key: cord-1038221-w97ak0ve authors: Ortúzar, Maite; Esterhuizen, Maranda; Olicón-Hernández, Darío Rafael; González-López, Jesús; Aranda, Elisabet title: Pharmaceutical Pollution in Aquatic Environments: A Concise Review of Environmental Impacts and Bioremediation Systems date: 2022-04-26 journal: Front Microbiol DOI: 10.3389/fmicb.2022.869332 sha: b97aa83bced77adacdd096e73e2d5fcc5b49ce74 doc_id: 1038221 cord_uid: w97ak0ve The presence of emerging contaminants in the environment, such as pharmaceuticals, is a growing global concern. The excessive use of medication globally, together with the recalcitrance of pharmaceuticals in traditional wastewater treatment systems, has caused these compounds to present a severe environmental problem. In recent years, the increase in their availability, access and use of drugs has caused concentrations in water bodies to rise substantially. Considered as emerging contaminants, pharmaceuticals represent a challenge in the field of environmental remediation; therefore, alternative add-on systems for traditional wastewater treatment plants are continuously being developed to mitigate their impact and reduce their effects on the environment and human health. In this review, we describe the current status and impact of pharmaceutical compounds as emerging contaminants, focusing on their presence in water bodies, and analyzing the development of bioremediation systems, especially mycoremediation, for the removal of these pharmaceutical compounds with a special focus on fungal technologies. The presence of emerging contaminants in the environment, such as pharmaceuticals, is a growing global concern. The excessive use of medication globally, together with the recalcitrance of pharmaceuticals in traditional wastewater treatment systems, has caused these compounds to present a severe environmental problem. In recent years, the increase in their availability, access and use of drugs has caused concentrations in water bodies to rise substantially. Considered as emerging contaminants, pharmaceuticals represent a challenge in the field of environmental remediation; therefore, alternative add-on systems for traditional wastewater treatment plants are continuously being developed to mitigate their impact and reduce their effects on the environment and human health. In this review, we describe the current status and impact of pharmaceutical compounds as emerging contaminants, focusing on their presence in water bodies, and analyzing the development of bioremediation systems, especially mycoremediation, for the removal of these pharmaceutical compounds with a special focus on fungal technologies. In recent decades, the production and consumption of pharmaceutical products have rapidly increased with the development of medicine. Approximately 3,000 compounds are used as pharmaceuticals, and the annual production quantity exceeds hundreds of tons (Carvalho and Santos, 2016; Grenni et al., 2018) . Anti-inflammatory drugs, antibiotics, and analgesics are the most common drugs used around the world. Consequently, the emergence of water-soluble and pharmacologically active organic micropollutants or pharmaceutical active compounds (PhACs) has gained much attention worldwide. Humans use a variety of these pharmaceuticals for their health in everyday life, but large quantities of these drugs are also used as veterinary medicine on farms around the world, to prevent and treat animal diseases and to increase economic benefits in intensive livestock (Blanco et al., 2017; Ekpeghere et al., 2017; Gros et al., 2019; Ramírez-Morales et al., 2021) . After ingestion, pharmaceuticals are excreted in urine and feces as active substances or metabolites (Sui et al., 2015; aus der Beek et al., 2016) . These pharmaceuticals are present in both influent and effluent wastewater but can also be found in surface water bodies, including freshwater ecosystems and marine environments, as well as in groundwater due to effluent leachates generated under recharge conditions (Deo, 2014; Furlong et al., 2017; Ojemaye and Petrik, 2018; Reis-Santos et al., 2018; Fekadu et al., 2019; Letsinger et al., 2019; Zainab et al., 2020) . The main concern is that conventional treatment plants are ineffective in removing some of these emerging contaminants (ECs), and new techniques are being sought and studied to achieve their total elimination, particularly advances in mycoremediation (Danner et al., 2019) . The importance of the study of pharmaceuticals lies in the massive increase in their consumption worldwide, as well as in the environmental repercussions that this entails, including their recalcitrance in aquatic and terrestrial ecosystems. In the contexts of wastewater and bioremediation, pharmaceutical compounds are considered as ECs due to the lack of regulation for their environmental disposal, as well as the lack of information regarding their long-term effects on the environment (Dhangar and Kumar, 2020; Valdez-Carrillo et al., 2020; Chaturvedi et al., 2021b; Rathi et al., 2021) , which remains unknown (Barber et al., 2015; Ahmed et al., 2017) . The fact that some drugs are marketed without medical prescription or pre-registration and, therefore, are widely consumed worldwide, meaning that they are widely distributed in the environment (Gil et al., 2017) , has contributed to this growing problem. Considering pharmaceuticals as ECs and the continual production of new PhACs, this review aims to comprehensively present the pharmaceuticals commonly detected in water, surface and groundwater and their adverse environmental effects. Advances in bioremediation technologies, which can be used as add-on treatments in wastewater treatment plants (WWTPs) to reduce unprocessed pharmaceuticals released via effluent into the environment, are presented and critically discussed with an emphasis on mycoremediation. Pharmaceutical compounds that reach water bodies, both surface water and groundwater, came from a number of different sources (Figure 1 ). The first of these is urban wastewater, which contains a high load of pharmaceuticals from human excrement, and also the inadequate disposal of expired or unused drugs due to the scarce control in their management. Another major source of pharmaceuticals is agricultural and livestock waste, especially the latter, since in large farms for intensive livestock, animals are often fed with feed supplemented containing drugs and excreta are often used in agriculture as soil amendments, reaching groundwater by leaching (Kim et al., 2008; Barrios-Estrada et al., 2018) . Effluents from the pharmaceutical industry are another important source, with high concentrations of pharmaceuticals being found due to discharges from factories in Asia, Europe and America, despite strict regulation of pharmaceutical production in Europe and the United States (Lin et al., 2008; Lin and Tsai, 2009; Phillips et al., 2010; Prasse et al., 2010; Sim et al., 2011; Cardoso et al., 2014) . These industries are obliged to carry out treatment before discharge into the general urban sewer network (Lindberg et al., 2004; Brown et al., 2006) . Pharmaceuticals found in high concentrations in wastewater include non-steroidal anti-inflammatory drugs (NSAIDs), β-blockers ad psychoactive compounds, analgesics, antibiotics, endocrine disruptors, antiretroviral drugs, and drugs to treat cancer (Roberts and Thomas, 2006; Gros et al., 2010; Lian et al., 2017) . These are the PhACs most commonly detected due to the analytical methods available and their resolution, although new methods for identifying these compounds are increasingly being developed (Pivetta et al., 2020; Zhang et al., 2020) . Table 1 shows the worldwide distribution of the drugs most commonly found in water (Supplementary Figure 1) . Non-steroidal anti-inflammatory drugs and analgesics are some of the most important groups of pharmaceutical products worldwide, with diverse chemical structures and similar therapeutic effects, having an estimated annual production of several hundred tons (Comber et al., 2018) . Large amounts of anti-inflammatory drugs are prescribed in human care, but they are often sold in much higher amounts without a prescription (Ternes, 2001) . NSAIDs and analgesics are often combined with antibiotics in veterinary medicine for problems such as pain, inflammation, fever, osteoarthritis and arthritis, and to reduce stress (Courtheyn et al., 2002; Bártíková et al., 2016) . However, these two types of pharmaceuticals have numerous adverse effects in humans, including gastrointestinal disturbances, ulceration, renal failure with increased risk of post-operative bleeding, asthma, and rare allergic reactions (Ben Maamar et al., 2017; Morelli et al., 2017; Borgeat et al., 2018; Hurtado-Gonzalez et al., 2021) . Approximately 35 million people use NSAIDs every day worldwide , and China increased its domestic production from 41,537 t in 2013 to 46,673 t in 2017 (Yan et al., 2021) . They are currently monitored in effluents worldwide to check these drug concentrations and several studies show that both NSAIDs and analgesics are commonly detected in water bodies (Balakrishna et al., 2017; Świacka et al., 2021) . In Cuernavaca (Mexico), high concentrations of naproxen (732-4,889 ng/L), acetaminophen (354-4,460 ng/L), and diclofenac (258-1,398 ng/L) have been detected in samples collected in different years, in the influent and effluent of a WWTP and in the surface waters of the Apatalco River (Rivera-Jaimes et al., 2018) . Furthermore, the drugs diclofenac (10,221 ng/L highest concentration detected) and acetaminophen (1234-2346 ng/L), among others, have been detected in effluents from the Red Sea (Saudi Arabia) (Ali et al., 2017) . On the other hand, in Brazil, ng/L), diclofenac (19.4 ng/L), and ibuprofen (326.1-2,094.4 ng/L) have been detected in the surface and bottom water samples from Santos Bay . Sweden (Hoje River), and China (Pearl, Hai, Liao and Yellow Rivers) (Peng et al., 2008 Valcárcel et al., 2011; López-Serna et al., 2013; Bilal et al., 2020) . Endocrine disruptors were defined in 2002 by the International Programme on Chemical Safety (IPCS) of the United Nations Environment Programme (UNEP) and by the World Health Organization (WHO) as "an exogenous substance or mixture that alters the function(s) of the endocrine system and consequently causes adverse health effects in an intact organism or population". Among the most common endocrine disruptors are pesticides, bisphenols and natural hormones (Gore et al., 2014; Tijani et al., 2016) . These substances are not removed from water by conventional treatment processes and are found in wastewater bodies in the order of nanograms to micrograms per liter (Andrade-Eiroa et al., 2016; Gröger et al., 2020; Li et al., 2020) . Antiretroviral drugs are frequently used to treat the human immunodeficiency virus (HIV), an epidemic that has developed worldwide and has its epicenter in South Africa (Tompsett, 2020) . As a result, millions of people have access to these drugs on a daily basis, with more than 40 different antiretroviral drugs being used for the treatment of HIV. These include abacavir, efavirenz, lamivudine, nevirapine, tenofovir, and zidovudine; many of which are used in combination (Russo et al., 2018; Mlunguza et al., 2020) . As a consequence of the increase in the rate of HIV infection over the years, there has been a significant increase in the production and consumption of antiretroviral drugs worldwide (Nannou et al., 2020; Reddy et al., 2021) . In addition, as consequence of the new pandemic coronavirus (COVID-19), antiretroviral drugs have also been used for the treatment of SARS-CoV-2. In some countries, such as China and Japan, clinical trials have been conducted to test the efficiency of using HIV drugs to treat COVID-19 (Reddy et al., 2021) . At the moment, a scarcity of studies has dealt with this new issue. However, some studies have started to show a relevant problem that we will have in the very near future (Mupatsi, 2020) . In the coming decades, annual cancer cases are expected to increase to more than 20 million, which means an exponential increase in anticancer drugs and their subsequent release into wastewater (Ferlay et al., 2013) . Most of these compounds are incompletely assimilated and metabolized by the human body, thus excreted in feces and urine. The most commonly administered anticancer drugs include cyclophosphamide, tamoxifen, ifosfamide and methotrexate, among others. These drugs have been detected in surface water, WWTP effluents and influents, and hospital effluents. Detected concentrations of cyclophosphamide range from 0.05 to 22,100 ng/L, ifosfamide 0.14-86,200 ng/L, methotrexate 1.6-4,756 ng/L, and tamoxifen 0.01-740 ng/L (Nassour et al., 2020) . Several studies have detected these drugs in water masses, confirming that current water treatment systems fail to degrade them (Verlicchi et al., 2010; Cristóvão et al., 2019) . Different international agencies have developed protocols for the handling and storing of pharmaceuticals to reduce their harmful effect on the environment (Bernabeu-Martínez et al., 2018) . One of the main concerns is that these drugs may suffer biomagnification (Yadav et al., 2021) . Since almost all drugs are not completely metabolized by organisms (usually a small fraction of the active site of drug metabolic enzymes are occupied, the half-life of drugs are limited, and drugs are administrated in higher amounts than necessary to increase efficiency) (Coleman, 2020) , the compounds that can cause the most damage once they are excreted and reached wastewater are PhACs. They are also called active pharmaceutical ingredients or APIs and metabolites, referring to the molecules resulting from these original compounds due to structural changes that take place in organisms. In addition, the resulting molecules are also subject to changes in the environment (such as oxidation, photolysis, or biotransformation). These changes can occur through both biotic and abiotic processes. Thus, many pharmaceutical products are biotransformed by microorganisms (Kümmerer, 2009; Wu et al., 2012) . Ecotoxicologists are increasingly concerned about the worldwide detection of pharmaceutical residues in aquatic environments since their long-term toxic effects are being increasingly studied. However, it is challenging to know these effects because of the short time period these substances have been present in the environment (Nantaba et al., 2020; Ramírez-Morales et al., 2020; Gani et al., 2021) . Different studies analyzed the microbiome of wastewater where, in the case of hospitals, an abundance of anaerobes related to pathogenic threats such as Bifidobacteriales, Bacteroidales, and Clostridiales was found (Buelow et al., 2018; Ogwugwa et al., 2021; Palanisamy et al., 2021) . They also noted that compared to other locations, hospital wastewater contains microorganisms with higher relative levels of antimicrobial and antibiotic resistance genes (Buelow et al., 2018) . The mycobiome of hospital wastewater has also been analyzed, indicating the presence of different opportunistic phyla such as Mycosphaerella, Drechslera, Candida, or Cyphellophora (Olicón-Hernández et al., 2021), whose risk that they may acquire resistance to antibiotics is of great concern and may have great repercussions for global health. β-blockers are a group of pharmaceuticals that are commonly detected in the environment. This is because many wastewater plants are not adapted to remove these micropollutants. Detected concentrations vary from 3 to 6,167 ng/L, which are already sufficient to cause neurotoxic and reproductive disorders in living organisms (Godlewska et al., 2021) . Bisoprolol causes immobilization in Daphnia similis (Godoy et al., 2019) and mortality in fish and green algae (Fonseca et al., 2021) . Propranolol causes growth and development problems in algae such as Synechococcus leopolensis and Cyclotella meneghiniana (Ferrari et al., 2004) , mortality in crustacea (Ceriodaphnia dubia) (Huggett et al., 2002) , and embryonic development problems in Danio rerio (Bittner et al., 2018) . Psychoactive substances affect thought, emotion, will and behavior (Jin et al., 2022) . According to their pharmacological properties, psychoactive substances (including legal and illegal drugs) are opioids, cannabis, central nervous system depressants, central nervous system stimulants, hallucinogens, and tobacco (Schlüsener et al., 2015; Tanoue et al., 2019) . These substances have different effects on humans, such as analgesia, anesthesia, inability to concentrate, excitement, anxiety, and mania. Jin et al. (2022) indicated that ecological risk assessment is a crucial part of research on psychoactive substances, as the current relevant literature is scarce. Due to the biological activity of such substances, there is a need for rapid improvement of risk assessment, including acute, cone and developmental toxicity, neurotoxicity, and endocrine-disrupting effects, among others, as well as the development of remediation technologies. Pharmaceuticals are known to have biological effects on living organisms, but there is not enough information currently available to assess the possible ecotoxicological impacts. Below are some of the toxic and ecological risks of NSAIDs and analgesics, according to various studies and summarized in Table 2 : (I) population declines of Gyps vultures in Asia due to high diclofenac concentration (Cuthbert et al., 2007) ; (II) diclofenac impairs prostate gland synthesis and damage to the gills, liver, and kidneys of Salmo trutta f. fario (Hoeger et al., 2005) ; (III) histological alterations of the kidneys and gills, cytological alterations of the liver, kidneys, and gills, and deterioration of ionic regulation in Oncorhynchus mykiss Triebskorn et al., 2004; Gravel et al., 2009 ); (IV) ibuprofen, diclofenac, naproxen and ketoprofen inhibits CYP2M in Cyprinus carpio (Thibaut et al., 2006) ; (V) ibuprofen change breeding pattern of Oryzias latipes (Flippin et al., 2007) ; (VI) ibuprofen, diclofenac, and acetaminophen cause cardiovascular abnormalities, hatch and motor behavior and interruption of oocyte maturation/ovulation in D. rerio (David and Pancharatna, 2009; Lister and Van Der Kraak, 2009; Xia et al., 2017) ; (VII) diclofenac alters estrogenic activity, response of specific tissue biomarkers, decreased superoxide dismutase, and glutathione reductase activities in gills, and high catalase activity and levels of lipid peroxidation in the digestive gland in Mytilus galloprovincialis (Gonzalez-Rey and Bebianno, 2014). As can be inferred, high concentrations of NSAIDs and analgesics in the environment, such as acetylsalicylic acid, acetaminophen, diclofenac, ibuprofen, and naproxen, cause serious environmental problems (Parolini, 2020) . In addition to fish, the main organisms affected are invertebrates, including arthropods, mollusks, cnidarians and rotifers (Parolini, 2020) . NSAIDs also affect the plant growth of species such as Pisum sativum and Vigna unguiculata (Svobodníková et al., 2020; Wijaya et al., 2020; Due to the continuous introduction of antibiotics into the environment, aquatic and soil organisms are chronically exposed to these drugs (Gothwal and Shashidhar, 2015; Bengtsson-Palme and Larsson, 2016) . Moreover, because they are active at very low concentrations, they have a toxic effect on organisms, and there is a synergistic effect when they are present together with other drugs and/or xenobiotic compounds (González-Pleiter et al., 2013) . Algae and aquatic plants are severely affected by antibiotics (Brain et al., 2008; Brausch et al., 2012) . Many of them have been found to be photosynthesis inhibitors, as they can block the electron chain of photosystems II and increase oxidative stress (Nie et al., 2013) . However, microorganisms, including bacteria and fungi, are developing resistance to antibacterial substances due to exposure to low concentrations over several generations (Kollef et al., 2017; Willyard, 2017; García et al., 2020; Wang et al., 2020) . Invertebrates such as Hydra attenuata and crustaceans such as Artemia salina, Daphnia magna, and Ceriodaphnia dubia show relatively low acute toxicity in the presence of antibiotics (Wollenberger et al., 2000; Kołodziejska et al., 2013; Minguez et al., 2016) . On the other hand, in fish, acute toxicity was only found at high concentrations, but there were cases in which no toxicity was observed (Santos et al., 2010; Brausch et al., 2012; Minguez et al., 2016 ; Table 2 ). The other major problem is antibiotic resistance genes (ARGs), which are genes that confer antibiotic resistance to bacteria, and can proliferate through the reproduction of antibiotic-resistant bacteria from the host or through horizontal gene transfer, are present in the environment, and thus considered as emerging environmental contaminants (Nadimpalli et al., 2020; Hu et al., 2021) . Although treated wastewater contains significantly lower amounts of ARGs than untreated wastewater, several studies show that aquatic environments downstream of treatment plants can increase the amounts of ARGs because they are carried by mobile genetic elements, such as conjugative plasmids, integrative and conjugative elements, and transposons and integrons (Amos et al., 2018; Freeman et al., 2018; Jäger et al., 2018; Karkman et al., 2018; Liu et al., 2018) . These effective carriers of ARGs could confer multi-resistance. One of the most detected genetic components in both effluents and aquatic environments is Class 1 integron-integrase gene (intI1) associated more frequently with ARGs and involved in horizontal gene transfer (Gillings et al., 2015; Cacace et al., 2019) . Endocrine disruptors seriously affect both human and animal health, as they act directly on the endocrine system and block or mimic the natural hormones responsible for the functioning of some organs (Vieira et al., 2020) . These substances have been studied extensively in humans, nevertheless, much less in the environment. It is known that they can alter the reproductive system, cause Alzheimer's disease, thyroid problems, obesity and/or cancer (prostate, breast or endometrium cancer), among others (Heindel et al., 2015; Forte et al., 2016 Forte et al., , 2019 Braun, 2017; Nadal et al., 2017; Marotta et al., 2019) . In natural ecosystems, the reproductive system is also affected, as well as the levels of vitellogenin and hatchability and thus feminization with the consequent threat to the preservation of biodiversity (Vieira et al., 2020; Akhbarizadeh et al., 2021; In contrast to other pharmaceuticals, antiretrovirals, despite being abundant in wastewater, are poorly monitored, although some studies report on them (Ngumba et al., 2016; Abafe et al., 2018; Rimayi et al., 2018; Mosekiemang et al., 2019; Mtolo et al., 2019) . These drugs could pass through treated wastewater in WWTPs, reach drinking water sources, and cause serious ecotoxicological problems for human health (Hawkins, 2010; Ncube et al., 2018; Mlunguza et al., 2020) . Currently, the greatest concern is that resistant strains of HIV can be created in the body through exposure to water contaminated with these drugs (Daouk et al., 2015; Ncube et al., 2018; Although anticancer drugs are designed to eliminate fastgrowing cells, such as tumor cells, many of these drugs are not selective (Chari, 2008) . This means that in addition to attacking healthy cells, they can cause cytotoxic, genotoxic, mutagenic, and teratogenic effects, i.e., cause adverse effects in any eukaryotic organism (Kümmerer et al., 2000; Johnson et al., 2008) . For this reason, anticancer drugs are considered to be of great environmental concern, and especially the groups at greatest risk are children, pregnant women, and the elderly (Rowney et al., 2009) . It has been shown that chronic exposure of two generations of D. rerio to anticancer drugs caused histopathological changes in the liver and kidney and impaired the integrity of their DNA, introducing massive changes in the Table 2 ). Residues of pharmaceuticals in the environment typically occur as complex mixtures and even if the concentrations of an individual compound are low, the "cocktail effect" could be of significant ecotoxicological importance (Heath et al., 2016) . To date, many works have focused on the study of individual organisms and analyzed a single drug or several drugs as a whole, but there are no works studying the impact of drugs on several populations simultaneously. This would provide essential information on ecotoxicity and the "domino effect" that affects individuals in a trophic chain since, in addition to bioaccumulation, the chain could be broken because a drug lethally affects a group of individuals. Improving technologies for drug elimination from wastewater is an important task since pharmaceuticals have been detected in effluent from WWTPs and consequently surface water, groundwater, and drinking water globally (Bartolo et al., 2021) . Although the pharmaceuticals are found in concentrations ranging from the nanogram to microgram per liter, which is too low to cause acute toxicity, they are biologically active compounds that have the potential for chronic toxicity, bioaccumulation, and biomagnification (Ruan et al., 2020) . Additionally, microplastics have been shown to serve as vectors for pharmaceuticals (Santos et al., 2021) , thus increasing the exposure potential. Because of incomplete elimination during conventional wastewater treatment (Reyes et al., 2021) and the potential risk posed to the environment, as discussed above, there has been pronounced interest in developing alternative treatments in recent years, specifically the biological transformation of these pollutants as a green technology (Domaradzka et al., 2015) . The future inclusion of bioremediation technologies in traditional WWTP treatments is progressive as it will result in the detoxification of hazardous substances, it is less disruptive to the environment than harsh oxidative chemicals, and more cost-efficient. With perseverance, research into optimization could result in the complete eradication of target pollutants, rooting out release into the environment. The wastewaters containing PhACs and their metabolites reaching WWTPs are commonly treated via purification systems. The potential of drug remediation via biological treatment utilizing microbes has been demonstrated (Kebede et al., 2018) . Biological systems are often used in conjunction with advanced treatments and combined with conventional activated sludge (CAS) systems due to limitations associated with the process (Crini and Lichtfouse, 2019) . Advanced biological treatments include modified CAS, aerobic granular systems, moving bed bioreactors (MBBRs), anammox systems, and membrane bioreactors (MBRs) (Grassi et al., 2012) . However, some of these processes, such as MBRs, could result in the generation of biosolids or sewage sludge as byproducts of required maintenance. Sewage sludge, after different stabilization processes such as thermophilic anaerobic digestion, continues onto different processes, such as composting, which could facilitate the transfer of PhACs and their metabolites into various trophic levels of the food web when used as a soil amendment (Marcoux et al., 2013) . Bioremediation, utilizing native microbial monocultures or consortia or bioaugmentation, has been used for decades as a sustainable technology to manage anthropogenic pollution (Ahumada-Rudolph et al., 2021) . The advantages of bioremediation include less input of hazardous chemicals, energy, and time, and it is cheap relative to other technologies (Azubuike et al., 2016) . The major benefit of bioremediation is that the pollutant is chemically transformed and not only shifted from one environment to another (Mashi, 2013) . However, a significant criticism of bioremediation has been that the remediation speed does not meet the requirements for the treatment capacity. Nonetheless, considering the benefits of the approach, attempts on optimizing the efficiency and decreasing retention times are being made and are reviewed below for mycoremediation. Developments in phyto-and phycoremediation of pharmaceuticals have been reported and recently reviewed (Vilvert et al., 2017; Rao et al., 2019; Kaloudas et al., 2021; Kurade et al., 2021) and thus, not included here. Bacterial remediation has been reviewed to some extent (Shah and Shah, 2020) , and, therefore, a brief overview of previously undiscussed advances are included here alongside mycoremediation. Bacterial communities have the ability to degrade and mineralize many xenobiotic compounds and have thus been used for centuries in wastewater-activated sludge (Xu et al., 2018) . Bioremediation technologies have been advanced by studies elucidating the importance of facilitating biofilm growth in achieving maximum efficiency and community stability and survival (Edwards and Kjellerup, 2013) . The majority of the available literature on bacterial remediation has focused on the aerobic degradation of pharmaceuticals by individual bacteria or consortia in which oxygenases are reported to be involved (Ferreira et al., 2018) . Activated sludge, in which an uncharacterized bacterial consortium in suspension is responsible for the remediation, is one of the most widely used biological methods to treat pharmaceutical wastewater at a large scale (Bis et al., 2019) . However, due to operational issues associated with the development of large amounts of sludge, research has been invested in developing bespoke bacterial consortia for remediation, including microalgae and bacterialmicroalgae consortia (Mamta et al., 2020) . In the environment, fungi are excellent decomposers through the nonspecific nature of enzymes, both intracellular and extracellularly secreted, which exhibit significant capabilities to degrade organic material (Rouches et al., 2016) . More specifically, the ligninolytic (including peroxidases and laccases) and cytochrome P450 systems have been proven to be involved in the exceptional capacity of white-rot fungi to degrade recalcitrant pollutants (Park and Choi, 2020) . The nonspecific nature of these enzymes also makes them an ideal approach to deal with the diverse chemical structures of the many classes of pharmaceuticals. Many fungal species are also hyperaccumulators, capable of absorbing and bioaccumulating xenobiotics from their environment, as demonstrated by the ability of mushrooms (Braeuer et al., 2020) . Furthermore, fungi are known for their capacities to adapt to severe environmental constraints (Jiao and Lu, 2020) , making them more tolerant to environmental changes than other bioremediation organisms. Thus, mycoremediation, which results in the reduced toxicity of wastewater (Jelic et al., 2012; Akhtar and Mannan, 2020) , offers a comparatively cost-effective, eco-friendly, and effective approach to pollution remediation. Macromycetes, aka mushrooms or polypores, were previously proven efficient in remediating various pharmaceuticals (Migliore et al., 2012; Cruz-Morató et al., 2014) , including β-blockers and psychoactive drugs, anti-inflammatory drugs, antibiotics and hormones (Table 3) . Mostly, investigations into the efficiency of fungi to remediate pharmaceuticals have been performed in flask batch experiments with white-rot fungi, especially Trametes versicolor, which exhibited impressive capacities for eliminating a vast range of pharmaceuticals. In bioreactors-based studies, T. versicolor was equally efficient, able to degrade various pharmaceuticals, including codeine, diazepam, carbamazepine, and metoprolol (Asif et al., 2017) . The role of redox-mediators has also been extensively studied in improving the performance of laccase-based treatments (Ashe et al., 2016; Shao et al., 2019) , including the treatment of pharmaceuticals Vasiliadou et al., 2019) . Studies employing filamentous micromycetes have shown potential for pharmaceutical remediation from wastewaters as reviewed by Olicón-Hernández et al. (2017) but are limited compared to the literature on macromycetes ( Table 3) . The efficiency of bacteria and fungi to remediate different classes of pharmaceuticals is discussed in more detail below. Carbamazepine, which is not adequately eliminated via standard wastewater treatments and is thus frequently detected in the environment (Ekpeghere et al., 2018) , has been reported to be degraded by the macromycete T. versicolor. By employing T. versicolor, Jelic et al. (2012) achieved 94% degradation of carbamazepine (9 mg/L) after six days in flask experiments. With a reduced concentration (50 µg/L), Jelic et al. (2012) reported a lower remediation percentage of 61% achieved in seven days. The same group evaluated the fungus's remediation efficiency of carbamazepine in an air pulsed fluidized bed bioreactor operated in batch and continuous mode. In batch mode, 96% of the drug was eliminated after 2 days, with higher efficiency achieved in the bioreactor than in flasks explained by glucose addition, pH management and air supplementation. In continuous mode, carbamazepine was reduced by 54% in the outflow compared to the inflow concentration of 200 µg/L (Jelic et al., 2012) . With Pleurotus ostreatus, another whiterot fungus, 68% carbamazepine was degraded in liquid culture after seven days with no further degradation after this time (Buchicchio et al., 2016) . The filamentous fungus Trichoderma harzianum was able to degrade 72% of environmentally detected concentrations of carbamazepine (4 µg/L) (Buchicchio et al., 2016) , which was superior compared to the polypore P. ostreatus. In a non-sterile bioreactor, Phanerochaete chrysosporium was able to degrade up to 80% of 5 mg/L carbamazepine when supplied with a diluted synthetic feed (Zhang and Geißen, 2012) . In a fedbatch stirred bioreactor, P. chrysosporium removed yo to 60% carbamazepine (0.5 mg/L); however, it was unable to degrade diazepam (0.25-0.5 mg/L) (Rodarte-Morales et al., 2012a). In a fixed bed reactor, where the pellets of P. chrysoporium were immobilized in polyurethane, the remediation efficiency of carbamazepine and diazepam was significantly improved (Rodarte-Morales et al., 2012b) . Even though nearly complete remediation of some betablockers and psychoactive drugs could be achieved in flask and lab bioreactor scale experiments, large or even pilot scale studies are needed to comprehensively evaluate the effect of upscaling on the remediation efficiency and the costeffectiveness of using fungi for these drugs as an add-on treatment in WWTPs. Bioremediation using bacterial monocultures for the treatment of NSAIDs has not to date been successful (Wojcieszyńska et al., 2014) . Some studies have shown the elimination of NSAIDs by bacterial consortia in WWTPs. One study showed that eliminating acetaminophen in an MBR was mainly associated with heterotrophic bacteria. They concluded that using a microbial consortium in an MBR could be complimentary for post-treating effluents from treatment plants containing pharmaceutical products (De Gusseme et al., 2011) . However, as seen with the consortia in CAS treatments, which are unidentified and often change in conjunction with the wastewater being treated, consortia in bioreactors may also change, resulting in decreased efficiency. To further explore the use of bacterial consortia in bioreactors, long-term studies need to be conducted on-site in WWTPs to evaluate the composition and stability of the bacterial assemblage, and it should be modeled how shifts could influence remediation. In terms of mycoremediation, T. versicolor has shown very promising results in the remediation of NSAIDs (Asif et al., 2017; Tińma et al., 2021) . In a continuous MBR (with a hydraulic retention time of one day), T. versicolor eliminated 55% of diclofenac added at concentrations ranging from 0.3 to 1.5 mg/L . Another fungus that demonstrated the potential to degrade anti-inflammatory drugs is the edible fungus Lentinula edodes (shiitake mushroom). The degradation products of piroxicam produced by L. edodes degradation has already been described ; however, the remediation percentage was not reported. Penicillium oxalicum was capable of totally degrading diclofenac in 24 h, starting from an initial concentration of 29.6 mg/L (100 µM) (Olicón-Hernández et al., 2019) . For Mucor hiemalis f. irnsingii (DSM 14200; Zygomycota), a strain isolated from a groundwater source in Germany, the diclofenac (10-50 µg/L) removal percentages ranged between 90 and 97% after 6 days . The same micromycete was also employed for the remediation of acetaminophen. After 24 h of exposure to environmentally relevant concentrations of acetaminophen (up to 20 µg/L), M. hiemalis was able to degrade up to 50% (Esterhuizen-Londt et al., 2016b,a) . However, after 24 h, diclofenac remediation halted; nevertheless, pH maintenance could overcome this (Esterhuizen et al., 2021) . The acetaminophen remediation efficiency of Phanerochaete chrysosporium (97 and 99% of 250 µg/L APAP after 3 and 7 days, respectively) was far superior to that of M. hiemalis, and co-cultivation of the two species resulted in a decreased remediation efficiency compared to P. chrysosporium in single (Esterhuizen et al., 2021) . Furthermore, Olicón-Hernández et al. (2020) studied the degradation of a mixture of acetaminophen, diclofenac, ibuprofen, ketoprofen and naproxen with P. oxalicum, starting from an initial concentration of 50 µM of each compound in both flasks and bench fluidized bioreactors. P. oxalicum showed higher degradation percentages in the bioreactor than at the flask scale. The authors reported that with glucose addition in the fluidized bed bioreactor, degradation of all drugs was complete after eight days (Olicón-Hernández et al., 2020) . In a fed-batch stirred bioreactor, P. chrysosporium oxidatively degraded up to 99% of diclofenac, ibuprofen, and naproxen each at a concentration of 0.8 mg/L (Rodarte-Morales et al., 2012a). However, in continuously stirred bioreactors, P. chrysosporium degraded diclofenac, ibuprofen, and naproxen (1 mg/L each) up to 95%. With these preliminary flask and laboratory-scale reactor experiments, the potential of using mycoremediation to treat NSAIDs is highlighted. However, data on the performance of the fungi in WWTPs is lacking, making a consequential evaluation impossible. A potential issue that may arise in practice is the need for maintenance and controlled conditions, as highlighted by the study conducted by Esterhuizen et al. (2021) , which showed the need for maintaining pH conditions. To overcome the limitations of monocultures for the remediation of these pollutants, the use of microorganismconsortia has been explored. Consortia of microorganisms that complement each other could improve biological wastewater treatment technologies significantly. For example, Nguyen et al. (2013) found that a mixed bacterial culture in conjunction with T. versicolor in an augmented MBR better degraded PhACs than a system containing the fungus or bacteria alone . In addition, bioaugmentation technologies using adapted fungi, such as P. oxalicum, have proven an interesting technology to overcome the problem of competition with autochthonous microbiota, as demonstrated by Olicón-Hernández et al. (2021) . However, more data are needed to define complementary species since the study by Esterhuizen et al. (2021) revealed that coculture of certain species could reduce the remediation efficiency. In general, low remediation efficiencies for most antibiotics from wastewaters have been reported using CAS treatment (Chaturvedi et al., 2021a; Zou et al., 2022) . Thus, CAS could be applied to treat some antibiotics; however, not all. More recently, increased antibiotic removal percentages have been reported with anoxic/anaerobic/oxic granular and suspended activated sludge processes, specifically with sulfamethoxazole (Kang et al., 2018) . The shortcoming could be improved by supplementing the sludge with bacteria capable of better remediation or even mixing treatments and complementing CAS with mycoremediation with macromycetes has been proven to be very effective for antibiotics. T. versicolor, in flask experiments, degraded the antibiotic ofloxacin (10 mg/L) with 80% efficiency. When upscaled to 10 L fluidized air-pulse bioreactors, ofloxacin spiked into hospital waste was removed by 98.5% under sterile conditions and 99% under nonsterile conditions (Gros et al., 2014) . Buchicchio et al. (2016) reported the elimination of 55% clarithromycin (0.03 µg/L) by edible mushroom P. ostreatus and 57% by the micromycete T. harzianum. In flask experiments, P. ostreatus could also eliminate oxytetracycline (50 and 100 mg/L) after 14 days (Migliore et al., 2012) . The antifungal drugs bifonazole and clotrimazole were also bioaccumulated and eliminated by the mycelia of the edible fungus Lentinus edodes (Kryczyk-Poprawa et al., 2019) . In flask experiments, the cephalosporin antibiotic cefuroxime axetil was entirely eradicated by both the edible mushrooms Imleria badia and L. edodes within seven days at all concentrations tested (400, 1,000, 1,600 mg/L) (Dąbrowska et al., 2018) . Leptosphaerulina sp. removed oxacillin (16 mg/L, in 6 days), cloxacillin (17.5 mg/L, in 7 days) and dicloxacillin (19 mg/L, in 8 days) from water in flask experiments by the action of laccase and peroxidase. With synthetic hospital waste, oxacillin was reduced by 60% within two days and wholly eradicated after six days by the Leptosphaerulina sp. (Copete-Pertuz et al., 2018) . In a comparative study investigating the degradation efficiencies of five ligninolytic fungi, the polypore Irpex lacteus degraded the fluoroquinolone antibiotic flumequine, ciprofloxacin and ofloxacin effectively within six days (Èvanèarová et al., 2013;Čvanvarová et al., 2015) . I. lacteus also removed the residual antibacterial activity of norfloxacin and ofloxacin via the action of manganese peroxidase (Čvanvarová et al., 2015) . Ahumada-Rudolph et al. (2021) evaluated fifty fungal isolates from sediments of salmon hatcheries for their oxytetracycline remediation abilities. The filamentous fungi Penicillium commune, Epicoccum nigrum, T. harzianum, Aspergillus terreus, and Beauveria bassiana were identified as having the best remediation rates amounting to a maximum of 78% removal of a 250 mg/L oxytetracycline concentration in flask experiments (Ahumada-Rudolph et al., 2021) . P. oxalicum RJJ-2 has also been studied in the degradation of erythromycin and degraded 84.88% erythromycin after 96-h incubation used as the sole carbon source producing different metabolites . The studies on the efficiency to remove antibiotics reported to date have focused on the efficiency under set conditions. However, in a WWTP, environmental conditions and even the water's parameter would fluctuate from time to time. How this could affect the remediation efficiency and fungal longevity over time is unknown. Nevertheless, this information could be essential in evaluating this technique's applicability in the field. It is importante to note the relevance of the use of fungi in removing antibiotics since bacteria can adquire rapidly antibiotic resistance genes during bioremediation and contribute to the widespread of ARGs. The fate of estrogenic hormones treated via activated sludge systems in full-scale WWTPs was reviewed by Hamid and Eskicioglu (2012) . Activated sludge systems with nutrient removal achieved more than 90% degradation in most studies (Hamid and Eskicioglu, 2012) . Degradation of testosterone and 17α-ethinylestradiol (EE2) by the fungus L. edodes was reported by Muszyńska et al. (2018) , with no testosterone or 17α-ethynylestradiol detected after 21 days . Interestingly, the white-rot fungus P. ostreatus HK 35, in the presence of the natural water microbiota of a WWTP, degraded up to 90% of 17β-estradiol (E2) within 12 days in various bioreactor sizes and under different regimes (Křesinová et al., 2018) . The micromycete Trichoderma citrinoviride AJAC3 degraded 99.6% 17 β-estradiol (E2) (at a starting concentration of 200 mg/L) after four days attributed to the secretion of ligninolytic enzymes (Chatterjee and Abraham, 2019) . A study investigating the efficiency of mycoremediation to remove 17 β-estradiol (E2) from poultry litter found that the polypore Pycnoporus sp. SYBC-L3 could remove up to 78.4% via solid-state cultivation supplemented with citric acid and lignocellulosic biomasses to boost laccase activity (Liu et al., 2016) , an approach that could be tested for increasing remediation from wastewaters. Even though the hormone remediation percentage reported with mycoremediation is, in some cases, higher than the CAS studies reviewed by Hamid and Eskicioglu (2012) , a comparison is not possible since the studies on the fungal efficiency were performed in the laboratory in comparison to the CAS studies completed on-site at WWTPs. In addition to excluding several variables that could impact the remediation efficiency, these studies have established the remediation efficiencies for individual compounds. In wastewater effluent, a mixture of not only PhACs are present, and the synergistic effect of all these compounds could affect the efficiencies reported (Chatterjee and Abraham, 2019) . Bioabsorption is another approach to PhAC remediation with fungi. L. edodes and Agaricus bisporus (champignon) stalks removal 100% of 17α-ethinylestradiol (EE2) in 20 and 30 min, respectively via absorption, whereas Shiitake substrate absorbed 80% (de Jesus Menk et al., 2019) . Despite the high hormone remediation percentages achieved with fungi described above, few studies have been published on this topic in the last decade, and renewed investigations would greatly benefit the development of this technique to elevate the environmental impacts of hormones released untreated from WWTPs. Cruz- Morató et al. (2013) studied the degradation of pharmaceuticals in hospital effluent by T. versicolor. By employing fluidized bed bioreactor in fed-batch mode, T. versicolor could eliminate ibuprofen (2.34 mg/L), acetaminophen (1.56 mg/L), ketoprofen (0.08 mg/L), propranolol (0.06 mg/L), and azithromycin (4.31 mg/L). By running the fluidized bed reactor in continuous mode, the efficiency was increased, and the fungus was able to completely remove acetaminophen (109 mg/L), naproxen (1.62 mg/L), ibuprofen (35.5 mg/L), diclofenac (0.477 mg/L), codeine (0.606 mg/L), trimethoprim (0.853 mg/L), and sulfamethoxazole 1.41 mg/L 100%, and partially remove several other drugs. However, salicylic acid, tetracycline, and carbamazepine were not degraded (Cruz-Morató et al., 2013 , 2014 . T. versicolor was also investigated for its performance to remediate PhACs from veterinary hospital wastewater; however, only 66% removal efficiency was achieved in a non-sterile batch bioreactor (Badia-Fabregat et al., 2016) . P. oxalicum XD.3.1 has also been used in batch benchscale bioreactors to test the remediation efficiency with real hospital effluents. Within 24 h, P. oxalicum was able to reduce the majority of the PhAC present in the effluent, including ketoprofen, naproxen and paracetamol. Interestingly, P. oxalicum also affected the native microbiota, including opportunistic pathogens (Olicón-Hernández et al., 2021) . In fluidized bed bioreactor studies, including hospital wastewater spiked with 10 mg/L each diclofenac, ketoprofen, and atenolol, P. ostreatus completely remediated diclofenac in 24 h and 50% of the ketoprofen in 5 days. However, atenolol was not removed (Palli et al., 2017) . These studies demonstrated the complexity of degrading PhAC in mixed matrix effluents, which could drastically reduce the remediation efficiency. Therefore, more studies should be conducted at a larger scale employing real effluents to develop mycoremediation using fungi. Currently, mycoremediation studies on other emerging PhACs, such as anticancer and antiretrovirals, are lacking. Testing fungal species capable of degrading pharmaceuticals at a laboratory scale is ongoing; however, it is difficult to predict how biological organisms would cope in a treatment facility exposed to chemical mixtures over long periods. Thus, recognizing the potential of mycoremediation for the treatment of pharmaceuticals demonstrated to date, studies regarding functioning and long-term applicability in practical terms to evaluate the feasibility of mycoremediation fully are still lacking. However, limitations such as partial degradation of pharmaceuticals and reduced efficiency at lower PhAC concentrations have been identified but could be overcome by using consortia or optimizing enzyme extraction and isolation to reduce costs. The exact mechanism of degradation for each fungal type and PhACs is still vague due to its complexity and all the counterparts involved (Dąbrowska et al., 2018) . However, the degradation seems to include activities of the intracellular enzymatic system such as the cytochrome P450 system, mainly in fungi lacking ligninolityc enzymes, and the extracellular enzymatic system, including lignin peroxidase, manganese peroxidase, laccase, versatile peroxidase as well as hydroxyl and free radical, in the case of lignin degrading enzymes producers (Dąbrowska et al., 2018; Barh et al., 2019) . Nevertheless, elimination is reported to produce no toxic byproducts (Copete-Pertuz et al., 2018) , therefore necessitating further studies into mycoremediation optimization for an add-on in WWTPs and elucidating the mechanism of action. The use of isolated fungal enzymes could also overcome some limitations associated with mycoremediation. Fungal enzymes, specifically the ligninolytic enzymes, have been recognized for their abilities to transform a broad range of recalcitrant PhACs. However, difficulties in growing fungi on a large scale, together with the long incubation processes, extensive growth phase, and spore formation, have prompted the exploration of extracted crude and isolated enzymes (Stadlmair et al., 2018) . Though, to date, the main limiting factor has been the high cost of the enzyme purification procedure. Commercially available laccases from T. versicolor efficiently degraded diclofenac, trimethoprim, carbamazepine and sulfamethoxazole as individual drugs, but the remediation efficiency decreased when applied to mixtures of the drugs (Alharbi et al., 2019) . Kang et al. (2021) isolated laccases from Bjerkandera spp., which could efficiently remediate acetaminophen under a range of pH conditions (Kang et al., 2021) . In a study employing immobilized laccases from Trametes hirsuta, Hachi et al. (2017) reported better remediation efficiencies for carbamazepine and acetaminophen (40 and 70%) in single compared to in mixtures (5 and 25%) (Hachi et al., 2017) . Using laccases (2,000 U/L) isolated from Myceliophthora thermophile, 94.1 and 95.5% of estrone E1 and 17β-estradiol E2 could be degraded within 8 h in the presence of a natural mediator in a fed-batch bioreactor. In an enzymatic membrane reactor (EMR) with a stir-tank configuration, this percentage was increased to 95% for E1 and near total E2 degradation (Lloret et al., 2010) . This indicates that the bioreactor type significantly impacts the remediation efficiency regarding isolated enzymes. In a study by Becker et al. (2017) , immobilized laccase from T. versicolor and M. thermophila could degrade 83 and 87%, respectively, of estrogenic compounds (E1 estrone; E2 17β-estradiol; EE2 17α-ethinylestradiol) in mixtures with other endocrine-disrupting compounds within 6h (Becker et al., 2017) . Golveia et al. (2018) reported 96.5% remediation of 10 mg/L 17-α-ethinylestradiol by Pycnoporus sanguineus laccase (1,642 U/mL) after 8 h (Golveia et al., 2018) . It would be noted that 1% (v/w) was added to the fungal culture to promote optimal laccase production concentration before extraction. Utilizing isolated enzymes has the advantages of reducing the remediation time by avoiding the lag phase of fungal growth, reducing sludge production, and facilitating process control (Jebapriya and Gnanadoss, 2013) . Apart from the high cost as a disadvantage, a study by Nguyen et al. (2014) demonstrated another drawback of using isolated enzymes (Nguyen et al., 2014) . In a direct comparison, whole-cell culture degraded trace organic compounds with higher efficiency, which is said to be facilitated by biosorption and the activity of both intracellular and mycelium associated enzymes. The environmental impact of pharmaceuticals and their proper elimination from wastewaters have gained interest in recent years, mostly due to the intrinsic characteristics of these compounds, their massive use, and the negative effects on the environment and humans. Although they are medicinal substances developed to aid in the well-being of organisms, their indiscriminate use can lead to irreversible environmental problems. Therefore, it is important to create legislation according to the current standards of using substances and eco-friendly trends. More versatile and efficient systems for eliminating PhACs such as mycoremediation are being developed to lessen or avoid the problems associated with pharmaceutical pollution in the environment. However, these promising techniques are still at a laboratory scale and data regarding the application in WWTPs are still lacking. Even though new techniques for the remediation of PhAC are being developed and optimized, relative to the development of new drugs, implementing these techniques into practice is slow. New promising approaches for this purpose, such as genetic engineering, are still in their infancy. Thus, the new editing tool, such as CRISPR-Cas9, could help to introduce metabolic genes focused on target recalcitrant compounds. Much more studies are still necessary to deal with the problem of PhACs. 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differentiated thyroid cancer in patients with thyroid nodules Biorremediation: issues and challenges Occurrence of selected pharmaceuticals in water and sediment of Umgeni River Biosorption of pharmaceutical products by mushroom stem waste Biodegradation of oxytetracycline by Pleurotus ostreatus mycelium: a mycoremediation technique Toxicities of 48 pharmaceuticals and their freshwater and marine environmental assessment in northwestern France Determination of selected antiretroviral drugs in wastewater, surface water and aquatic plants using hollow fibre liquid phase microextraction and liquid chromatography -tandem mass spectrometry Effect of NSAIDs on recovery from acute skeletal muscle injury: a systematic review and metaanalysis Simultaneous quantification of commonly prescribed antiretroviral drugs and their selected metabolites in aqueous environmental samples by direct injection and solid phase extraction liquid chromatography -tandem mass spectrometry Synthesis and application of a molecularly imprinted polymer in selective solid-phase extraction of efavirenz from water Phytotoxicity of different antibiotics to rice and stress alleviation upon application of organic amendments Observed and potential environmental impacts of COVID-19 in Africa Lentinula edodes Mycelium as effective agent for piroxicam mycoremediation Analysis of the biodegradation of synthetic testosterone and 17α-ethynylestradiol using the edible mushroom Lentinula edodes Endocrine-disrupting chemicals and the regulation of energy balance Urban informal settlements as hotspots of antimicrobial resistance and the need to curb environmental transmission Pharmaceutical chemicals and endocrine disrupters in municipal wastewater in Tokyo and their removal during activated sludge treatment Antiviral drugs in aquatic environment and wastewater treatment plants: a review on occurrence, fate, removal and ecotoxicity Occurrence, distribution, and ecotoxicological risk assessment of selected pharmaceutical compounds in water from Lake Victoria Occurrence of anticancer drugs in the aquatic environment: a systematic review Environmental fate and ecotoxicological effects of antiretrovirals: a current global status and future perspectives Cytostatic drugs and metabolites in municipal and hospital wastewaters in Spain: filtration, occurrence, and environmental risk Occurrence of antibiotics and antiretroviral drugs in source-separated urine, groundwater, surface water and wastewater in the peri-urban area of Chunga in Lusaka Occurrence of selected antibiotics and antiretroviral drugs in Nairobi River Basin Removal of trace organic contaminants by an MBR comprising a mixed culture of bacteria and white-rot fungi Removal of pharmaceuticals, steroid hormones, phytoestrogens, UV-filters, industrial chemicals and pesticides by Trametes versicolor: role of biosorption and biodegradation Toxic effects of erythromycin, ciprofloxacin and sulfamethoxazole exposure to the antioxidant system in Pseudokirchneriella subcapitata Taxonomic profiling of bacteria and fungi in freshwater sewer receiving hospital wastewater Pharmaceuticals in the marine environment: a review Determination of selected antimalarial pharmaceuticals in water from two hospital environments in Abeokuta Ogun state-Nigeria using SPE-LC Evaluation of diclofenac biodegradation by the ascomycete fungus Penicillium oxalicum at flask and bench bioreactor scales Penicillium oxalicum XD-3.1 removes pharmaceutical compounds from hospital wastewater and outcompetes native bacterial and fungal communities in fluidised batch bioreactors Overview on the biochemical potential of filamentous fungi to degrade pharmaceutical compounds Metabolic capability of penicillium oxalicum to transform high concentrations of anti-inflammatory and analgesic drugs Meta-analysis to identify the core microbiome in diverse wastewater Preliminary evaluation of Pleurotus ostreatus for the removal of selected pharmaceuticals from hospital wastewater Fate of antibiotics in soil and their uptake by edible crops Genomic and transcriptomic perspectives on mycoremediation of polycyclic aromatic hydrocarbons Toxicity of the non-steroidal anti-inflammatory drugs (NSAIDs) acetylsalicylic acid, paracetamol, diclofenac, ibuprofen and naproxen towards freshwater invertebrates: a review Occurrence of steroid estrogens, endocrine-disrupting phenols, and acid pharmaceutical residues in urban riverine water of the Pearl River Delta, South China Distribution pattern, behavior, and fate of antibacterials in urban aquatic environments in South China Occurrence of pharmaceuticals and cocaine in a Brazilian coastal zone Pharmaceutical formulation facilities as sources of opioids and other pharmaceuticals to wastewater treatment plant effluents Tracking the occurrence of psychotropic pharmaceuticals in Brazilian wastewater treatment plants and surface water, with assessment of environmental risks Antiviral drugs in wastewater and surface waters: a new pharmaceutical class of environmental relevance? Pharmaceuticals in farms and surrounding surface water bodies: hazard and ecotoxicity in a swine production area in Costa Rica Occurrence of pharmaceuticals, hazard assessment and ecotoxicological evaluation of wastewater treatment plants in Costa Rica Phycoremediation: role of algae in waste management A review on effective removal of emerging contaminants from aquatic systems: current trends and scope for further research Algae-mediated processes for the treatment of antiretroviral drugs in wastewater: prospects and challenges Screening of human and veterinary pharmaceuticals in estuarine waters: a baseline assessment for the Tejo estuary Degradation of erythromycin by a novel fungus, Penicillium oxalicum RJJ-2, and the degradation pathway Pharmaceutical and personal care products in different matrices: occurrence, pathways, and treatment processes Contaminants of emerging concern in the Hartbeespoort Dam catchment and the uMngeni River estuary 2016 pollution incident occurrence and environmental risk assessment The occurrence of selected pharmaceuticals in wastewater effluent and surface waters of the lower Tyne catchment Biotransformation of three pharmaceutical active compounds by the fungus Phanerochaete chrysosporium in a fed batch stirred reactor under air and oxygen supply Operation of stirred tank reactors (STRs) and fixed-bed reactors (FBRs) with free and immobilized Phanerochaete chrysosporium for the continuous removal of pharmaceutical compounds Antibiotic residues in final effluents of European wastewater treatment plants and their impact on the aquatic environment Improvement of anaerobic degradation by white-rot fungi pretreatment of lignocellulosic biomass: a review Cytotoxic drugs in drinking water: a prediction and risk assessment exercise for the thames catchment in the United Kingdom Enantiomer-specific bioaccumulation and distribution of chiral pharmaceuticals in a subtropical marine food web Removal of antiretroviral drugs stavudine and zidovudine in water under UV254 and UV254/H2O2 processes: quantum yields, kinetics and ecotoxicology assessment Occurrence and risk assessment of pharmaceutically active compounds in wastewater treatment plants. a case study: Seville city (Spain) Ecotoxicological aspects related to the presence of pharmaceuticals in the aquatic environment Microplastics as vectors of pharmaceuticals in aquatic organisms -an overview of their environmental implications. Case Stud Occurrence of venlafaxine, other antidepressants and selected metabolites in the Rhine catchment in the face of climate change Toxic effects of the non-steroidal anti-inflammatory drug diclofenac: part I: histopathological alterations and bioaccumulation in rainbow trout Global occurrence of anti-infectives in contaminated surface waters: impact of income inequality between countries Characterisation and bioremediation of wastewater: a review exploring bioremediation as a sustainable technique for pharmaceutical wastewater Immobilization of laccase on hollow mesoporous carbon nanospheres: noteworthy immobilization, excellent stability and efficacious for antibiotic contaminants removal Occurrence and distribution of pharmaceuticals in wastewater from households, livestock farms, hospitals and pharmaceutical manufactures Enzymes in removal of pharmaceuticals from wastewater: a critical review of challenges, applications and screening methods for their selection Occurrence, sources and fate of pharmaceuticals and personal care products in the groundwater: a review Root response in Pisum sativum under naproxen stress: morpho-anatomical, cytological, and biochemical traits Toxic effects of NSAIDs in non-target species: a review from the perspective of the aquatic environment Identification and risk assessment of human and veterinary antibiotics in the wastewater treatment plants and the adjacent sea in Tunisia Modelling of the fate of selected endocrine disruptors in a municipal wastewater treatment plant in South East Queensland Protecting the environment from psychoactive drugs: problems for regulators illustrated by the possible effects of tramadol on fish behaviour Occurrence of drugs in German sewage treatment plants and rivers Pharmaceuticals and metabolites as contaminants of the aquatic environment The interference of pharmaceuticals with endogenous and xenobiotic metabolizing enzymes in carp liver: an in-vitro study Pharmaceuticals, endocrine disruptors, personal care products, nanomaterials and perfluorinated pollutants: a review Trametes versicolor in lignocellulose-based bioeconomy: state of the art, challenges and opportunities Occurrence and fate of carbamazepine, clofibric acid, diclofenac, ibuprofen, ketoprofen, and naproxen in surface waters The lazarus drug: the impact of antiretroviral therapy on economic growth A preliminary study on the occurrence of pharmaceutically active compounds in hospital wastewater and surface water in Hanoi Toxic effects of the non-steroidal anti-inflammatory drug diclofenac: Part II. Cytological effects in liver, kidney, gills and intestine of rainbow trout (Oncorhynchus mykiss) Detection of pharmaceutically active compounds in the rivers and tap water of the Madrid Region (Spain) and potential ecotoxicological risk Pharmaceuticals as emerging contaminants in the aquatic environment of Latin America: a review Understanding the role of mediators in the efficiency of advanced oxidation processes using white-rot fungi A framework for the analysis of polar anticancer drugs in wastewater: on-line extraction coupled to HILIC or reverse phase LC-MS/MS Multi-residue analysis of pharmaceuticals in wastewater by liquid chromatography-magnetic sector mass spectrometry: method quality assessment and application in a Belgian case study Hospital effluents as a source of emerging pollutants: an overview of micropollutants and sustainable treatment options Contaminants of emerging concern in municipal wastewater effluents and marine receiving water Removal of endocrine disruptors in waters by adsorption, membrane filtration and biodegradation. A review The effect of oxytetracycline on physiological and enzymatic defense responses in aquatic plant species Egeria densa, Azolla caroliniana, and Taxiphyllum barbieri Fate of antibiotics, antibiotic-resistant bacteria, and cell-free antibiotic-resistant genes in fullscale membrane bioreactor wastewater treatment plants Occurrence and ecological hazard assessment of selected antibiotics in the surface waters in and around Lake Honghu Ecotoxicological effects of ibuprofen on plant growth of Vigna unguiculata L The drug-resistant bacteria that pose the greatest health threats Bacterial degradation of naproxen -undisclosed pollutant in the environment Acute and chronic toxicity of veterinary antibiotics to Daphnia magna Study on the matrix effect in the determination of selected pharmaceutical residues in seawater by solid-phase extraction and ultra-high-performance liquid chromatographyelectrospray ionization low-energy collision-induced dissociation tandem mass spectrometry Paracetamol in the environment and its degradation by microorganisms Effects of ibuprofen, diclofenac and paracetamol on hatch and motor behavior in developing zebrafish (Danio rerio) Analysis of bacterial community structure of activated sludge from wastewater treatment plants in winter Threat and sustainable technological solution for antineoplastic drugs pollution: review on a persisting global issue Use of selected NSAIDs in Guangzhou and other cities in the world as identified by wastewater analysis Removal of bisphenol A and diclofenac by a novel fungal membrane bioreactor operated under non-sterile conditions Occurrence and phase distribution of selected pharmaceuticals in the Yangtze Estuary and its coastal zone Occurrence and biodegradability studies of selected pharmaceuticals and personal care products in sewage effluent Seasonal variation of endocrine disrupting compounds, pharmaceuticals and personal care products in wastewater treatment plants Occurrence and quantification of prevalent antibiotics in wastewater samples from Rawalpindi and Islamabad Antibiotics and antibiotic resistant genes (ARGs) in groundwater: a global review on dissemination, sources, interactions, environmental and human health risks Comprehensive evaluation of antibiotics emission and fate in the river basins of china: source analysis, multimedia modeling, and linkage to bacterial resistance Efficient multiresidue determination method for 168 pharmaceuticals and metabolites: optimization and application to raw wastewater, wastewater effluent, and surface water in Beijing Elimination of carbamazepine in a non-sterile fungal bioreactor Quinolone antibiotics in sewage treatment plants with activated sludge treatment processes: a review on source, concentration and removal The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.