to explore hybrid treatment technologies that also integrate photochemical, electrochemical and other treatments with biological ones.

5. Conclusions

The occurrence of emerging pollutants in the environment continue to generate increasingly stringent problems. Thanks to the increase in water monitoring and development of new analytical techniques mixtures of emerging chemicals are detected in aquatic environments. Even if they can be present at very low concentrations (ng/L), their impact on environmental and human health may be significant.
Source reduction and substitution of emerging pollutants with products having lower toxicity and easier to remove from water can play an important role in reducing the impact of EPs on the environment and human health but are not feasible in all cases. Studies on the elimination of emerging pollutants need to be focused on robust remediation processes developed on sustainable bases, designed to ensure consistency between pollutants characteristics and the possibility of integrating several removal processes to ensure compliance with regulations. Future technologies need to be both effective and environmentally friendly treatments, capable of removing the widest possible spectrum of emerging pollutants, with low energy consumption and capital expenditures. Moreover, the efficiency of the treatment has to be adjustable to emerging pollutants concentrations in the aquatic environment and to make it possible to recover the treated water.

Author Contributions

Conceptualization, I.C.V., M.G.; writing—original draft preparation, I.C.V., D.M.A., D.I.F.; writing—review and editing, M.G.; funding acquisition, M.G. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by a grant of the Romanian National Authority for Scientific Research, CNCS—UEFISCDI, project number PN-III-P4- ID-PCE-2016-0683, Contract no. 65/2017, and a grant of the Romanian Ministry of Education and Research, CCCDI—UEFISCDI, project number PN-III-P2-2.1-PED-2019-5239, Contract no. 269PED/2020, within PNCDI III.

Institutional Review Board Statement.

Not applicable.

Informed Consent Statement.

Not applicable.

Data Availability Statement

Data is contained within the article.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

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Figure 1. Categories of emerging pollutants that impact on soil, air, water, animals, plants, microorganisms and humans (adapted upon [13,14,15,16]).
Figure 1. Categories of emerging pollutants that impact on soil, air, water, animals, plants, microorganisms and humans (adapted upon [13,14,15,16]).
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Figure 2. Emerging pollutants volatility and polarity (adapted upon [41]).
Figure 2. Emerging pollutants volatility and polarity (adapted upon [41]).
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Figure 4. Incidence of emerging pollutants’ (EPs) toxicity from various sources of pollution (hazards), which can generate environmental and human threats/consequences.
Figure 4. Incidence of emerging pollutants’ (EPs) toxicity from various sources of pollution (hazards), which can generate environmental and human threats/consequences.
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Figure 5. Sources (bold) and pathways for emerging contaminants to reach various receptors (grey) [73]. (Reproduced from [73] with Elsevier permission, license 4912431334481, from 19 September 2020).
Figure 5. Sources (bold) and pathways for emerging contaminants to reach various receptors (grey) [73]. (Reproduced from [73] with Elsevier permission, license 4912431334481, from 19 September 2020).
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Figure 6. Risk-based decision analysis [62] (reproduced from [62] with Elsevier permission, license 4912101420021, from 18 September 2020).
Figure 6. Risk-based decision analysis [62] (reproduced from [62] with Elsevier permission, license 4912101420021, from 18 September 2020).
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Figure 7. Physico-chemical and biological processes applied for the removal of emerging pollutants from the environment (developed mainly based on information from [93,94,95]).
Figure 7. Physico-chemical and biological processes applied for the removal of emerging pollutants from the environment (developed mainly based on information from [93,94,95]).
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Figure 8. Conventional anaerobic membrane bioreactor (AnMBR) types. Side stream AnMBR (a), submerged AnMBR (b) and external submerged AnMBR (c). Novel AnMBR configurations: anaerobic dynamic membrane bioreactor (d). (Reproduced from [97] with Elsevier permission, license 4963301077334, 6 December 2020).
Figure 8. Conventional anaerobic membrane bioreactor (AnMBR) types. Side stream AnMBR (a), submerged AnMBR (b) and external submerged AnMBR (c). Novel AnMBR configurations: anaerobic dynamic membrane bioreactor (d). (Reproduced from [97] with Elsevier permission, license 4963301077334, 6 December 2020).
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Figure 9. Various categories of adsorbents used in the elimination of emerging pollutants.
Figure 9. Various categories of adsorbents used in the elimination of emerging pollutants.
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Figure 10. Sorbents and mechanisms for the removal of some emerging pollutants from the environment (adapted upon [29,92]).
Figure 10. Sorbents and mechanisms for the removal of some emerging pollutants from the environment (adapted upon [29,92]).
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Figure 11. Some advantages of applying biosorption for the removal of emerging pollutants from liquid effluents.
Figure 11. Some advantages of applying biosorption for the removal of emerging pollutants from liquid effluents.
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Table 1. Categories of emerging chemicals of concern in the water environment, with some examples [3,14,15,16].
Table 1. Categories of emerging chemicals of concern in the water environment, with some examples [3,14,15,16].
GroupCompounds
Various chemicals
New phthalatesDPHP (Di-2-propylheptyl phthalate)
Non-phthalate plasticizersATBC (Acetyltributyl citrate), DEHA (Di-2-ethylhexyl adipate), DEHS (Di-2-ethylhexyl sebacate), DEHTP (Di-2-ethylhexyl terephthalate), DINCH (1,2-Cyclohexanedicarboxylicacid-diisononyl ester), DnBA (Di-n-butyl adipate), DIBA (Di-isobutyl adipate), DINA (Di-iso-nonyl adipate), TOTM (Tri-2-ethylhexyltrimellitate)
Emerging flame retardantsDBDPE (Decabromodiphenyl ethane (BDPE-209)), TBBPA-BDBPE (Tetrabromobisphenol-A-bis(2,3)-dibromopropyl ether), BEH-TEBP (Bis(2-ethylhexyl)-tetrabromo phthalate), BTBPE (1,2-Bis(2,4,6-tribromophenoxy) ethane), EH-TBB (2-Ethylhexyl-2,3,4,5-tetrabromobenzoate), DBE-DBCH (Tetrabromoethylcyclohexane), PBB (Pentabromobenzene), PBT (Pentabromotoulene), HBB (Hexabromobenzene), TBX (1,2,4,5-tetrabromo-3,6-dimethylbenzene), TBCT (Tetrabromo-o-chlorotoluene), DDC-CO (Dechloran Plus)
BPA (Bisphenol A) substitutesBPS (Bisphenol S), BPF (Bisphenol F), BPAF (Bisphenol AF)
DrugsMethylamphetamine, tetrahydrocannabinol (THC)
Technologies
3D-printingCaprolactam, lactide, Irganox 1076, siloxanes (D3-D6)
E-cigarettes, e-shishasPropylene glycol, glycerol, glycidol, acetol, diacetyl
Energy saving lampsMercury (Hg)
NanospraysSilver (Ag), siloxanes, MgO, ZnO, TiO2
Pharmaceuticals compounds
AntibioticsTrimethoprim, Ciprofloxacin, Sulfamethoxazole
Analgesics and anti-inflammatoryNaproxen, Ibuprofen, Diclofenac, Salicylic acid, Ketoprofen
AntiepilepticsCarbamazepine
DisinfectantTriclosan
DiureticsFurosemide, Hydrochlorothiazide, Amidotrizoic acid, Diatrizoate, Iotalamic acid
Lipid regulatorsFenofibric acid, Gemfibrozil, Bezafibrate, Atenolol
CosmeticsGalaxolide, Tonalide
Other pollutants of concern
Corrosion inhibitorsBenzothiazoles, benzotriazoles
UV filtersBenzophenone-3, homosalate, octocrylene, 4-MBC, 2-ethyl-hexyl-4-trimethoxycinnamate (EHMC)
Synthetic muskGalaxolide (HHCB), tonalide
Biocidesparabens, neonicotinoids
ParticlesMicroplastics
Table 2. Toxicities of the drugs and pharmaceuticals residues in aquatic organisms and plants *.
Table 2. Toxicities of the drugs and pharmaceuticals residues in aquatic organisms and plants *.
Therapeutic GroupCompoundsTaxonomic GroupLong-Term Exposure
(mg/L)
Anti-bacterialTrimethoprimPlant (duckweed)>1.0 (EC10)
Anti-bacterial (aminoglycoside)NeomycinPlant (duckweed)>1.0 (EC10)
(Aminoglycoside) anti-bacterialStreptomycinPlant (duckweed)>1.0 (EC10)
Anti-bacterialCephalexinPlant (duckweed)>1.0 (EC10)
Anti-bacterialCiprofloxacinPlant (duckweed)0.106 (EC10)
NorfloxacinPlant (duckweed)0.206 (EC10)
Anti-bacterial (macrolide antibiotic)ErythromycinPlant (duckweed)>1.0 (EC10)
Anti-bacterial (macrolide antibiotic)LincomycinPlant (duckweed)>1.0 (EC10)
RoxithromycinPlant (duckweed)>1.0 (EC10)
Anti-bacterial (macrolide antibiotic)Tylosin >1.0 (EC10)
Anti-bacterial (sulfonamide)SulfadimethoxinePlant (duckweed) (duckweed)>0.044 (EC10)
SulfamethazinePlant (duckweed)>1.0 (EC10)
PlantPlant (duckweed)0.011 (EC10)
2.33 (EC50)
Sulfamethoxazole 2.33 (EC50)
Sulfachlorpyridazine
Anti-bacterial (tetracycline)ChlortetracyclinePlant (duckweed)0.036 (EC10)
DoxycyclinePlant (duckweed)0.055 (EC10)
OxytetracyclinePlant (duckweed)0.788 (EC10)
TetracyclinePlant (duckweed)4.92 (EC50)
Plant (duckweed)0.23 (EC10)
Anti-depressant Plant (duckweed)>1.0 (EC10)
FluvoxetineSertralinePlant (duckweed)>1.0 (EC10)
Anti-diabetic (biguanide)MetforminAlga (green)>320.0 (EC50)
Plant (duckweed)110.0 (EC50)
Anti-epilepticCarbamazepineAlga (green)74.0 (EC50)
Plant (duckweed)>1.0 (EC10)
Plant (duckweed)25.5 (EC50)
Anti-hyperlipidemicAtorvastatinPlant (duckweed)0.085 (EC10)
Anti-hyperlipoproteinemicClofibric acidAlga5.4 (EC10)
Alga (green)115.0 (EC50)
Plant (duckweed)12.5 (EC50)
Anti-hypertensiveCaptroprilAlga (green)168.0 (EC50)
Plant (duckweed)25.0 (EC50)
Anti-protozoalMetronidazoleAlga (green)2.03 (EC10)
Alga (green)19.0 (EC10)
Bone resorption inhibitorTiludronateAlga (cyanobacteria)13.3 (EC50)
Alga (green)36.6 (EC50)
Nicotine metaboliteCotininePlant (duckweed)>1.0 (EC10)
Non-steroid anti-inflammatory drugAcetaminophen (paracetamol)Plant (duckweed)>1.0 (EC10)
DiclofenacAlga (green)72.0 (EC50)
Plant (duckweed)7.5 (EC50)
IbuprofenAlga (green)315.0 (EC50)
Plant (duckweed)>1.0 (EC10)
NaproxenPlant (duckweed)22.0 (EC50)
Alga (green)>320.0 (EC50)
Plant (duckweed)24.2 (EC50)
EstrogenEthinylestradiolAlga0.054 (EC10)
β-Adrenergic receptor blockerMetoprololAlga (green)7.3 (EC50)
Plant (duckweed)>320.0 (EC50)
PropranololAlga (green)5.8 (EC50)
Plant (duckweed)114.0 (EC50)
* reproduced from [29] with the permission of Elsevier, license 4890980598709, from 16 August 2020.
Table 3. The toxic effects of typical EPs in the environment [62] *.
Table 3. The toxic effects of typical EPs in the environment [62] *.
Emerging PollutantEcology EffectHuman Health Effect
Engineered nanoparticlesToxicity in plants, fish, earthworm, bacteria (growth, mortality, reproduction, gene expression)Cytotoxicity, oxidative stress, inflammatory effects, in lungs, genotoxicity, carcinogenic effects, granulomas, thickening of alveolar wall and augmented intestinal collagen staining
Endocrine disruptorsToxic to wildlife, humanAlter reproductively relevant, sexually dimorphic neuroendocrine system, alter endogenous steroid levels, etc., diabetes, problems in the cardiovascular system, abnormal neural behaviors and linked to obesity
Ionic liquidsInhibitory effects on a variety of bacteria and fungi, influencing the growth rate of algae, toxic to invertebrates, fish and frogsAdverse effects on neuronal process, cytotoxicity
Perfluorinated compoundsBioaccumulation in fish and fishery productsAccumulate primarily in the serum, kidney and liver, potentially adverse effects on developmental, reproductive systems and other damaging outcomes
* reproduced from [62] with the permission of Elsevier, license 4912101420021, from 18 September 2020.
Table 4. Characterization of risks based on the frequency-based risk quotient.
Table 4. Characterization of risks based on the frequency-based risk quotient.
Range of RQf ValuesRisk Characterization
RQf ≥ 1High environmental risk
1 > RQf ≥ 0.1Moderate environmental risk
0.1 > RQf ≥ 0.01Small-scale adverse effect (endurable risk)
0.01 > RQf > 0Limited (negligible risk)
RQf = 0No risk (safe)
Table 5. Advantages and challenges of different technologies in the removal of emerging pollutants [100] *.
Table 5. Advantages and challenges of different technologies in the removal of emerging pollutants [100] *.
Treatment ProcessAdvantagesChallenges
Conventional
Biological activated carbonA wide range of EPs removal from wastewaterRelatively high cost in operation and maintenance
Removal of residual disinfection/oxidation productsRegeneration and disposal of high sludge amounts
Not generating toxic active productsProcessing of sludge can increase total cost by 50–60%
Microalgae reactor Resource recovery of algal biomass, used as fertilizerRemoval efficiencies affected by cold season
High quality effluent and no acute toxicity risk associated with EPsEPs cannot be degraded properly
Activated sludgeLower capital and operational costs than AOPsLow efficiencies for pharmaceuticals and beta blockers
More environmentally friendly than chlorinationLarge amount of sludge containing EPs
Unsuitable where Chemical Oxygen Demand (COD) levels are higher than 4000 mgL−1
Non-conventional
Constructed wetlandLow energy consumption and low operational and maintenance costsClogging, solids entrapment and sediments formation
High performance on removal of estrogens, pathogensBiofilm growth, chemical precipitation and seasonal dependent
Needs large area of lands and long retention time
MBREffective for the removal of biorecalcitrant EPsHigh energy consumption and fouling control of heat and mass transfer
Small footprintHigh aeration cost and roughness of membrane
Pharmaceutical pollutants have low efficiencies
Chemical process
CoagulationReduced turbidity arising from suspended inorganic and organic particlesIneffective micropollutants removal
Increased sedimentation rate through suspended solid particles formationLarge amount of sludge
Introduction of coagulant slats in the aqueous phase
OzonationStrong affinity to EPs in the presence of H2O2High energy consumption, formation of oxidative by-products
Selective oxidant favoring disinfection and sterilization propertiesInterference of radical scavengers
AOPsMajor ancillary effects on removal of EPs such as pharmaceuticals, personal care products (PCPs and pesticidesEnergy consumption issues, operational and maintenance cost
Short degradation rateFormation of toxic disinfection by-products
Interference of radical scavengers
Fenton and photo-FentonDegradation and mineralization of EPsDecrease in OH* forming chloro and sulfato-Fe(III) complexes or due to scavenge of OH* forming Cl2 * and SO4 *- in the presence of chloride and sulphate ions
Photocatalysis (TiO2)Sunlight can be used by avoiding UV light
Degrading persistent organic compoundsDifficult to treat large volume of wastewater
High reaction rates upon using catalystCost associated with artificial UV lamps and electricity
Low price and chemical stability of TiO2 catalyst and easier recoverySeparation and reuse of photocatalytic particles from slurry suspension
Physical process
Micro- or ultra-filtrationCan remove EPs and pathogensNot fully effective in removing some EPs as pore sizes vary from 100 to 1000 times, larger than the micropollutants
NanofiltrationUseful for treating saline water and wastewater treatment plants (WWTP) influentsHigh energy demand, membrane fouling and disposal issue
Can remove dye stuff and pesticidesLimited application in pharmaceuticals removal
Reverse osmosisUseful for treating saline water and WWTP influentsHigh energy demand, membrane fouling and disposal issue
Can remove PCPs, endocrine disrupting compounds (EDCs) and pharmaceuticalsCorrosive nature of finished water and lower pharmaceutical removal
* reproduced from [100] with Elsevier permission, license no. 4912441171076 of 19 September 2020.
Table 6. Efficiency of EPs removal in constructed wetlands (CWs).
Table 6. Efficiency of EPs removal in constructed wetlands (CWs).
Emerging PollutantConstructed WetlandsRemoval Efficiency (%)Operating Scale *References
IbuprofenHSSF-CW74–99 [103]
SF-CW45–95 [105]
FW-SW27–74 (winter)
6–96 (summer)
[106,107]
SSF-CW71 [108]
VSSF-CW55–99 [103]
SF-CW95–96Full scale[109]
SSF-CW71–79.7 [110]
SF-CW50–100 [101]
KetoprofenFW-SSF47–81 [105]
FW-SF11–50 (winter) [106,107]
SF-CW47–91 [103]
HSSF-CW10–90 [103]
NaproxenFW-SSF58–81 [105]
FW-SF27–66 (winter)
27–83 (summer)
[106,107]
SF-CW75–76 [103]
HSSF-CW76–97 [103]
VSSF-CW69–96 [103]
SSF-CW85 [108]
SF-CW52–92 [101]
SF-CW82.8–91.3 [110]
CarbamazepineFW-SSF35–71 [105]
SSF-CW16 [108]
SF-CW32–37 [111]
SSF-CW26.7–28.4 [110]
GalaxolideFW-SSF67–82 [105]
SF-CW88–90 [111]
SF-CW87 [112]
DiclofenacFW-SF17–26 (winter)
36–52 (summer)
Full scale[106,107]
SF-CW20–50 [103]
HSSF-CW24–93 [103]
VSSF-CW53–73 [103]
SF-CW73–96 [111]
SF-CW85 [109]
TramadolSF-CW12–26 [113]
HSSF-CW54–85 [103]
ParacetamolHSSF-CW95–100 [103]
HSSF-CWs>90 [114]
hybrid-CWs>95–99 [101]
AcetaminophenHSSF-CWs>90 [114]
OxybenzoneHSSF-CWs>97 [115]
AtenololHSSF-CWs58–99 [103]
SF-CWs27–53 [113]
HSSF-CWs48 [48]
MetoprololHSSF-CWs60–93 [103]
SF-CWs3–30 [113]
HSSF-CWs11 [48]
FurosemideHSSF-CWs80–96 [103]
HSSF-CWs35–71 [48,115]
TriclosanHSSF-CWs62–91 [103]
Reclamation pond-wetland74–93Full scale[116]
ChlorpyrifosMecopropSSF-CWs>96 [117]
SF-CWs79–91 [111]
SSF-CWs22 [108]
* only full scale is mentioned (where available), the rest of results are from laboratory and pilot scales SF-CW: surface-flow constructed wetland; FW-SSF: free water subsurface flow; FW-SF: free water surface flow; HSSF-CW: horizontal subsurface flow constructed wetland; VSSF-CW: vertical subsurface flow constructed wetland.
Table 7. Efficiency of EPs removal in AnMBR system.
Table 7. Efficiency of EPs removal in AnMBR system.
Emerging PollutantRemoval Efficiency (%)References
Bisphenol A31.5[134]
Androsterone98[134]
Linuron88.1[135]
Diazinnon80[136]
Triclosan90.2[134]
Ceftriaxone47.7[137]
Ampicillin34.6[137]
Amoxicillin73.2[137]
Table 8. EPs removal efficiency by biosorption-based systems [100] *.
Table 8. EPs removal efficiency by biosorption-based systems [100] *.
CategoryEPsBiosorption
Live (Fungus)Inactivated (Fungus)
Influent (μgL−1)Removal (%)Influent (μgL−1)Removal (%)
EDCs **Androstenedione
Androsterone
E150725031.5
E25060.55029.5
EE250621.50; 2.101.38; 2.76
E3504.55013
17β-Estradiol-17-acetate50795084
Bisphenol A50651.50; 2.101.24; 2.59
4-tert-butylphenol50335010.5
nonylphenol
Octylphenol
4-tert-octylphenol 90 82.5
4-n-nonylphenol
Testosterone
Dihydrotesterone
PesticidesAtrazine5018509
Dicamba
Fenoprop5001500
2,4-D
Mecoprop
Pentachlorophenol50635096
Beta-blockersTriclosan5078.55097
Atendol
Metoprolol
Nadolol
Propranolol
Sotalol
Salbutamol
PCPs **Benzophenone50401.50; 2.101.11.5; 2.83
Oxybenzene5054.5 59.5
Propyl parabene
Salicylic acid5068500
Antiplatelet agentsCodeine
Paracetamol
Anxiety relieversClopidogrel
Hydrocodone
AntagonistsDiazepam
Pain-relieversFamotidine
GastroesophagealLorazepam
Ranitidine
AnalgesicsCarbamazepine50015007
Citalopram
Diclofenac50975043
Ibuprofen501005027
Lorazepan
Metronidazole
Naprox501005017
Primidone50125027
Trazodone
Anti-depressantsAmitriptyline50055009
AnticonvulsantsKetoprofen50225011
Lipid regulatorsClofibric acid50065018
Gemifibrozil501005057.5
DiureticsHydrochlorothiazide
Furosemide
AntibioticsAzithromycin
Clarithromycin
Erythromycin
Ofloxacin
Sulfamethaxazole
Trimethoprim
Anti-inflammatoryAcetaminophen
StimulantCaffeine
* reproduced from [100] with Elsevier permission, License 4912441171076 of 19 September 2020. ** EDCs—endocrine disrupting chemicals, PCPs—personal care products.
Table 9. Comparison of removal efficiency of some processes involving biological technologies for the removal of several emerging pollutants.
Table 9. Comparison of removal efficiency of some processes involving biological technologies for the removal of several emerging pollutants.
Emerging PollutantRemoval Efficiency, %
HSSF-CW [120]Lab-Scale MBR
[143]
Biological Filtration
[111]
Biosorption [144]
Live
Fungus
Inactivated
Fungus
Diclofenac5558939743
Carbamazepine2613517
Naproxen91-7210017
Atrazine-9-189
Table 10. Efficiency of EP removal achieved by hybrid systems.
Table 10. Efficiency of EP removal achieved by hybrid systems.
Emerging PollutantFirst StepSecond StepRemoval Efficiency, %Reference
PropanololMembrane Biological ReactorReverse Osmosis99.5[145,146]
DiclofenacMembrane Biological ReactorReverse Osmosis95[146]
Activated sludge + UltrafiltrationUltrasounds99.7[146]
Membrane Biological ReactorElectrochemical Process75[147]
IbuprofenBiological Activated CarbonUltrafiltration45[148]
Bisphenol AFlocculants + Activated SludgeUltrafiltration95[149]
SulfonamidesMembrane Biological ReactorReverse Osmosis>93[146]
Salicylic acidMembrane Biological ReactorUltrafiltration92.6[144]
Membrane Biological ReactorNanofiltration97.3[144]
Membrane Biological ReactorReverse Osmosis95.4[144]
Activated sludgeUltrafiltration + Reverse Osmosis99.9[144]
ClarithromycinMembrane Biological ReactorReverse Osmosis99.5[145]
OzonationUltrasound94.3[150]
OzonationUltrasound100[150]
Activated sludgeUltrafiltration + Reverse Osmosis95.9[146]
AtrazineBiological Activated CarbonOzonation70[151]
PentachlorophenolMembrane Biological ReactorReverse Osmosis99[144]
Membrane Biological ReactorUV Oxidation99[144]
2,4-DBiological Activated CarbonOzonation92.9[151]
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Vasilachi, I.C.; Asiminicesei, D.M.; Fertu, D.I.; Gavrilescu, M. Occurrence and Fate of Emerging Pollutants in Water Environment and Options for Their Removal. Water 2021, 13, 181. https://doi.org/10.3390/w13020181

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Vasilachi IC, Asiminicesei DM, Fertu DI, Gavrilescu M. Occurrence and Fate of Emerging Pollutants in Water Environment and Options for Their Removal. Water. 2021; 13(2):181. https://doi.org/10.3390/w13020181

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Vasilachi, Ionela Cătălina, Dana Mihaela Asiminicesei, Daniela Ionela Fertu, and Maria Gavrilescu. 2021. "Occurrence and Fate of Emerging Pollutants in Water Environment and Options for Their Removal" Water 13, no. 2: 181. https://doi.org/10.3390/w13020181

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