key: cord-0796363-m51j6a5m authors: Singh, Rishikesh; Bhadouria, Rahul; Singh, Pardeep; Kumar, Ajay; Pandey, Shilpi; Singh, Vipin Kumar title: Chapter 21 Nanofiltration technology for removal of pathogens present in drinking water date: 2020-12-31 journal: Waterborne Pathogens DOI: 10.1016/b978-0-12-818783-8.00021-9 sha: 7fd6893d6009d4faedbdb9bb953917b320003337 doc_id: 796363 cord_uid: m51j6a5m Abstract Water is one of the most important natural resources supporting the diverse array of life present on earth. Rapid diminution of fresh potable water reserves, contamination of existing ones, and generation of large amount of wastewater due to anthropogenic activities have compelled the scientists to develop methods to treat the contaminated water. Across the globe, millions of people are inaccessible to fresh drinking water. Multiple health issues are linked with the purification of drinking water supplied through different ways including bottled water, tap water, and borewells. The drinking water is most often contaminated with pathogenic microbes including bacteria, viruses, and protozoa beyond the recommended limits causing serious human health hazards. The pathogenic microbes commonly detected in water supplies include those related to dysentery, typhoid fever, vomiting, and cholera. Therefore, removal of human pathogens from drinking water is essential for health security. Numbers of physical and chemical techniques have been developed to make available the pathogen free drinking water. Techniques employing membranes for trapping hazardous biological contaminant are currently gaining momentum worldwide. This chapter deals with the sources of pathogens in drinking water, important waterborne diseases, and different aspects of nanofiltration techniques over other commercially used methods for removal of pathogens. Water is the essence of life present on earth. Various biological processes in living organisms are solely dependent on the presence of water. Shortage of potable water has emerged as an important challenge to current world generation. Furthermore, the contamination of fresh drinking water by pathogenic microbes as well as their presence in treated water poses a serious challenge to human health globally. The drinking water, under natural condition, is very often susceptible to contamination by nuisance microbes such as bacteria, viruses, and protozoa. To date, more than 100 waterborne pathogenic microorganisms belonging to bacteria, viruses, and protozoa have been identified in contaminated drinking water. Because the contamination happens during withdrawal, collection, storage, and transportation of drinking water, the microbial contamination at source is minimal as compared to places of storage. Importantly, these small infectious entities pose significant limitations in their assessment because of smaller size. The inherent dynamic behavior of conventional water treatment systems leading to process inefficiency for elimination of different organic and inorganic contaminants (Upadhyayula et al., 2008) as well as pathogenic microbes is well recognized. Slight changes in the feedwater quality in terms of pH, temperature, and a. Equally contributed to this chapter. transparency in addition to nature and concentration of microbial pathogens significantly affect the treatment efficiency of traditional water purification practices (Kfir et al., 1995) . Furthermore, changes in water characteristics may modify the equilibrium between the absolute elimination and nonabsolute elimination of a treatment system (Assavasilavasukul et al., 2008; Lechevallier and Au Keung, 2004) . The treatment in conventional process may also allow the luxuriant growth of noxious cyanobacterial strains followed by secretion of health hazardous toxins culminating into poor water quality. Also, the generation of disinfection by-products (DBPs) after application of chlorine and other disinfectant results into water with compromised features (Gopal et al., 2007; Dong et al., 2019) . In this context, many of pathogenic microbes generally encountered in drinking water are resistant to chemical treatment processes (Mohammed, 2019) that might pose serious hazards to human health. Most importantly, the deliberate introduction of pathogenic microbes and their toxins (biothreat agents) in water treatment units or water supply systems with an aim to disturb mass public health as reported in developed countries such as the United States is also a major issue (Horman, 2005; Nuzzo, 2006) . These limitations of conventional treatment units have necessitated the research on membrane processes for the removal of contaminants of either organic or inorganic origin. Among different membrane-based contaminant removal practices, microfiltration (MF), ultrafiltration (UF), reverse osmosis (RO), and nanofiltration (NF) have gained global popularity for water purification as compared to conventional treatment practices. This chapter has been framed to encompass the different waterborne pathogens, important diseases caused by them, and membrane-based processes for their effective removal with particular emphasis on NF technology. The advantages, limitations, and future perspectives of NF process in this connection have also been added. According to an estimate, around 1.5 million deaths of children have been reported to result from diarrhea (Fenwick, 2006) . Astonishingly, diarrhea has been ranked as the second important disease responsible for heavy mortality in children globally. Worldwide, 90% cases of diarrheal diseases are the outcomes of improper sanitary practices and consumption of contaminated drinking water (UNICEF, 2012) . The water-transmitted diseases are also one of the important factors for global economic loss. Apart from the expenses made by human, the World Bank has calculated annual global expenses equivalent to US$260 billion caused by unavailability of safe drinking water and cleanliness (WHO, 2012) . The World Health Organization (WHO) has documented the annual death occurrences reaching up to 5 million caused by waterborne diseases. Children from Asian and African nations below the age of 5 years are the most frequent victims of disease transmitted through microbially contaminated water (Seas et al., 2000) . The population from developed and rural areas is most commonly affected by diseases caused by microbially contaminated drinking water. However, the life-threatening impact of microbially contaminated water has also been observed for human population in developed countries. As per an estimate, in the United States of America, 5.6 lacs people are affected annually to a greater extent from diseases occurring from microbially contaminated water, while 7.1 million are expected to be affected moderately by waterborne microbial diseases leading to an average 12,000 deaths per year (Medema et al., 2003) . Moreover, a minimum of 33 outbreaks of waterborne illness during the year 2009e10 in the United States of America is described (Center for Disease Control and Prevention, 2013) . Such disease incidences indicate the development of easy and low-cost technology for detection of pathogens even at very low density as well as introduction of suitable measures to control the severe human diseases resulting from the utilization of microbially contaminated drinking water. Some of the important waterborne diseases and their causal organism are presented in Table 21 .1. Generally, most of the waterborne pathogens gets their entry into water through humans and animals excreta (Swaffer et al., 2018) and urine. Application of livestock manures for enhancing plant productivity may also lead to microbial contamination of water systems (Bergion et al., 2018) . Some of the pathogenic bacterial species such as Legionella has been suggested to transmit through aerosol formation followed by inhalation (Percival et al., 2004) . Different species of Cryptosporidium are known to contaminate the water system via surface runoff from livestock farm houses destined for milk or meat production (Ruecker et al., 2007) . In addition, for distribution of water, in many countries, the drinking water is supplied through long networks of pipes. The pipe-based translocation system serves as the substrata for the attachment of bacterial species with the tendency to form biofilm. The developed biofilms, on the other hand, may also support the existence of pathogenic microbes either for short time or longer durations. The hygienically important pathogenic organisms may include fecal indicator coliforms (Escherichia coli), some species of Campylobacter, Mycobacterium (Lehtola et al., 2007) , opportunistic bacterial species such as Legionella and Pseudomonas aeruginosa, and viruses responsible for intestinal disease such as adenoviruses, caliciviruses, small round viruses, rotaviruses, etc. In addition, the originated biofilms also promote the suitable environmental habitats for helminths and nuisance protozoa including Entamoeba histolytica, Giardia lamblia, and Cryptosporidium parvum (Wingender and Flemming, 2011) . The survivability of attached pathogenic organisms is largely decided by their physiological and biological characteristics apart from surrounding ecological conditions. Therefore, biofilms present in water transportation system may act like the active reservoir for pathogenic microorganisms and pose serious health hazards to human health if not managed properly. The contamination of drinking water with pathogenic microorganism (Amin et al., 2019; Sanganyado and Gwenzi, 2019 ) is a severe threat to human health. Disease outbreaks in both the developing and developed countries caused by drinking water contamination have lead to millions of death worldwide (Ashbolt, 2004) . Many of the waterborne disease can be controlled through the application of physicochemical methods. Most of the modern water purification techniques are relied on the application of physical and chemical treatment technologies. The traditional methods for managing the pathogenic microbes in drinking water systems involve the heating (Zaman et al., 2019) , treatment with ozone, chlorine and UV irradiation (Antony et al., 2012) , or filtration through membrane system (Ostarcevic et al., 2018) . The conventional treatment technologies for selected pathogenic microbes are effective but are costly and may generate excessive secondary pollutants with toxicity greater than parent molecule necessitating the improvement in currently employed methods. The formation of trihalomethanes as a DBP after treatment with chlorine may be detected up to a level equivalent to 160 ppb causing significant human health hazard (Bellar et al., 1974; Costet et al., 2011) . On the other hand, the added chemicals itself may be hazardous beyond the recommended dose. The chemical treatment techniques for managing the microbial contamination in drinking water are primarily based upon the oxidation of organic component of living cells. The application of a particular disinfection process is, however, not equally effective for eliminating every kind of pathogenic microbes present in drinking water, thus indicating the process limitation. For instance, viruses are generally less susceptible to commonly exploited chemical disinfection processes. Application of membrane-based techniques for microbial decontamination (Torii et al., 2019; Németh et al., 2019) has gained considerable momentum in water purification industries. The superiority of membrane-based techniques over conventional treatment methods can be expressed in terms of (i) produced water with consistent characteristics, (ii) rapid and effective elimination of chemically resistant pathogens, (iii) inhibition of bacterial remultiplication, (iv) negligible residual chemical hazard, and (v) promising efficacy to decontaminate the polluted water with the quality reaching at standard levels. The size-exclusion property of membrane processes is important in view of pathogen removal efficiency (Bennett, 2008) . Membrane with a specified pore size could not be considered fit for removal of every pathogenic microorganisms. Under certain conditions, with the passage of time, the membrane may suffer from low pathogen removal efficiency because of development of breaches, salt deposition, and biofilm formation in applied filter (Stoica et al., 2018) , thereby limiting the overall performance of the filtration technology. On the other hand, the removal of pathogenic microbes via membrane filtration is also affected by different factors including the surface characteristics (Langlet et al., 2008) as well as the time of pathogen's interaction with membrane (Langlet et al., 2009 ). Worldwide increasing demands for synthetic membranes have been expected due to scarcity as well as the microbiological contamination of fresh drinking water. Water purification practices based on pressure-driven membrane filtration can be broadly categorized as (i) MF and UF involving convective separation through membrane with characteristic porous structure and (ii) RO and NF involving diffusion-aided separation through semipermeable membrane displaying dense structure (Antony et al., 2012; Betancourt and Rose, 2004) . The membrane-dependent water treatment technologies have contributed significantly in generation of potable water especially in the United States and Europe. The techniques have been successfully employed to manage not only the pathogenic microbes but also for the elimination of secondary by-products and inorganic as well as organic contaminants of hazardous nature commonly encountered in drinking water. The low pressure operated MF and UF proved as potential alternatives to conventional treatment methodologies. The aforementioned process may involve the removal of pathogens by size exclusion, association with charged membrane to produce a layer, interaction with membrane developed biofilm. Separation of a particular pathogenic microbe is governed by its natural characteristics, features of applied membrane, and physicochemical characteristics of aqueous medium (Jacangelo et al., 1995) . Some of the important information about MF, UF, and RO are presented below. The process is based on the low pressure guided separation through membrane having pore size in the range of 0.1e10 mm allowing efficient water flow rate. The technique is useful in removing the particle supposed to interdict the further water purification steps. Apart from the removal of pathogenic waterborne microorganisms, the technique could be applied successfully for clarification, pretreatment, and removal of coarse particles (Jacangelo et al., 1997; Van der Bruggen et al., 2003) . In contrast to MF, the porosity of membrane employed here for separation process ranges from 0.002 to 0.1 mm, leading to low water filtration rate and thus requirement of high pressure. Currently the process is being practiced for the elimination of pathogens and particulate materials. The pore size of membranes used for UF in water treatment process generally varies from 0.01 to 0.5 mm and is quite effective in removal of most of the pathogenic protozoan cysts having the size in the range of 4e15 mm (Jacangelo et al., 1997) . In general, the membrane used for purification processes are consisted of polysulfone or polyethersulfones. The membranes can be regenerated by suitable treatment methods and can be utilized multiple times for removal of pathogens present in drinking water. One of the experimental investigations has reported the complete removal of poliovirus with the UF membranes having pore size 0.2 nm (Madaeni et al., 1995) . Another study conducted by Jacangelo et al. (1995) has reported the elimination of MS2 virus higher than 6 logs utilizing the UF membrane with pore size as reported by Madaeni et al. (1995) . The process of RO utilizes the denser membrane system without any definite porosity (Van der Bruggen et al., 2003) . The transfer through membrane is hence slow and infiltration is not the outcome of pores present but the high pressureebased removal of targeted contaminant (waterborne pathogen). The broad range of water purification process is effective in simultaneously eliminating both microbial and organic contaminants (Wintgens et al., 2005; Malaeb and Ayoub, 2011) . The high pressure is more desirable for decontamination of feedwater having high osmotic pressure rendered by increased concentration of soluble substances. The RO process is high energy demanding to maintain the pressure required for permeation of molecules. The separation of pathogens is chiefly attributed to the size-exclusion phenomena in addition to other factors including membrane physicochemical characteristics, functional groups associated with pathogens, and the characteristics of feedwater (Antony et al., 2012) . The commonly available module designs for RO devices include spiral wound and hollow fibers. The hollow fibers module with greater density is advantageous in the sense that it allows the fast generation of contaminant free water but has limitations because of rapid membrane fouling (Malaeb and Ayoub, 2011). The NF has emerged as an innovative technology to solve the problem of drinking water contamination (Emamjomeh et al., 2019) . Since its introduction during late 80s, the NF membraneebased separation process so far has achieved multiple improvements. There was continuous rise in numbers of publication starting from 1995 to 2018 ( based on web of science data revealed the "Journal of Membrane Science," "Desalination," "Desalination and Water Treatment," "Separation and Purification Technology," and "Water Research" as some of the important research journals having significant research publications (Fig. 21.2) . Most of the NF-based laboratory and field studies have been conducted in the area of engineering, water resources, polymer science, and chemistry ( Fig. 21.3) , indicating the interest of researchers from wide disciplines in NF technology. The pore size of membrane employed in NF process is generally less than 10 nm (Bohonak and Zydney, 2005) . Based on size-exclusion phenomenon, the NF technology could be utilized for the removal of pathogens present in drinking water together with the organic and inorganic contaminants generally encountered in drinking water and wastewater. However, its expensive nature, high energy requirement, loss in membrane properties after fouling as a prevalent issue, and disposal problems are the major limitations (Snyder et al., 2007; Luo et al., 2014) restricting its widespread dissemination. NF is a complicated phenomenon and is considerably regulated by fluid flow, its characteristics, and interfacial episodes occurring on the outer membrane surface and within porous structures of membrane. The separation through NF membranes is the integrated outcome of Donnan, transport, dielectric, and steric effects. The Donnan effect refers to the equilibrium and interaction between a soluble charged molecule and charge existing on membrane (Donnan, 1995) . The charge existing on membrane has been assumed to result from dissociation of different ionic groups present on membrane as well as from porous conformation of membrane (Hall et al., 1997; Hagmeyer and Gimbel, 1998; Ernst et al., 2000) . The ions may be of acidic, basic, and amphoteric nature depending on the type of materials used for membrane fabrication. The dissociation of surface available ionizable groups is significantly governed by pH of the solution intended for its purification. Noteworthy, the membranes with amphoteric behavior may display isoelectric point at a particular pH value (Childress and Elimelech, 1996) . Apart from the presence of surface ionizable groups, under some conditions, the mild ion exchange property of NF membrane could also lead to adsorption of ions present in solution to be treated and hence may affect the membrane characteristics (Afonso et al., 2001; Schaep and Vandecasteele, 2001) . According to the prevailing conditions accounted by charges on solute molecule and NF membrane, there may be attraction or repulsion. The process of dielectric extrusion as a possible mechanism of NF is very little known and the so-called two important hypotheses "image forces" and "salvation energy barrier" have been proposed to explain the mechanistic details of interaction (Yaroshchuk, 1998; Bowen and Welfoot, 2002) . Both phenomena are attributed to the intense spatial internment, nanoscale dimension existing in the NF membrane, and charge. Solutes mobilizing in the solution phase are affected by drag forces imposed by solvent passing through pores with different dimensions. Thus, the transport of solute molecule through different confined pores is considerably affected by characteristics of solvent, and the free movement of solute is hindered. The overall transport of solute is thus determined by convection and diffusion process. Nevertheless, the real mechanistic details of NF membrane separation process are still unresolved, and interestingly the contribution of dielectric exclusion in membrane separation needs further work in this direction (Oatley et al., 2012) . In general, uncharged solute molecules are rejected because of their size differences (size exclusion). The application of NF technique for separation of different pathogens generally encountered in drinking water is discussed briefly and provided in Table 21 .2. Bacterial pathogens transmitted through supplied drinking water have resulted into several disease outbreaks and mortality in both developed and developing countries. The NF technology has been described to eliminate the bacteria and viruses from both surface and groundwater. The laboratory and field condition evaluation of NF membrane (Fyne process) of lake water was reported by Patterson et al. (2012) . The NF experiments were conducted with varied tubular membrane system having different molecular weight cut-off (MWCO). The filtration process was effective in restricting the passage of bacterial pathogen Bacillus subtilis. The NF process evaluation for removal of test bacteria (B. subtilis) in recycle and dead end mode was based on filters ES404 and CA2PF. The effectiveness of ES404 (MWCO ¼ 4000 Da) in elimination of test bacteria was slightly higher than the CA2PF membrane (MWCO ¼ 2000 Da). Experimental investigations with NF membranes have represented the promising results . The nanofilter NF1 was found to restrict the passage of Clostridium perfringens (w1e5 mM) in four challenges out of seven independent membrane-based separation tests. Higher than 6 log rejection of B. subtilis as test pathogen from surface water (lake water) under field and laboratory condition is illustrated in tubular NF membrane (ES404 and AFC30) evaluated in recycle and dead end mode without the introduction of coagulating substances (Sinha et al., 2010) . Field testebased studies on ES404 and AFC30 membrane NF demonstrated average log removal value as 5.5 and 4.7, respectively, for B. subtilis. The AFC30 membrane with low molecular cut-off (MCO), however, exhibited comparatively weaker removal of test pathogen. Kim et al. (2016) have demonstrated the potential of carbon nanotube and silver compositeebased nanofilter in removal of waterborne bacterial pathogen Staphylococcus aureus. The composite material loaded onto the nanofilter leading to creation of nanopores was shown to be responsible for elimination of bacterial pathogen absolutely. Furthermore, the membrane loaded with composite material displayed considerable antibacterial activity against the S. aureus and E. coli rendered by silver nanoparticles. Most interestingly, the antibacterial effects of silver nanoparticle would be helpful in designing the membrane with negligible biofouling, an important limitation of the most of the currently used membrane-based filtration techniques. Viruses are the important pathogens often detected in drinking water leading to numbers of severe human diseases. Because of resistance, application of chemical processes such as chlorination has been found to have no profound effect on most of the viruses as compared to pathogenic bacteria, calling for the need of membrane-based technologies. The development of membrane-based filtration technology has gained considerable success to eliminate their presence in potable water. Studies conducted on removal of virus based on NF technology have demonstrated promising results. Because the smaller sized virus particles of coliphage Qb as model virus may traverse the NF membrane, the elimination of particular viruses could not be expected to be the only outcome of pore size. The passage of smaller virus particles was expected to result from exceptionally larger membrane pores, not considered for porosity evaluation. However, retention value reaching up to 100% could be achieved for small viruses through NF technology (Urase et al., 1996) . Most importantly, the NF membrane used in the study was not able to act as absolute barrier against the Qb virus having diameter equivalent to 23 nm. Mostafavi et al. (2009) have described the potential of carbon nanotubeebased nanofilter for the separation of MS2 virus for purification of contaminated water. The hollow nanofilter as synthesized through spray pyrolysis displayed efficient permeation and was very much effective in virus removal at pressure ranging from 8 to 11 bar. Studies have been conducted for removal of two bacteriophages MS-2 and PRD-1 (size ranging from 28 to 65 nm) from surface water through sand filtration coupled with NF (Yahya et al., 1993) . The removal efficiency of slow sand filtration was recorded as 99% and 99.9% for bacteriophage MS-2 and PRD-1, respectively. On the other hand, NF process was able to remove the test viruses by 4-6 log units. Otaki et al. (1998) have described 6 log removal of coliphage Qb and 7 log removal of poliomyelitis virus vaccine from river water by using NTR-729HFS4 NF membrane. In this sequence, studies performed by Urase et al. (1996) have reported the efficacy of NF process for rejection of model viruses Qb and T4. The elimination of test virus ranged from 2 to 6 log units. The effectiveness of NF technique for elimination of MS2 virus under field and laboratory condition is demonstrated (Patterson et al., 2012) and suggested the process utilization for small-scale drinking water systems. The two NF membrane systems ES404 (MWCO ¼ 4000 Da) and AFC30 (MWCO ¼ 350 Da) applied for MS2 virus elimination indicated the better performance of ES404. The designed membrane system ES404 achieved approximately complete elimination (around 6 log removal) during three runs performed in recycle mode. On the other hand, the average log removal of test MS2 virus under similar conditions was observed to be 4.8 for AFC30 membrane. Studies with NF membranes have displayed the outstanding performance . Out of seven tests performed for membrane separation of virus MS2 (0.025 mM), in five cases there was complete absence of model virus in permeate after passing through nanofilters comprising of composite thin film (NF1). In two of the runs, there was presence of test organism indicating the fact that the log removal value is not absolutely regulated by microbe size and concentration. For cellulose acetate NF membrane (NF2), log removal value was very weak for PRD-1 and MS2 phage probably because of constraints in maintaining the pH of medium. For composite thin film membrane (NF3), the MS2 virus passed the membrane barrier at three challenges out of four runs conducted. The PRD-1 phage was able to traverse the membrane at two occasions out of four runs performed. Overall, the composite thin filmebased nanofilter was able to achieve 4.5e5.5 log removal value for test microorganism and in more than 50% challenges there was complete removal of test microbes. The study pertaining to elimination of MS2 virus from lake water has shown the effectiveness of membrane NF under field condition (Sinha et al., 2010) . The NF membrane ES404 and AFC30 under recycle mode achieved the mean log removal value 4.6 and 4.3, respectively, for the MS2 bacteriophage and fulfilled the guidelines of USEPA. The tighter membrane AFC30 could not exhibit better log removal performance for MS2 virus. The membrane filter could also be loaded with composite of metal nanoparticle exhibiting antibacterial and carbon nanotube to improve the separation performance of membrane separation process. Kim et al. (2016) have reported the potential of carbon nanotube and silver compositeebased nanofilter in removal of waterborne viruses such as polio-, noro-, and coxsackieviruses. At ambient temperature, the membrane filter loaded with >0.8 mg/cm 2 of composite material was remarkably effective in completely restricting the passage of viruses at a pressure equivalent to 5 kgf/ cm 2 . The composite material loaded membrane was found effective in inhibiting the passage of a mixture of poliovirus and norovirus as revealed through real-time reverse transcription quantitative polymerase chain reaction (RT-QPCR). The elimination of virus was ascribed to the binding of the viruses on comprehensive mesh consisting of carbon nanotube and silver present on membrane surface; therefore, increase in the density of composite material was associated with the increased removal of test virus. Development of NF devices working on the principles of tangential and dead end flow has been evaluated for different plasma-borne viruses and model viruses including HIV, hepatitis virus, parvovirus, reovirus, poliovirus, herpes simplex virus, etc. Some of the filtration devices available in the market are Viresolve, Omega VR, Planova, Viresolve NFP and NFR, and Ultipor. The elimination of pathogenic protozoans including Giardia and Cryptosporidium from contaminated drinking water is a worldwide challenging problem for various government organizations as well as water purification companies. Conventional chlorination is practiced for the inactivation and killing of such pathogens present in drinking water; however, generation of DBPs and resistance to chemicals necessitate the development of membrane-based separation techniques. The combination of RO with NF may improve the removal of targeted pathogen of concern. The integrated approach involving NF has shown 8e10 log removal of Giardia and Cryptosporidium for Lake Arrowhead, California (Madireddi et al., 1997) . Studies on NF membraneeassisted elimination of C. parvum oocysts (w4e6 mm) and G. lamblia cysts (w8e14 mm) are described . Out of 22 runs carried out for separation of protozoan oocysts and cysts, 16 challenge tests displayed the complete rejection in case of composite thin filmebased membrane filtration. Microbial elimination was attributed to the membrane module configuration and structure. There are numerous advantages associated with the application of NF for the efficient removal of contaminants present in drinking water. Some important benefits of NF technology are presented below. NF membrane devices are specifically designed to eliminate the viruses from contaminated sources. In most of the cases, the working parameters such as flow rate, temperature, nature of membrane, load of virus, and filter area are optimized for efficient and reproducible elimination of virus of concern. In contrast to the NF membraneebased virus elimination technique, other separation process such as centrifugation, chromatographic devices destined for purification of a protein molecule could removes viruses as an accidental phenomenon (Burnouf, 1993) . Furthermore, the virus exclusion from contaminated water based on other existing techniques as compared to NF membrane techniques may be expensive and time-consuming. The virus removal through NF membranes occurs via sieving process and hence could be predicted for its efficiency and reproducibility if the process conditions are well-defined. The sieving is very much effective in restricting the passage of virus particles having size higher than mean pore size of NF membrane. Under the conditions where size of virus particles is equivalent to or lower than the membrane pore size, the other operating conditions could have considerable effects on virus removal. This includes congregation of virus particles and their adsorption on membrane filter rendered by surface charge. Examination of NF membrane integrity has demonstrated insignificant variations in the efficiency of virus removal during long-term run signifying the process consistency. NF is efficient in removing high concentration of both enveloped and nonenveloped virus particles. The effectiveness of process is largely determined by the pore size of the membrane and the virus particle size. Most importantly, so far, no other membrane-based technique could have been established that could remove both enveloped and nonenveloped virus particles to an equivalent level as displayed by NF membranes relying on small size pores. Very few separation techniques have represented the considerable flexibility as demonstrated by NF techniques. Nanofilters can be utilized at different phases of synthesis, generally not exhibited by other virus elimination processes. To date, NF membranes with different pore sizes and surface areas have been synthesized and commercialized for virus particles permitting the wide scale and straightforward application. Opposed to the virus inactivation techniques resulting into killing of virus particles and leaving behind the markers such as antigens, coat proteins, and nucleic acids, the NF is potentially able to eliminate these viral signatures and could be utilized for process validation. The chemical processes generally used for the killing of viruses are health hazardous (mutagenic, carcinogenic, teratogenic) and pose negative impact to natural environment, requiring their precise detection and effective removal. Such toxicological assessments are not essential in case of NF-based virus elimination. However, the assessment of leaching of surface adhered virus particles in treated water should be taken into account as a priority during determination of NF process authentication. In addition, the downstream contamination of treated water is rare in case of the NF techniques because of its application before the end of production process. Furthermore, the quality of production also remains unchanged while those based on heat or chemicals for elimination of virus particles may deteriorate the characteristics of treated water to an unacceptable level. The combined application of different membrane-based technologies could be a promising approach over traditionally used methodologies to eliminate the pathogenic microbes resistant to chemical disinfection processes simultaneously with the effective inhibition of bacterial species remultiplication and removal of hazardous chemicals leading to water purification and meeting the standard criteria. Under real conditions, the NF technology may not absolutely serve as the strong barrier for human pathogens including bacteria and viruses (Adham et al., 1998) . Furthermore, the functional efficiency may be reduced with the passage of time because of formation of breaches in the membrane indicating the continuous monitoring of the membrane integrity. The breaches in membranes are generally produced through chemical or biological deterioration processes, aging, scratches caused by particle like substances, membrane fouling, detachment of membrane layers, improper fitting of connectors, O-ring, etc. Apart from abovementioned facts, the defects in membrane may also result during membrane manufacturing processes. Hence, testing the membrane integrity at certain interval of time would be helpful in maintaining the better efficiency of any membrane-based process for water purification targeting against the pathogenic microbes generally encountered in drinking water. The loading of membrane with silver nanoparticle could be a viable approach to stop the membrane biofouling, an important limiting factor diminishing the overall performance of separation process. However, there may be leaching of the loaded nanomaterials into the permeate at some extent. Further improvement in this direction would surely increase the separation efficiency of membrane and could be recommended for industrial scale application to disinfect the drinking water contaminated with different waterborne human pathogens. The human pathogens transmitted through drinking water are one of the major causes of diseases and mortality at global scale. The conventional physicochemical techniques have limitations in separating many of the waterborne pathogens. NF technology on the other hand has shown promising application in purification of water contaminated with pathogenic bacteria, viruses, and protozoa. The discipline of NF technology has gained significant momentum in the academics and water processing industries. During the long course of laboratory studies, there was rapid rise in the number of research publications worldwide. Their ease in operation, high efficacy in removal of different pathogens, absence of DBPs, process flexibility, and robustness have promoted further research in separation technology to improve its overall performance in the area of membrane technology. However, the changes in membrane properties during the long run, clogging of filters, and leaching of adsorbed contaminants in permeate at some extent could limit its exploitation at industrial scale. 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A pooled and meta-analysis of European case control studies Formation of iodinated disinfection byproducts (idbps) in drinking water: emerging concerns and current issues Theory of membrane equilibria and membrane potentials in the presence of non-dialysing electrolytes. A contribution to physicalechemical physiology Impact of independent and non-independent parameters on various elements' rejection by nanofiltration employed in groundwater treatment Zeta-potential and rejection rates of a polyethersulfone nanofiltration membrane in single salt solutions Waterborne infectious diseases-could they be consigned to history? Chlorination byproducts, their toxicodynamics and removal from drinking water Modelling the salt rejection of nanofiltration membranes for ternary ion mixtures and for single salts at different pH values Reverse osmosis of multicomponent electrolyte solutions. Part II. Experimental verification Nanostructured Virus Filtration Membranes Based on Two-Component Columnar Liquid Crystals Assessment of microbial safety of drinking water produced from surfacewater under field conditions Fabrication of flexible self-standing all-cellulose nanofibrous composite membranes for virus removal Mechanism of Cryptosporidium, Giardia, and MS2 virus removal by MF and UF Role of membrane technology in drinking water treatment in the United States Studies evaluating the applicability of utilizing the same concentration techniques for the detection of protozoan parasites and viruses in water A nanofilter composed of carbon nanotube-silver composites for virus removal and antibacterial activity improvement Removal of small nonenveloped viruses by antibody-enhanced nanofiltration during the manufacture of plasma derivatives Aggregation and surface properties of F-specific RNA phages: implication for membrane filtration processes Efficiency of MS2 phage and Qb phage removal by membrane filtration in water treatment: applicability of real-time RT-PCR method Water treatment and pathogen control Survival of Mycobacterium avium, Legionella pneumophila, Escherichia coli, and caliciviruses in drinking waterassociated biofilms grown under high-shear turbulent flow Micro-organism rejection by membrane systems A review on the occurrence of micropollutants in the aquatic environment and their fate and removal during wastewater treatment Virus removal from water and wastewater using membranes Wastewater reclamation at Lake Arrowhead, California: an overview Reverse osmosis technology for water treatment: state of the art review Silver nanomembrane and ceramic silver nanofilter for effective removal of water borne diarrhoegenic Escherichia coli. Ind Virus filtration of high-concentration monoclonal antibody solutions Safe drinking water: an ongoing challenge Resistance of bacterial pathogens to calcium hypochlorite disinfectant and evaluation of the usability of treated filter paper impregnated with nanosilver composite for drinking water purification Preparation of nanofilter from carbon nanotubes for application in virus removal from water Surface modification of membrane filters using graphene and graphene oxide-based nanomaterials for bacterial inactivation and removal Enhanced virus filtration in hybrid membranes with MWCNT nanocomposite The biological threat to the U.S. water supplies: toward a national watersecurity policy Virus removal studies using nanofiltration membranes Review of the dielectric properties of nanofiltration membranes and verification of the single oriented layer approximation Current and emerging techniques for highpressure membrane integrity testing Virus removal in a membrane separation process Nanofiltration membranes for removal of color and pathogens in small public drinking water sources Microbiology of Waterborne Diseases Electrochemical carbon-nanotube filter performance toward virus removal and inactivation in the presence of natural organic matter Tracking host sources of Cryptosporidium spp. in raw water for improved health risk assessment Antibiotic resistance in drinking water systems: occurrence, removal, and human health risks Evaluating the charge of nanofiltration membranes Surveillance of bacterial pathogens associated with acute diarrhea in Lima Laboratory and field evaluation of a nanofilter membrane to remove disinfection byproduct precursors and microogranisms from lake water sources used for drinking water Role of membranes and activated carbonin the removal of endocrine disruptors and pharmaceuticals Carbon nanotube filters Biofouling on RO-membranes used for water recovery in the dairy industry Understanding human infectious Cryptosporidium risk in drinking water supply catchments The effect of flux decay on a 20-nm nanofilter for virus retention Emerging contaminants and membrane technology Impact of repeated pressurization on virus removal by reverse osmosis membranes for household water treatment Integration of membrane bioreactor and nanofiltration for the treatment process of real hospital wastewater in Pneumonia and Diarrhoea: Tackling the Deadliest Diseases for the World's Poorest Children. Statistics and Monitoring Section-Division of Policy and Strategy Adsorption kinetics of Escherichia coli and Staphylococcus aureus on single walled carbonnanotube aggregates Effect of pore structure on membranes and module configuration on virus retention A review of pressure-driven membrane processes in wastewater treatment and drinking water production Nanostructured surface modification of microporous ceramics for efficient virus filtration Global Costs and Benefits of Drinking-Water Supply and Sanitation Interventions to Reach the MDG Target and Universal Coverage Biofilms in drinking water and their role as reservoir for pathogens The role of membrane processes in municipal wastewater reclamation and reuse Virus removal by slow sand filtration and nanofiltration Rejection mechanisms of NF membranes Inactivation and removal of Chikungunya virus and mayaro virus from plasma-derived medicinal products Evaluation of adaptive low cost solar water pasteurization device for providing safe potable water in rural households Evaluation of viral removal by nanofiltration using real-time quantitative polymerase chain reaction Virus rejection with two model human enteric viruses in membrane bioreactor system Integrity of reverse osmosis membrane for removing bacteria: new insight into bacterial passage Inactivation of Norwalk virus in drinking water by chlorine Effect of pH on rejection of different species of arsenic by nanofiltration