key: cord-0753191-w6rpoq3q authors: Anand, Uttpal; Li, Xuan; Sunita, Kumari; Lokhandwala, Snehal; Gautam, Pratibha; Suresh, S.; Sarma, Hemen; Vellingiri, Balachandar; Dey, Abhijit; Bontempi, Elza; Jiang, Guangming title: SARS-CoV-2 and other pathogens in municipal wastewater, landfill leachate, and solid waste: A review about virus surveillance, infectivity, and inactivation date: 2021-08-04 journal: Environ Res DOI: 10.1016/j.envres.2021.111839 sha: 5822d53de5f004ff0cb0f6d0824f675395076220 doc_id: 753191 cord_uid: w6rpoq3q This review discusses the techniques available for detecting and inactivating of pathogens in municipal wastewater, landfill leachate, and solid waste. In view of the current COVID-19 pandemic, SARS-CoV-2 is being given special attention, with a thorough examination of all possible transmission pathways linked to the selected waste matrices. Despite the lack of works focused on landfill leachate, a systematic review method, based on cluster analysis, allows to analyze the available papers devoted to sewage sludge and wastewater, allowing to focalize the work on technologies able to detect and treat pathogens. In this work, great attention is also devoted to infectivity and transmission mechanisms of SARS-CoV-2. Moreover, the literature analysis shows that sewage sludge and landfill leachate seem to have a remote chance to act as a virus transmission route (pollution-to-human transmission) due to improper collection and treatment of municipal wastewater and solid waste. However due to the incertitude about virus infectivity, these possibilities cannot be excluded and need further investigation. As a conclusion, this paper shows that additional research is required not only on the coronavirus-specific disinfection, but also the regular surveillance or monitoring of viral loads in sewage sludge, wastewater, and landfill leachate. The disinfection strategies need to be optimized in terms of dosage and potential adverse impacts like antimicrobial resistance, among many other factors. Finally, the presence of SARS-CoV-2 and other pathogenic microorganisms in sewage sludge, wastewater, and landfill leachate can hamper the possibility to ensure safe water and public health in economically marginalized countries and hinder the realization of the United Nations' sustainable development goals (SDGs). some questions (Sahin et al., 2021) . Though these vaccines have shown a lot of promise, they also raise concerns for their safety and effectiveness (Kelly et al., 2021) . In fact, many patients in India have tested positive for COVID-19 following their second dose of vaccines. According to the Indian Council of Medical Research, more than 21,000 people tested positive following their first dose of Covishield or Covaxin, while over 5,500 people tested positive following their second dose (Anon, 2021) . Almost all the countries around the globe ordered complete or partial lockdown for weeks or longer, which were enforced through cancellation of mega-events, reduced transportation, lesser industrial activities, and lesser human to human exposure. This allowed a major improvement in the air quality index in almost all megacities of the world. Lokhandwala and Gautam (2020) have found a reduction of about 85% in particulate matter levels in the most polluted city of India. The NO2 emission has dropped by 30-60% in many European countries, including Rome, Paris, Madrid, Milan, and Barcelona (EEA, 2020) . In the United States (US), the levels of NO2 have declined by 25.5% during this COVID-19 period compared to previous years (Jesse and Keita, 2020) . The lesser gaseous emissions during this period are also supported by the fact that the oil demand has dropped down to 4,350,000 barrels in the first three months of 2020 compared to the same period in 2019 (IEA, 2020) . Major industrial sources of pollution have stopped completely or partly, which has enhanced the J o u r n a l P r e -p r o o f water quality of the rivers (Singhal and Matto, 2020) . Travel restrictions have also resulted in less air or road traffic, which has reduced the noise pollution. Despite that the current pandemic situation has in some cases reduced the environmental load, serious health issues have emerged majorly because of its contagious nature and unavailability of effective medical treatment (Coccia, 2021) . It is a challenge for the public health officials right from diagnosing to the treatment of COVID-19 patients. Moreover, as it is a pandemic disease and a big population is affected, many countries are facing issues of insufficient testing capacities, inadequate hospitalization facilities, including beds, intensive care units (ICUs), doctors and medical staff (Bontempi, 2021) . One additional complication is that many asymptomatic cases are also reported . The history of such pandemics reveals that monitoring sewage for traces of a pathogen provides a sensitive signal of the presence of the pathogen in entire communities and can also predict whether the transmission is increasing or declining (Larsen and Wigginton, 2020) . The science of wastewater-based epidemiology (WBE) by monitoring viral RNA in wastewater provides opportunities to assess the COVID-19 prevalence and spread in defined populations, proving beneficial for informing related public health policy (Wu et al., 2021) . WBE can be processed to obtain an unbiased surveillance system and reflect community health (Scott et al., 2021; Yaniv et al., 2021; Tomasino et al., 2021) . It is scalable, economical and provides rapid results for emergent and reemergent pathogens (Polo et al., 2020; Randazzo et al., 2020; Tiwari et al., 2021) . The information gained from sewage can be used to refine the response to the pandemic and help the authorities to make strategies (Kumar et al., 2021b) . Possible recommendations may be towards lockdown or quarantine. Researchers in Australia, the Netherlands, Sweden, and the USA have already detected SARS-CoV-2 in wastewater Malapatty, 2020; . During the early week of the outbreak of COVID-19 in New Haven (Connecticut) several cases were tracked and declared positive by confirming the presence of SARS-CoV-2 RNA in primary sewage sludge from local wastewater treatment plants . More importantly, as sewer systems continuously receive human excreta with viral particles irrespective of the symptomatology status of the patient (symptomatic/asymptomatic/subclinical/presymptomatic), WBE approach can provide a real-time and unbiased surveillance for the outbreak (Kordatou et al., 2020) . Even during air travel or cruises, the wastewater provides an additional diagnostic tool of the prevalence of SARS-CoV-2 infections among passengers onboard . At the same time, the virus persistence in wastewater opens other issues, related to its spread. The mechanism for the detection of virus in sewage initiates by dilution of virus from feces and other shedding sources in toilet water, then in other municipal wastewater including grey water and some cases industrial and storm waters. Subsequently, the virus travels along with its RNA through a J o u r n a l P r e -p r o o f complex sewage system where it is exposed to different physical, chemical, and biological factors. Moreover, the detection of the virus is related to its concentration methods like polyethylene glycol (PEG) method for precipitation of viral material and ultrafiltration at molecular weight level (Aviles et al, 2021) . However, the persistence and survival of the coronavirus in water systems depend on several factors like temperature, organic content, light familiarity, and the existence of antagonistic organisms (Bilal et al., 2020; Wigginton et al., 2015) . At present, data about virus persistence in different regions and climatic conditions seem to be highly variable (Hart et al., 2020) . Significant gaps in the knowledge of the wastewater contribution to the SARS-CoV-2 spread exist. Virus survival in the environment, including the soil, the air, water bodies, and sewage and landfill leachate, is still poorly known . Experimental data about SARS-CoV-2 inactivation and/or removal by sewage and the most suitable and verified treatment processes is scarce . The enveloped coronavirus is considered unstable in the environment due to its higher susceptibility to oxidants like chlorine and is inactivated much faster in water than non-enveloped human enteric viruses . Researchers have also tried a quantitative microbial risk assessment (QMRA) framework for estimation of SARS-CoV-2 in natural water bodies through dose-response model and Poisson's distribution . However, despite the high number of papers devoted to sewage (mainly concerning wastewater surveillance to track COVID-19), considering it as an important tool in early diagnosis and prevention of its outbreak in urban areas, only few works were devoted to sewage sludge and no works were devoted to landfill leachate as additional possible sources of virus spread in the environment. This study reviews the SARS-CoV-2 infectivity, surveillance, and inactivation as biohazard, that can be found in sewers, wastewater treatment plants, and landfills. Due to the possibility to use the reviewed technologies for surveillance and inactivation to pathogens in general, this work may be also used to have an overview of available possibilities to manage other outbreaks. Also the SARS-CoV-2 infectivity and reported transmission mechanisms may be useful to study or support similar behaviours for other pathogens. To provide a comprehensive assessment of the surveillance, infectivity, and inactivation of SARS-CoV-2, the available literature was investigated by a systematic review. COVID-19 pandemic has attracted great attention in literature: SCOPUS database shows the existence of more than 210,000 papers devoted to this argument (in July 2021). The present review paper is dedicated to wastewater, landfill leachate, and sewage sludge. However, as reported in the introduction, no works expressly dedicated to landfill leachate and the current pandemic were found, then the bibliographic search was devoted to "sewage sludge", "wastewater", and COVID-19 (or J o u r n a l P r e -p r o o f SARS-CoV-2). SCOPUS database allowed to identify about 200 papers containing these keywords in all available document fields. The downloaded information derived from the SCOPUS platform included for all articles title, authors, abstract, keywords, and references. In particular, an analysis of keywords co-occurrence network of papers devoted to "sewage sludge", wastewater, and COVID-19 (or SARS-CoV-2) allowed to perform a cluster analysis of the literature (see Figure 2 ) to propose a suitable and structured review. The study design (with connected literature) was updated on July 14, 2021. Literature data analysis was performed by "VOSviewer version 1.6.16," 2020. The results (see Figure 2) show that the already available papers can be grouped in 5 clusters. The first one (79 items), represented by red bubbles, is mainly devoted to wastes generated during the pandemic and their toxicity, with attention to their management and treatment. In this cluster there are several papers treating wastewater and sewage sludge. Some interest related to the sustainable development can be also found. The second cluster (37 items), highlighted by green bubbles, concerns public health and virus characteristics and detection. The third cluster (34 items) is mainly centered on wastewater and the virus monitoring aspects (blue bubbles). The fourth cluster (42 items) is addressed to SARS-CoV-2 transmission mechanisms and sewage sludge and wastewater treatments (yellow bubbles). Finally, the last cluster (7 items) is more general: it is centered on coronavirus and pandemic (violet bubbles). Based on the results of cluster analysis, the paper was conceived in some categories (developed in the Results and discussion, section 3), devoted to presence and risks associated to SARS-CoV-2 (3.1), its potential transmission routes (3.2), and its detection and treatment (3.3). Finally, based on the literature results, attention is also dedicated to clean water and sanitation for a sustainable future (3.4). Due to the lack of papers devoted to "landfill leachate" and COVID-19, general literature concerning this waste was checked. The keywords co-occurrence network of papers devoted to "sewage sludge", wastewater, and COVID-19 (or SARS-CoV-2). The study design was updated on July 14, 2021. Data analysis was performed by "VOSviewer version 1.6.16," 2020. In this era of COVID-19, inadequate wastewater treatment and management (especially in economically marginalized countries), whether at the urban, rural, domestic, or industrial level, pose a high risk and major challenge due to the massive amount of biomedical waste and wastewater that finds its way to wastewater treatment plants. Biomedical waste generated by hospitals is typically incinerated or autoclaved before disposal. However, in some countries, such treatment facilities are insufficient due to poor infrastructure, and as a result, raw waste containing living pathogens may enter water systems, jeopardizing the environment (Iyer at al., 2021) . For example, in some cities in Bangladesh, many residents' septic tanks are directly connected to open drains, allowing their waste to be released into the environment without their knowledge (Jeffrey, 2018) . Moreover, landfill leachate generated during this pandemic may contain pathogenic microorganisms and promote the SARS-CoV-2 migration in the environment, threatening society and leaving many scientific challenges. These situations may be a hindrance to human health, especially in the ongoing pandemic situation. The invasion of SARS-CoV-2 needs to be assessed in each of the unit operations in the sewage treatment plant along with the presence of other hazardous pathogenic microbes. Microorganisms such as pathogenic bacteria, virus, and worm eggs, as well as other physio-chemical pollutants, are commonly found in such a stream (Suresh et al., 2018 . They are further divided into four categories: bacteria, viruses, protozoa, and helminths. The presence of many pathogenic or non-pathogenic (E. coli) bacteria (>10 10 /g) in septic tank sludge and wastewater sludge could greatly affect human health conditions. Excreta from SARS-CoV-2-infected humans contains such organisms and finds way into sewage, which might pose a serious risk. There is a potential risk of SARS-CoV-2 transmission among people due to the dumping of wastewater or sewage into perennial streams or rivers (Ducoli et al., 2021) . Despite such an ominous possibility, the current opinion, especially of most water microbiologists, is that wastewater does not appear to be a significant mode of SARS-CoV-2 transmission (Ahmed et al., 2021) . Recently, SARS-CoV-2 highlighted the presence of risks in septic tank sludge and sewage sludge (Zambrano-Monserrate et al., 2020; . Coronavirus is entering into sewage stream from different sources like restroom, public toilets, hospitals, schools, and office buildings (Daughton, 2020; Heller et al., 2020; Usman et al., 2020) . Diarrhea, typhoid, cholera, paratyphoid, and other types of diseases occur due to water-borne pathogenic organisms detected in wastewater/sewage. In addition, sewage sludge also contains viruses and pathogenic protozoa which comes from mainly infected humans, i.e., human adenoviruses, enteroviruses (e.g., polioviruses), diarrhea-causing viruses (e.g., rotavirus), hepatitis-A virus and reoviruses, Balantidium coli, Entamoeba histolytica and Giardia lamblia, helminths (parasitic worms) (Bibby and Peccia, 2013; Carr and Strauss, 2001 ). On another side, solid waste landfills or leachate contains pathogenic microbes (fecal coliforms, salmonellae, human enteroviruses, human noroviruses, and protozoan parasites), which mainly comes from food waste, pet feces, human disposable hygiene products, and biosolids from sewage plants. In particular, an increase of plastic use derived from the health diapositives (as for example from disposable facemasks), has increased the amount of waste destined to landfilling, with a risen concern about the possibility of SARS-CoV-2 migration in the leachate. Typical indicator bacteria (total coliforms, fecal coliforms, and fecal streptococci) were estimated in the early 19 th century. However, despite that the first publications indicated that these pathogens are not a major concern in solid waste landfills or leachate (Peterson, 1974 ) (Haas et al., 1996 , more recent reports from the United States Environmental Protection Agency (USEPA) identified different pathogenic bacteria and viruses present in the solid waste landfills or leachates, with increasing risks to the human health (Gerba et al., 2011; USEPA, 2008; USEPA, 2009 ). J o u r n a l P r e -p r o o f Figure 3 shows the total amount of waste landfilled in EU in 2019. More recent data, reporting also the expected increase of landfilled waste due to pandemic, are still not available. However, it is estimated that landfilled waste is globally increased more than 3500 thousand tons in the first pandemic year, only due to facemasks disposal (Silva et al., 2021) . It is evident that several countries will have a huge problem in waste management, with high consequent risk derived from possible pollution due to leachate, and possibility of virus spread. Nghiem et al. (2020) examined the impact of the COVID-19 pandemic on waste and wastewater services. The lifespan of SARS-CoV-2 varies depending on the material, ranging from 3 hours in aerosols to 2-3 days in sewage/solid feces. As a result of their long periods of survival, anyone who comes into contact with contaminated materials during that period is likely to become infected (Nghiem et al., 2020) . J o u r n a l P r e -p r o o f SARS-CoV-2 has spherical particle with spike proteins on its surface and positive-sense singlestranded RNA within the lipid envelope . SARS-CoV-2 virions can be transmitted via air as part of aerosols with its nature of size . COVID-19 patients can excrete feces and sputum with high loads of SARS-CoV-2 that eventually enter the wastewater. Several research groups, for example Australia, the Netherlands, Sweden, and the USA, have already reported detecting traces of SARS-CoV-2 in wastewater (Figure 4) . Randazzo et al. (2020) reported the finding of SARS-CoV-2 RNA in six wastewater treatment plants ( Similar SARS-CoV-2 RNA was found in the sewage sludge as SARS-CoV-2 was isolated from COVID-19 patients' feces and urines (Randazzo et al., 2020) . While the presence of virus RNA does not always mean that the virus is infective, the RNA may, however, persist in the media, even though the virus itself may have been inactivated. Moreover, these viruses may survive in the wastewater or sludge. Indeed, it has also been reported that the human coronavirus had been detected in sewage sludge (Bibby and Peccia, 2013) J o u r n a l P r e -p r o o f Moreover, solvents and detergents are present in sludge that can deactivate the viral envelop with ambient temperature. In the oxidation pond with elevated pH, long retention times and proper sunlight is a very good option to treat the sludge and to destroy the pathogen (WHO, 2020). Composting of sludge could inactive male-specific coliphage (Viau and Peccia, 2009 ). Based on experience, sludge treatment and disposal process should maintain in a closed system to reduce the risks of viral contact with the human and ecologic environment. The common treatment for medical waste is through incinerators, landfills, autoclaves, furnaces, and kilns etc. Zanda and Heir (2020b) reviewed safe separation, handling, and disposal of municipal solid waste, including medical wastes from the hospital and non-hospital sources in the Tehran region. They suggested substantial structural modification in waste management is required, from the separation and storage guidelines at homes and hospitals to the safety protocols for waste collection teams during the pandemic. For example, an uncorrected management of medical waste destined to landfill may generate risk of SARS-CoV-2 spread, due to the possibility that the virus could migrate from the waste in the landfill and then into the landfill leachate. This not only may represent an additional source of environmental contamination, but also a potential exposure risk to landfill workers or workers handling the leachate after it is removed from the landfill (Langone et al., 2020) . Then, the current situation of the COVID-19 pandemic requires special designed treatments due to the excess flow of pathogen laden waste and personnel protective equipment. It involved high health risks for handling workers using alternative disposal of medical waste as co-incinerate in the cement plants (Ducoli et al., 2021) . Automatic incinerators can reduce the human contact with pathogens in the solid waste. Furthermore, some of the operating conditions of thermal treatment should be strictly maintained to destroy any pathogens in the medical wastes (WHO, 2017). While limited evidence was found that sludge would play an essential role in SARS-CoV-2 transmission, there is still a need to understand the fate of coronaviruses outside the human host, including their persistence and inactivation mechanisms in sludge, which would help to reveal their potential risks during sludge treatment and disposal. Viruses can transmit potentially from wastewater. This could be due to the inhalation of infectious droplets generated by contaminated waste (as happens when contacting with infected persons, which has been diffusely discussed in the literature (Bontempi, 2020a) , drinking, and direct contact with contaminated water (Ducoli et al., 2021) . Water is commonly recognized to be the main vehicle of virus transmission. Most of the viruses present in the human's gastrointestinal tract can be discharged into the environment through feces, resulting from possible pollution of surface water and J o u r n a l P r e -p r o o f groundwater (Paleologos et al., 2020) . As a result, the drinking of contaminated water and/or the consumption of fruits or vegetables deriving from sites contaminated with such water may be the source of virus transmission that can be recognized as a pollution-to-human transmission mechanism. This is different to the well-documented human-to-human transmission mechanism due to the contact and/or proximity to infected people. In addition, food can be an origin of transmission, considering contamination originated from sewage (García-Ávila et al., 2020). It has been recently shown that SARS-CoV-2 can bioaccumulate in mollusks and other aquatic organisms, with its consequent possible presence in seafood markets (which is also one of the suspicious primary origins of SARS-CoV-2), with a viral transmission from wastewater to surface water bodies (for example sea) in a circular contamination process (Mordecai and Hewson, 2020). In this context, it is important to cite that combined sewer overflow (CSO) caused by heavy rainfalls have been reported as a possible source of COVID-19 diffusion. In particular, this possibility was attributed to overflows of sewage that are not still opportunely treated (that may contain human wastes mixed with stormwater runoffs). This risk may occur in urban spaces and in water bodies (Han and He, 2021) , with several possible negative consequences. Although only few papers have proposed the SARS-CoV-2 infectivity due to its persistence in the municipal sewage , several papers have already demonstrated that SARS-CoV-2 remains active when it is present in the feces and urine of infected people (Jeong et al., 2020; Sun et al., 2020) . The inhalation of polluted water droplets can happen in all the environments where an infected sewage source can be present (Bogler et al., 2020; Kang et al., 2020 , Bogler et al., 2020 Kang et al., 2020) . For example, several researchers reported that the virus presence in air samples of wastewater treatment plants strongly suggest that wastewater aerosols can be a source of SARS-CoV-2 spread . Some studies developed a quantitative microbial risk analysis that showed a relatively high risk of infection deriving from bioaerosols exposition (Gholipour et al., 2021) . However, it is important to highlight that the lack of a SARS-CoV-2 model for dose-response is a critical limitation for conducting quantitative microbial risk analysis for this virus (Gholipour et al., 2021) . It is also important to underline that some safety measures (that may have different social acceptance (Bontempi et al., 2020; Bontempi, 2021) , such as facemask wearing, can contribute to decreasing occupational health risk also in wastewater treatment plants. On the contrary, the SARS- fundamental to underline that land application of biosolids may result in another potential way to generate aerosol (Siddique et al., 2020) . This may be considered as another SARS-CoV-2 transmission pathway connected to pollution-to-human transmission through droplets and aerosols (Bontempi, 2020b) . This can cause concerns because of pandemic, needing to re-consider the land applications of biosolids under the conditions. Finally, untreated sewage may also be used for soil penetration or exfiltrate accidently to underground soils. However, the SARS-CoV-2 survival in the soil is not still supported by solid literature (Wiktorczyk-Kapischke et al., 2021) , and then it is difficult to predict its possibility of transmission to humans. Sewage that can also be defined as domestic wastewater or municipal wastewater is the untreated wastewater produced by a human community. In addition to water, it mainly consists of organic matter, viruses, bacteria, heavy metals, and inorganic salts. Due to its direct discharge in water bodies (rivers and streams) by many countries, sewage is often considered the oldest form of pollution. In particular, surface water, including rivers, oceans, estuary, and lakes, can be contaminated by viruses even after wastewater treatment due to the fact that sewage treated effluents often still contain some pathogens that could be discharged into surface water bodies (Okoh et al., 2010 (Randazzo et al., 2020) due to the current lack of evidence. Moreover, SARS-CoV-2 RNA was already detected in sewage and wastewater in many countries (Davó et al., 2021; Weidhaas et al., 2021) . Some research (e.g., Paleologos et al., 2020; Anayah et al., 2021) showed that residence time and temperature are the most significant factors that can be correlated with the diffusion/spread of COVID-19 in water. Non-suitable waste management, mainly in low-income countries, has opened several problems of possible pathogens propagation through waste. In this frame, the effect of the pandemic in the change of waste management strategies (mainly in developed counties) has been extensively treated in literature (Sharma et al., 2020; Zand and Heir, 2021) , reporting the change in the composition and quantity of solid wastes due to COVID-19. On the contrary, the emerging challenges in waste J o u r n a l P r e -p r o o f management practices have been rarely addressed (Zand and Heir, 2020) . Concerning the waste discarded in landfilling sites that may contain a large quantity of infected wastes, such as facemasks, gloves, plastics, and tissues contaminated with sputum, new suggested issues are connected with the possibility of generating liquid pollutants (Figure 5) . The persistence of pathogenic bacteria in leachate landfill can be dependent on temperature, salt content, pH, and predation with other pathogenic bacteria (Madigan et al., 2006) . SARS-CoV-2 remained viable on different surfaces as cardboard, copper, stainless steel and plastic from 15-72 h under laboratory conditions (Van Doremalen et al., 2020) . Infectious SARS-CoV-2 was also detected from tissue papers after 3 hours, cloths after 2 days, glass and banknote for 4 days and a surgical mask for 7 days (Chin et al., 2020) . In landfill site, waste compacting is commonly applied to minimize the size of waste before landfill. Waste compacting coupled with the high moisture content of other collected wastes and precipitation mostly result in the landfill leachate (Zand and Heir, 2020) . This liquid residue is a complex waste that may have different chemical composition, depending on generating controlled nature and typologies of waste, among other factors (Iskander et al., 2018) . Some sites collect the leachate into J o u r n a l P r e -p r o o f a tank or a retention pond for further treatment (Renou et al., 2008) . The leachate in the leachate ponds can infiltrate in the soil, which can also occur due to the leaching and washing by rainfalll can also generate groundwater pollution, which can be considered a secondary way of SARS-CoV-2 spread in the environment (Langone et al., 2020) . Then, secondary contagion sources of SARS-CoV-2, for example deriving from landfill leachate, is due to improper waste management that is more likely occurring in low-income countries, where the control and legislation about solid waste are lacking. During the pandemic, the leachate of landfills (also known as percolate) should be carefully processed, with the aim not only to avoid secondary pollution and virus spread but also to avoid the generation of aerosol that may occur during flushing or aeration processes in the treatment plant . It was published that the virus of avian influenza (H6N2) can be inactivated by landfill leachate, also due to the non-neutral pH of this waste (Graiver et al., 2009 ). However, the inactivation time was reported to be in the range of 30 and 600 days. Moreover, direct information regarding SARS-CoV-2 is lacking due to the lack of research about its fate in landfill leachate. It is thus essential to perform in-depth studies to investigate the potential virus presence in landfill leachate and its possibility to diffuse in the environment. The wastewater-based epidemiology (based on the principle of SARS-CoV-2 genetic material detection in wastewater) has been proposed as a promising approach to monitoring the pandemic status in real-time . This is based on establishing a way for the surveillance of people infected within an area (that may be a city of a region) that excrete viral genomes into wastewater. WBE has the great advantage to have samples containing excrement from both symptomatic and asymptomatic people, returning a more real situation about contamination. Indeed, the current detection system is often not able to map a significant per cent of asymptomatic individuals that, on the contrary, can be accounted for by sewage analysis. Many works have reported SARS-CoV-2 molecular detection worldwide in wastewater in the USA, Australia, the Netherlands, and France (see, for example, Lodder et al., 2020; . Generally, three SARS-CoV-2 genes (ORF1ab, S, and N) have been detected in the wastewater. Some of the studies depicted in the table (Table 2 ) focused on the presence of SARS-CoV-2 in various urban environments. Nevertheless, it was also reported that a step to ensure SARS-CoV-2 concentration is mandatory to increase the chance of subsequent virus detection, even if the analysis concerns untreated wastewater Lodder et al., 2020) . Moreover, even if a lot of methods were developed to concentrate viruses in wastewater, it was shown that standard concentration methods, used for the most abundant viruses that can be found in J o u r n a l P r e -p r o o f environmental water samples, which have some specific structural and physical properties, are inefficient to recover coronavirus (Ye et al., 2016) . The persistence of SARS-CoV-2 and the methods that may be used for its concentration have been first investigated by using surrogates, such as other coronaviruses and bacteriophage Φ6, (Silverman et al., 2020) . J o u r n a l P r e -p r o o f Some of these results, even if sometimes controversial , also support the idea that using a filter for virus concentration may have great potentialities to remove SARS-CoV-2 from sewage and water. Recent studies performed in the USA, Australia, the Netherlands, and France, have shown that RNA extraction of SARS-CoV-2 was possible by using several concentration methods, such as electronegative membrane adsorption, PEG precipitation, and ultrafiltration . In addition, the concentration of water volumes is a key factor that can affect the SARS-CoV-2 detection. The first studies treating SARS-CoV-2 molecular detection investigated samples up to 200 mL of raw wastewater . However, it is evident that in situations where the virus may be less prevalent, larger sewage volume in comparison to the standard used for other analysis may be necessary for the detection. Concerning the SARS-CoV-2 detection, it primarily relies, at present, on reverse transcriptionpolymerase chain reaction (RT-PCR) and a quantitative assay (RT-qPCR) (see, for example, García-Ávila et al., 2020) , being N protein gene the most reported target gene for these assays . For example, the last developed assays based on this protein were found to be able to detect few RNA copies per reaction , Corman et al., 2020 . These results are supported by recent work (Nalla et al., 2020) that shows comparative results about the performance of the RT-qPCR assay concerning the genes that are targeted (N, E, and RdRp). It is also important to remember that RT-qPCR assays that are currently available at laboratory levels were developed for clinical diagnosis. Then their application in the environmental analysis may involve some unexpected problems and produce conflicting results . To overcome this obstacle, it is strongly suggested to perform sequencing analysis or PCR preamplification, followed by sequencing, if RT-qPCR detects the virus RNA in wastewater samples . In the future, new improvements or new techniques are foreseen. For example, it is expected that technologies will be improved to allow SARS-CoV-2 RNA detection more easily and rapidly, especially when laboratory facilities are not available. To limit the use of thermal cycler, essential to perform PCR, loop-mediated isothermal amplification methods are needed to be improved . The use of digital RT-PCR can also introduce some advantages in detecting SARS-CoV-2 RNA in wastewater samples, such as higher sensitivity and accuracy in detection and quantification than RT-qPCR (Dong et al., 2021; Suo et al., 2020) . Another critical issue of RNA analysis with molecular-based method is the inhibition, which requires process controls (Haramoto et al., 2018) to avoid the necessity to re-analyses the samples. The conventional RT-PCR techniques used for analysis have some drawbacks, such as their unavailability in remote regions. They also are labor-intensive and requires high resources. Biosensors, some of them based on nanoparticles, were also explored as an alternative to RT-qPCR J o u r n a l P r e -p r o o f for the SARS-CoV-2 detection (Tetteh et al., 2020; . Nevertheless, for the integration of WBE into a conventional SARS-CoV-2 detection and surveillance context, other points need to be opportunely addressed, like the incidence of PCR false-positives and negatives (that may be due to unsuitable primers/probe or virus mutation in the targeted genome region), the SARS-CoV-2 persistence in wastewater and other environmental matrices Polo et al., 2020) . SARS-CoV-2 RNA detection in sewage plants need to be investigated more accurately (Street et al., 2020; Gwenzi, 2020) , and the proposed assays need to be studied and tested by multiple laboratories, also to better evaluate their sensitivities and viability. Many research groups all over the world are monitoring wastewater for SARS-CoV-2 RNA. However, potential impacts of temporal and spatial variables on the correlation of RNA and human infection prevalence have been posed Li et al., 2021b) . It is also important to investigate these relationships in different contexts, such as in low-income areas and rural locations (with decentralized infrastructure for wastewater management) and/or in urban centralized wastewater facilities. International collaborative activities must be done to assess the uncertainty and variation of the diverse settings, using systematic methodologies for the validation and the harmonization of the methodologies. Efforts in data sharing, the introduction of appropriate standards, suitable quantitative controls, and coordinated actions must also be encouraged. Efforts must also be devoted to suggesting suitable strategies for sample storage, virus concentration and extraction requirements. In addition, efforts must also be made to recommend appropriate strategies for sampling, surveillance, and the reduction of infectivity as well as the decay of SARS-COV-2. An overall study design should be considered. All these actions will help to ensure high quality, data defensibility, quality control, high-quality publications, and cross-laboratory comparability, to reach solid robustness of resulting data sets making able the scientific community to analyze transmission dynamics also considering various temporal and spatial levels . Some concerns about sewage monitoring may include privacy implications. A protocol should be standardized to SARS-CoV-2 recovery and detection from environmental water samples. The protocol should include several of the described issues, such as concentration methods, detection assays, and process controls and sampling and preserving methods. Environmental persistence accounts for the time a pathogen can survive outside the human body. The virus is more likely to cause infection the longer it survives (Lahrich et al., 2021) . The virus persistence is dependent on the type of environment (for example natural water or sewage) and by J o u r n a l P r e -p r o o f the environment chemical, physical and biological properties (for example, pH, temperature, and humidity) (Lahrich et al., 2021) . The demonstrated capability of some viruses in comparison to bacteria to travel for long distances in the soil and probably into groundwater sources is attributed to their persistence that may occur for a considerable period (up to 17 days in the environment). Their limited size makes their removal extremely hard and the risk of contamination very high (Paleologos et al., 2020) . Enveloped viruses were found able to survive for 6-7 days in sewage (Casanova et al., 2009) , while it was suggested that SARS-CoV-2 might persist for periods ranging from 4 to 72 hours on the surfaces, depending on the environmental conditions and the material surface nature (van Doremalen et al., 2020) . This evidence supports the hypothesis that the SARS-CoV-2 virus may be present in water bodies, resulting in reservoirs for human diseases. As a consequence, virus inactivation is a fundamental factor that can allow to control virus fate and transport in the environment. By inactivation, a virus is destroyed or rendered non-pathogenic. This usually can be realized by altering the environment around the virus, that in turn produces an irreversible disruption and denaturation of the viral structure. It can be obtained by using physical, chemical, and/or energetic methods (Sakudo et al., 2011) . The EPA communicated that standard wastewater treatment and disinfection are expected to be effective for SARS-CoV-2 (EPA, 2020). Similar considerations have been suggested by other water utilities in some European countries, such as Poland and Czech Republic. On the contrary, China has proposed increased use of chlorine to improve its disinfection efficiency to reduce the possibilities of SARS-CoV-2 circulation by wastewater (Taleb et al., 2020) , not evaluating the possibility that high concentration and high dose of disinfectants may promote the evolution toward antimicrobial resistance (Chen et al., 2021) . On April 23, 2020, WHO guidance (WHO, 2020) has informed about the role of temperature, pH, and sunlight in reducing the virus persistence. However, it highlighted the possible occurrence of problems for wastewater treatment plants not optimized for the removal of viruses. It must also be considered that even if the available and most used treatment technologies show high performances for chemical, physical, and some microbiological contaminants (Adelodun et al., 2021) , the removal of some human viruses (like enteric viruses) in the sewage is still unsatisfactory. In addition, regulatory standard procedures for the treatment of sewage-contaminated with viruses have not been introduced at this time. Despite that, a list of some active disinfectants against SARS-CoV-2 has been published (EPA, 2020b), essentially for surface use. On the contrary, no standard guideline exists related to sewage treatments. SARS-CoV-2 is an enveloped virus with a fragile outer lipid membrane surrounding a protein capsule consisting of protein and glycoprotein, susceptible to chemical inactivation (García-Ávila et al., 2020) or other disinfectant solutions . For example, if chlorine is used, when it J o u r n a l P r e -p r o o f penetrates the lipid membrane, its reaction with the internal proteins leads to SARS-CoV-2 inactivation. Then, wastewater disinfection with chlorine dioxide or free chlorine has been reported to be effective (Tetteh et al., 2020) . Wang et al. (2005) investigated the SARS-CoV persistence in hospital sewage, domestic sewage, urine, feces, wastewater and tap water. They also studied the contact time role for the coronavirus inactivation in sewage with different chlorine and chlorine dioxide concentrations. Results showed that coronavirus can persist for a longer time at lower temperatures (at 4 °C in comparison to 20 °C) in domestic sewage, hospital sewage, and dechlorinated tap water. At 20 °C, coronavirus persisted in some fecal and urine samples for some days. They also showed that free chlorine resulted more effective inactivation in comparison to chlorine dioxide (Wang et al., 2005) . However, a more recent work seems to be in contrast with the reported results, showing that disinfection seems less effective than other processes, as for example adsorption and coagulation for SARS-CoV-2 removal (Kumar et al., 2021c) , highlighting the need of technological improvement (Ardito et al., 2021; Coccia and Watts, 2020; Coccia, 2019) . Other proposed disinfection strategies are based on advanced oxidation process, including ultrasonic process, Fenton and photo-Fenton, photocatalysis, UV irradiation, ozone combined with catalysts, and ozone combined with hydrogen peroxide (Tetteh et al., 2020) . Several studies have experimented with hybrid methods where two or more technologies can be integrated to increase treatment efficiency and performance. Also, there are other strategies using solar and UV irradiation (Polo et al., 2015) , coagulation and microfiltration (Matsushita et al., 2013) , and ceramic water filtration (Farrow et al., 2013) . A hybrid process consisting of several steps involving ozonation, coagulation, and ceramic membrane separation, has also been proposed to abate water contamination . Several of the proposed technologies can be implemented at the plant scale in the treatment of municipal wastewater (Figure 6) . Moreover, they are relevant only for large cities where suitable treatment plants are already in place. However, some studies propose advanced and expensive technologies that cannot be applied for lowincome countries or when the implementation should be on a large scale, like the use of Ag for wastewater decontamination, that results in an advantage for photocatalytic degradation, ceramic pot filtration, and adsorption column (Liga et al., 2011) . For wastewater remediation, magnetic nanomaterials have also been proposed as a promising wastewater treatment technology. In this case, contaminant-loaded magnetic particles can be selectively removed from the original solution using a magnetic field (Tetteh et al., 2020) . Membrane-coupled bioreactors are an effective system to remove SARS-CoV-2 (Lesimple et al., 2020) . Literature generally assumes wastewater treatment technologies to be effective also for SARS-CoV-2, even though no experimental investigation was done. On the other hand, even if their J o u r n a l P r e -p r o o f effectiveness for SARS-CoV-2 must be investigated in detail, there are some simple existing technologies for virus decontamination, e.g., ceramic water filter (Farrow et al., 2014) due to their applicability in low-income countries and/or rural areas. Some of these simple technologies may also be improved and re-designed for application in these areas. Finally, it is also extremely important to consider that excessive disinfectants and drug use of such may produce some effects on the environment (García-Ávila et al., 2020; Kuroda et al., 2021 , Islam et al., 2020 that are not still considered or suitably evaluated. For example, in the environment, chlorine can be transformed into substances that can be highly dangerous for aquatic organisms. If it reacts with organic matter, it can also produce haloacetic acids (HAA) that are toxic for aquatic species can also be persistent for a long time in the environment (Li et al., 2019) . Some research highlighted the overuse of antimicrobial agents as a possible reason for the increase in antimicrobial resistance (Koch et al., 2021) . Despite that lockdown policies have generally produced a reduction of atmospheric emissions of several pollutants (Parida et al., 2021) , the pandemic has caused negative effects on water, as discussed in the previous sections. Specifically, in connection with water pollution, pandemic has a high impact on several SDGs. Figure 6 shows the proposed remediation technologies (discussed in section 5), that are strictly related to SDGs 3 and 6. However, in conventional methods, the addition of disinfectant chemicals frequently results in the formation of disinfection by-products (DPBs), which are again harmful and pose health risks. As a result, safe and environmentally friendly removal of microorganisms from wastewater is required to meet the United Nations SDGs. Viruses cannot be removed by microfiltration as they are too small. Most water filters will remove contaminants that are on the micron scale, however, viruses are only nanometers (1-100 nm) in size and will break through. Advanced oxidation processes (APOs) are convenient methods for degrading and detoxifying contaminants in water systems. The combination of systems such as UV radiation with ozone, hydrogen peroxide, and ferrous and titanium oxide are used for micro-pollutant removal. Viruses can be inactivated by oxidizing their DNA/RNA and protein envelope structures. It also shows the SDGs that can be directly correlated with water management due to COVID-19 crisis. In particular, the possibility of virus survival on aquatic media can also impact SDG 2. Concerning food production, it is interesting to highlight that lockdown may promote the development of local food supply chains, that requires less transport and packaging in comparison to conventional food supply chains (Marusak et al., 2021; Thilmany et al., 2021) , offering a better alternative for responsible consumption and production (SDG 12). However, sustainable food systems need to acquire food security that can be guaranteed by suitable irrigation and fertilizers. Therefore, the problem concerns not only water but also sewage sludge management that cannot be always reused as fertilizer (Ducoli et al., 2021) . At urban level wastewater treatment management need particular attention, to limit the possibility of virus spread during the treatment (see section 4), with impact on SDG 11. In addition, it was shown that in several countries, wastes generated by personal disposal used because of pandemic (as for example facemask) are often discarded in the environment and consequently found in water bodies, as for example in wastewater gullies, inland waterways, and drainage canals. Also, this practice strongly impacts SG 11 (Benson et al., 2021) and SDG 15. In developing countries, the food insecurity can cause the rise in poverty levels (SDG 1); the lack of safe water can lead to search for water far from home. The installation of piped water near the home promotes better economic development (Bontempi et al., 2021b) . With large populations relying on J o u r n a l P r e -p r o o f forests for survival, land degradation, makes population more vulnerable to climate change that can exacerbate existing inequalities and problems related to safe water supply. The sixth United Nations SDGs focus on the availability of clean water and better sanitation to all communities across the world. This is especially pertinent in the context of low-income countries since accessibility to these basic life necessities are the lowest in these countries. The pandemic has had a negative impact on water management strategies across the world in general, but low-income countries have faced tougher challenges in ensuring the availability of safe drinking water due to several infrastructural handicaps (Figure 7) . In particular, the proximity of the pit-latrine sanitation system and groundwater source is a major concern in many low-income countries while also open defecation close to the surface water is also a common practice (Adelodun et al., 2020) . In these areas, most of the population, especially the population living in rural communities, largely rely on the surface and groundwater resources for the daily water consumption need. This not only can represent a local sanitary problem, but also can increase the risk of COVID-19 disease spread. In addition, the pandemic has raised the water supply-demand, for example, for the increase of the personal hygiene measures. In this context it is important also to highlight that, during the last century, water use is globally increasing, with more than twice the rate of population growth (TLGH, Editorial 2020). Consequently, measures devoted to water resources protection and suitable treatment and discharge of wastewater are urgently needed. Improved sanitation facilities are necessary to ensure hygienic procedures to assure the separation of human excreta (avoiding direct human contact) from water sources destined to humans. COVID-19 pandemic has highlighted the extent of the existing gap in safe water availability worldwide and stressed the need to reach the SDG 6, addressed to guarantee water availability and sustainable management and sanitation world population by 2030. To reach SDG 6, more efforts are needed to develop and diffuse cost-effective technologies for the detection and disinfection of sewage. Reuse of wastewater for agricultural purposes to recover nutrients must be carefully considered and controlled. The potential for SARS-CoV-2 airborne transmission during sewage management due to aerosolisation of the virus must be carefully evaluated. However, the impressive global disruption due to pandemic offers an opportunity to proceed, react, and increase people's resilience. With a change of global vision and a revision of the priorities, we can achieve a more sustainable world by accelerating the process mainly concerning SGD 6 and addressing future environmental and health challenges. This review paper concerns the surveillance, infectivity, and inactivation of SARS-CoV-2, addressed to wastewater, landfill leachate, and sewage sludge. Despite the lack of papers specifically devoted to landfill leachate, a systematic literature analysis allowed to provide some fundamental information. Also thanks to the recent advances in molecular biology SARS-CoV-2 (and other pathogenic organisms) has been detected in municipal wastewater, sewage sludge, and solid waste, imposing high risks of potential circulation and transmission. In particular, based on data (sometimes contrasting) about its fate and decay in urban wastewater and environment, SARS-CoV-2 has been reported to only induce a remote chance of pollution-to-human transmission. However, this review paper shows that the knowledge of SARS-CoV-2 transmission routes and environmental fates still needs to be improved and that the effective surveillance and deactivation are critical, calling for significant efforts in establishing standardized and quantitative detection methods. As a result, it is fundamental to conduct proper monitoring of wastewater for any pathogenic organism that has been scientifically identified. Natural water systems that receive untreated or inadequately treated wastewaters poses an even higher risk of transmitting infectious diseases. Change of wastewater and solid waste management will be critical in alleviating the problems and ensure UN SDGs to be achieved worldwide, especially in developing countries under the impact of COVID-19. This study presents some limits. One of the main limitations of this research is due to the data source, which was confined to articles collected from SCOPUS till a certain data (on July 14, 2021) . The information about COVID-19 and "sewage sludge" and wastewater obtained from the following periods may provide additional data that are not considered in this work. Another limitation of this work concerns the lack of data about COVID-19 and "landfill leachate". This make necessary to use already published literature, concerning similar pathogens, but not directly related to SARS-CoV-2. Dr Xuan Li is supported by the Australian Research Council Discovery project (DP190100385). Elza Bontempi acknowledges Regione Lombardia for the partial support of this research in the frame of the FANGHI project (call HUB Ricerca e Innovazione). The authors declare no conflict of interest. Anayah, F., Al-Khatib, I.A. and Hejaz, B., 2021. 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Authors expresses their gratitude to Servier Medical ART for designing some figures.