Abstract
The Meenachil, the only river that flows through the heart of the Kottayam district of Kerala state, India was selected for the study. The present study has been carried out with an objective to systematically examine the prevalence of indicator and pathogenic microorganisms and to compare the microbiological quality of the river water during the pre-monsoon and post-monsoon seasons. Water samples from 44 different sites during pre-monsoon and post-monsoon seasons were collected for the analysis. During the pre-monsoon period, the faecal coliform count ranged from 230 to 110,000 MPN/100 ml while there was a variation from 200 to 4600 MPN/100 ml during the post-monsoon period. When the faecal streptococci count was analysed, it ranged from 140 to 110,000 MPN/100 ml during the pre-monsoon and 70 to 4600 MPN/100 ml during the post-monsoon seasons, respectively. All the samples collected were found to have total viable count (TVC) higher than those prescribed by Bureau of Indian Standards (ISI 1991). Total viable counts were found in the range of 1.1 × 102 to 32 × 102 cfu/ml in the pre-monsoon and 1.0 × 102 to 26 × 102 cfu/ml in the post-monsoon. The presence of faecal indicator bacteria, Escherichia coli and potentially pathogenic bacteria, Vibrio cholerae, Vibrio parahaemolyticus and Salmonella enterica in the Meenachil River indicates that the bacteriological quality of the Meenachil River is poor. Moreover, it sheds light to the fact that raw sewage is being dumped into the Meenachil River. Urban runoffs and effluents of rubber factories appear to be the important sources of faecal contamination in the river. From this study, we conclude that these water bodies pose significant public health hazards. Adequate sanitary infrastructure will help in preventing source water contamination. Besides this, public health education aimed at improving personal, household and community hygiene is urgent.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Anthropogenic activities result in a significant decrease in surface water quality of aquatic systems in watersheds (Massoud et al. 2006). River inflows contribute many pollutants, thereby tending to induce ecological and hygienic problems (Wang et al. 2007). Escalating water pollution causes not only the deterioration of water quality but it also compromises human wellbeing and the permanence of aquatic ecosystems, economic growth and community affluence (Milovanovic 2007). The surface waters in populous countries have become reservoirs of antimicrobial-resistant pathogenic microbes due to the haphazard use of antimicrobials in human and veterinary medicine and accumulation of faecal contamination through point as well as non-point sources, storm drain infrastructure and malfunctioning septic tanks (Ahmed et al. 2005, Economou et al. 2013). The propensity of species dissemination is influenced by a variety of biotic and abiotic factors including geographical area and demography (Randall et al. 2006). Human faecal material is generally considered to be the greater menace to human health as it is more likely to contain human enteric pathogens (Scott et al. 2003). The most important and desired aspect of water quality is its freedom from contamination with faecal matter. Higher the level of indicator bacteria, greater the level of faecal contamination and greater the risk of water-borne diseases (Pipes 1981). A wide range of pathogenic microorganisms can be transmitted to humans via water contaminated with faecal material. These include unicellular parasites (such as the protozoan Cryptosporidium, Microsporidium, Amoebae) and enteropathogenic agents such as salmonellas, shigellas, enteroviruses and multicellular parasites as well as opportunistic pathogens like Pseudomonas aeroginosa, Klebsiella, Vibrio parahaemolyticus and Aeromonas hydrophila (Karanis et al. 2002; Hodegkiss 1988). It is not feasible to test water for all these organisms. The isolation and identification of many of these organisms are intensely complicated and seldom quantitative (Cairneross et al. 1980; WHO 1983). The most widely used indicators are the coliform bacteria, which may be the total coliform that get narrowed down to the faecal coliforms (FC) and the faecal streptococci (FS) (Kistemann et al. 2002; Pathak and Gopal 2001; Harwood et al. 2001; Vaidya et al. 2001). Concurrently, contamination of water by enteric pathogens has increased globally (Islam et al. 2001; Pathak et al. 1991; Craun 1986). It has been demonstrated that contact with bathing water which has been faecally contaminated enhances the menace of disease (Kay et al. 1994; Fleisher et al. 1993).
The presence of FC as E. coli serves as an indicator for the possible presence of other disease-causing pathogens (Rajkumar and Sharma 2013). FC are selected members of the coliform group of bacteria which are able to ferment lactose at 37 °C and are fairly specific for the faeces of warm-blooded animals. The bacteriological parameters of different river systems have been studied by various groups (Badra et al. 2003; Baghel et al. 2005; Arvanitidou et al. 2005; Schets et al. 2008; Jurzik et al. 2010; Chigor et al. 2013).
The bacteriological examination of water has a special significance in pollution studies. It provides a direct measure of the deleterious effect of pollution on human health. On the other hand, over 1.6 million people directly or indirectly depend on water for various purposes such as agriculture, fishing, transportation and recreation. As a result, water-related diseases are very common in the study area, particularly amongst the young children, though no official reports exist on this. The dearth of reports on the bacteriological quality of Meenachil River calls for attention. Therefore, it is important to carry out this study with the primary goal of determining the bacteriological quality of these essential surface waters and to assess the public health risks emanating from the use of the contaminated water. The present study has been carried out with an objective to systematically examine the prevalence of indicator and pathogenic microorganisms and to compare the microbiological quality of the river water during the pre-monsoon and post-monsoon seasons. The river is part of the tourist circuit in Kerala, and has an important role in making the backwater destination of Kumarakom a highly rated one.
Materials and methods
Study area
Meenachil River (length 78 km, area 1272 km2) originates at an elevation of 1097 m above mean sea level (MSL), in Kerala, in southwestern India. Its watershed extends from 9o25′ to 9o55′N and 76o20′ to 76o55′E (Fig. 1). The general elevation ranges from 77 to 1156 m in the high lands; 8–68 m in the mid lands; and less than 2 m in the low lands. The watershed experiences an average annual rainfall of 3120 mm of which 1646 mm is received after South-West Monsoon (June–September). The river has a total annual yield of 2349 million cubic metres and an annual utilizable yield of 1110 million cubic metres. During monsoon the river can be full and quite often submerge the nearby low lying areas.
Sampling
The sampling sites were selected right from the upstream to downstream of the river. The river originates from Western Ghats grasslands and empties to the largest Ramsar wetland of the state, the Vembanadu Lake. The upstream locations are significant and abound in tourism activities such as contact water sports. In the vicinity of the entire main stream sampling points there are pumping activities for irrigation and drinking purposes. The sampling locations were surrounded by agricultural lands and human settlements. The Meenachil River may be the only river in Kerala, which is characterized by the presence of human settlement right from the source of the river to its cessation at the Vembanad Lake, adversely affecting the river and its basin. The contamination is less till it reaches Erattupetta. Between Erattupetta and Kottayam, the river has to gulp down all the dirt flowing in from the towns like Erattupetta, Bharananaganam, Pala, Kidangoor, Ettumannor and Kottayam. The waste dumping and treatment sites of municipalities are located very close to the main river channel. Majority of the public sewage system opens into the river which in turn results in hepatitis, dysentery, diarrhoea and many contagious diseases as per the reports of the public health department.
Water samples were collected from 44 different sampling sites of Meenachil river basin (MRB), in sterile glass bottles, transported on ice to the laboratory and processed within 6–8 h of collection. Samples were collected during the pre-monsoon (February–May) and post-monsoon (October–January) seasons, from the upper (M1–M19), middle (M20–M35) and lower reaches (M36–M44) of the river basin (Fig. 1).
Bacteriological analysis
A three-tube most probable number (MPN) method was used for the isolation of FC and Escherichia coli using Escherichia coli (EC) broth (Hi-Media Laboratories, India) as medium. 10, 1 and 0.1 ml of appropriately diluted samples were inoculated into respective dilution tubes containing inverted Durham’s tubes. Inoculated tubes were incubated at 44.5 °C for 24 h. Loopful of culture from each tube showing growth and gas production were streaked on Eosine Methylene Blue (EMB, Himedia, Bombay, India) agar for the isolation of E. coli and incubated at 37 °C for 24 h. Typical E. coli-like cultures were isolated, restreaked to ensure purity and corroborated by indole, methyl red, voges proskauer and citrate (IMViC) test. Isolates showing + + − − reaction for IMViC test were confirmed as E. coli.
FS were detected by inoculation of water samples into Azide Dextrose broth (ADB) and incubated at 37.5 ± 1 °C for 24–48 h (APHA 1998). Turbidity in ADB was used for the detection of FS after 24–48 h incubation. In order to confirm the presence of Enterococcus, positive FS tubes in the presumptive MPN tests were streaked onto Pfizer Selective Enterococcus Agar (PSEA), and incubated at 37 °C for 24 h. After incubation, colonies with black colouration were confirmed as typical Enterococcus cells. The source of faecal contamination was identified using FC/FS ratios (US EPA 1978; Geldreich 1974, 1976).
Two methods for isolation of Vibrio parahaemolyticus and V. cholerae were used. The first was a direct plating procedure, which included inoculating 0.2 ml river water sample on Thiosulfate Citrate Bile Salts Sucrose Agar (TCBS, Himedia, and Bombay, India) plates, and incubating at 37 °C for 48 h characterization (Chandran et al. 2008). Blue-green colonies were recorded as V. parahaemolyticus and yellow colonies were considered as V. cholerae and held for further biochemical testing. In the second method, 10 ml of river water samples were inoculated into 40 ml alkaline peptone water for pre-enrichment in a conical flask and incubated at 37 °C for 24 h characterization (Chandran et al. 2008). Flasks showing growth in enrichment broths were streaked onto TCBS agar and incubated at 37 °C for 24–48 h. Typical colonies, whenever present, were isolated, restreaked to ensure purity and maintained on nutrient agar slants for further biochemical.
The cultures were identified according to bacteriological analytical manual (BAM) of United States Food and Drug Administration (USFDA). Cytochrome oxidase (+), Nitrate reduction (+), Voges—Proskauer (−) acid from sucrose (−) and lactose (−), growth in peptone water containing 0 % (2), 3 % (+), 6 % (+) and 8 % (+) NaCl and growth at 43 °C in LIA (+) were considered as V. parahaemolyticus. For V. cholerae, cytochrome oxidase (+), Nitrate reduction (+) Voges—Proskauer (V) acid from sucrose (+) and lactose (−), growth in peptone water containing 0 % (+), 3 % (+), 6 % (−) and 8 % (−) NaCl and growth at 43 °C in LIA (+) were considered confirmatory.
Pseudomonas species were isolated by adopting spread plate method on pseudomonas agar (HI MEDIA) plate and incubated at 37 °C for 24 h. The inoculant from Brain Heart infusion broth was streaked onto MacConkey agar. Streptococcus species were observed by using blood agar swarming test. All the culture media were obtained from Hi-Media Pvt. Ltd., Bombay, India.
Results and discussion
Microbial analyses are presented in Table 1. The bacteriological analysis revealed that all the samples of MRB were contaminated with coliforms, FC and FS. All samples were found to have total viable counts (TVC) higher than those prescribed by Bureau of Indian Standards (ISI 1991). Total viable counts (TVC) were found in the range of 1.1 × 102 to 32 × 102 cfu/ml and 1.0 × 102 to 26 × 102 cfu/ml in the pre-monsoon and post-monsoon, respectively (Table 1). Along the main stream the values of TVC show an escalating trend downstream. Furthermore, the lower reaches show high count of total coliform of 2.5 × 102 to 11.3 × 102 and 1.5 × 102 to 8.5 × 102 in the pre-monsoon and post-monsoon, respectively.
The FC count ranged from 230 to 110,000 MPN/100 ml during the pre-monsoon and 200 to 4600 MPN/100 ml during the post-monsoon period (Table 1). High values of FC were recorded during the pre-monsoon season. The irregular variations in the coliform bacteria due to seasonal changes corroborated the findings of Legendre et al. (1984), Barcina (1986) and Ramanibai (1996). The existence of other members of the FC group (Klebsiella, Enterobacter and Citrobacter) was reported for non-faecal origin (Alonso et al. 1998). The higher FC has indicated the tolerance of high temperature as shown in Table 1. This result coincides with the observation of Ravichandran and Ramanibai (1988).
FS have been proposed as the possible alternative indicator bacteria to E. coli. They have greater persistence in water and will not multiply in polluted environments. There is also evidence that these bacteria have a stronger relationship to adverse health outcomes than E. coli (Moe et al. 1991). It is clear from our results that the count of FS increases from 140 to 110,000 MPN/100 ml and 70 to 4600 MPN/100 ml during pre-monsoon and post-monsoon, respectively in the MRB (Table 1). The lower reaches evidently displayed high counts of FS.
Population of aquatic microbiota is influenced by many environmental parameters. The increasing presence of pollution indicator bacteria in river water is a frequent hitch in urban and rural areas, often leading to outbreaks of serious water-borne diseases like cholera, dysentery, etc. The bacteriological analysis revealed that the entire sample collected from four different sites of the Meenachil River was contaminated with coliform, faecal coliform (FC) and other pathogenic bacteria. This may be attributed to the large number of pilgrims and tourists who visit the area in summer. Inadequate facilities for sanitation result in pumping untreated sewage into the river. It is clear from the results that the maximum count of FS is observed in the pre-monsoon season. FC and FS ratio is given in the Fig. 2. Probably, the sites with FC/FS ratio above one may have contamination by human faecal matter (Araujo et al. 1989). The Meenachil River may be the only river in Kerala, which is characterized by the presence of human settlement right from the source of the river to its final debouching point at the Vembanad Lake, adversely affecting the river and the river basin. The sewage from hotels and lodges flows into the riverine systems, polluting its freshwater ecosystem. Kistemann et al. (2002) observed that in case of rainfall, the microbial loads of running water may get amplified and reach reservoir bodies swiftly. The above observation indicates that the bacterial contamination increases from the upper reaches to the lower reaches. This may be due to increased anthropogenic activities at different sites along the lower reaches. Rapid development of the townships in the surrounding vicinity of the lower reach may also have added to the increased runoff and to an extent enhancing the degradation of the river water quality. Toilets in the urban agglomerations are located along the river banks and have their outlets into the river systems (Photo 1). McLellan et al. (2001) stated that faecal pollution indicator organisms can be used to monitor a number of conditions related to the health of aquatic ecosystems and the potential for adverse health impacts among individuals using these aquatic environments. The presence of such indicator organisms may provide indications of water-borne problems and is a direct threat to human and animal health.
The Meenachil river system is the major source of drinking water for the population along the river banks. Drinking water can be contaminated with these pathogenic bacteria, and this is an issue of great concern. However, the presence of pathogenic bacteria in water is sporadic and erratic, levels are low, and the isolation and culture of these bacteria is not straightforward. For these reasons, routine water microbiological analysis does not include the detection of pathogenic bacteria. However, safe water demands that water is free from pathogenic bacteria.
It is universally accepted that higher sewage contamination would lead to increased number of coliform and FC in natural water bodies. Hansen and Bech (1996) clearly suggest that there is a proliferation of allochthonous microflora in the river environment. As inestimable quantities of pathogenic bacteria constitute the microflora of effluents discharged from different anthropogenic activities, quantifying different groups of pathogenic bacteria have to be part of surveys on water quality. For instance, information on occurrence, abundance and distribution of potent human pathogens, Vibrio cholera (causing cholera in humans), Vibrio parahaemolyticus (gastroenteritis), Salmonella and Shigella sp. (typhoid fever, food poisoning), Streptococcus sp. (meningitis and skin infections) and Pseudomonas aeruginosa (pulmonary and lung infections) in aquatic environment may prove useful in public health management.
In this context, an attempt was made to identify the bacterial species in the Meenachil river systems (Table 2). The consistently high load of the pollution indicator E. coli and its isolation from all the stations indicated that the water body is undergoing severe sewage pollution (Photo 6 and 7). This is due to human interference through settlements along the main reach and mixing of untreated municipality sewage with the river waters. E. coli is normally found in human and animal intestines and is the most reliable indicator of faecal contamination in water, which indicates the possible presence of pathogens (Geldreich and Clarke 1966).
All through the study period and at all sites, E. faecalis counts were lower than E. coli counts. Similar observations were made by Lanusse (1987), Fernandez-Alvarez et al. (1991), Chahlaoui (1996) and Hunter et al. (1999). This is owing to a difference in the rate of decline which is faster for E. fecalis (Hunter et al. 1999).
According to WHO (1992) the guideline criteria for faecal indicator bacteria for bathing waters, is: bacteria up to 500/100 ml for total coliforms, and 100/100 ml for both faecal coliforms and Enterococci. The survey of the indicator bacteria along the Meenachil river basin revealed that the waters are subjected to sewage pollution and are unfit for bathing. The counts of faecal coliforms (E. coli) exceeded 100 per ml all through the sampling stations. This is primarily due to excessive land runoff containing raw sewage and faecal debris, which in turn supports the proliferation of the tested faecal bacteria.
Pathogenic bacteria which may cause serious problem for human health have been studied mostly for their survival in the aquatic ecosystem (Sood et al. 2008; Nagvenkar and Ramaiah 2009; Harakeh et al. 2006; Servais et al. 2007; Sigua et al. 2010). Servaais et al. (2007) studied faecal contamination of the main rivers of the Seine watershed (Seine, Marne, Oise rivers) and found high levels of microbiological pollution when compared to European guidelines for bathing waters. They also found that the discharge of treated urban waste water effluents can significantly degrade the microbiological quality of rivers. The presence of Pseudomonas spp. in all the sites in all seasons may be attributed to human activities and sewage discharge to these sites. Pathogenic bacteria such as S. aureus, P. aeruginosa, and Salmonella sp. were isolated and identified. High level of incidence of S. aureus, P. aeruginosa and Salmonella sp. was observed during the post-monsoon season. The relatively high levels of prevalence of pathogenic bacteria during the rainy season suggest high influx of sewage, soil leaching and flooding as well as good survival capabilities of these microorganisms to changing hydrographic parameters (Mohamed et al. 2008). Sigua et al. (2010) too have demonstrated that a positive relationship exists between the variability of faecal contamination levels and agricultural cover. This substantiates the mounting risk of enhanced contamination occurring rapidly during the rainy season as agricultural cover increases.
In Kerala, Hepatitis-A, Typhoid, acute Diarrhoeal Diseases and Cholera are the major water-borne diseases (Shylaja 2009). Leptospirosis, acute dysentery, typhoid fever and acute hepatitis were reported from Kottayam district (John et al. 2004). Salmonella is widespread worldwide and is transmitted by ingestion of contaminated food and water. Its presence in river waters makes these waters unfit even for bathing. P. aeruginosa is present in the waters of Meenachil river basin but in very minor quantities. The presence of this bacterium poses a risk to swimmers because it is responsible for ear infections. The high incidence of human pathogenic bacteria in the river may indicate their possible presence in fish and other foods derived from this source.
In this study, water collected from majority of the sites were not suitable for domestic uses as it exceeds maximum permissible limits of total coliform and total FC as per the standards of National River Conservation Directorate, India. McLellan et al. (2001) stated that faecal pollution indicator organisms can be used to determine the number of cases related to the impacts on human health as well as health of aquatic ecosystems. The presence of such indicator organisms may provide information regarding water-borne diseases and is a direct threat to human, animal and aquatic organisms. The study clearly exposes the fact that water becomes unhealthy for drinking as well as domestic purposes because of contamination due to industrial and domestic litter. The present study has obviously demonstrated that there is a significant occurrence of bacterial pollution indicators and pathogenic bacterial groups in the Meenachil river. The condition of the river is very alarming.
Conclusion
The detection and isolation of E. coli and V. parahaemolyticus, V. cholerae and S. enterica from Meenachil river basin indicates the frequent discharge of sewage containing pathogenic microorganisms into the riverine ecosystem. Moreover, it throws light on the extended survival of these organisms to a detectable level at higher concentrations. The survival and persistence of these bacteria in natural environments is a matter of great concern. The public health is at hazard as the population in this region depends on this water body for numerous domestic reasons. Apart from it, this water body sustains major fish and shellfish resources. The people of Kottayam mainly depend on Meenachil river for fish. There is a great chance of food-borne epidemics due to the presence of these pathogenic bacteria in fishes. The observations clearly indicate that all the studied sites of the Meenachil River have been contaminated with water-borne pathogenic bacteria. This may be due to increased anthropogenic and socio-cultural activities at different sites of the Meenachil River. Overall, the bacteriological analysis of the Meenachil River water reveal that the water is polluted by sewage, faecal contaminants and industrial wastes and this water is not appropriate for drinking and recreational purposes. Regular monitoring of microbial contamination in the water of the Meenachil River should be an essential component in future public health protection strategies.
References
Ahmed W, Neller R, Katouli M (2005) Host species-specific metabolic fingerprint database for Enterococci and Escherichia coli and its application to identify sources of fecal contamination in surface waters. Appl Environ Microbiol 71:4461–4468
Alonso JL, Soriano A, Amoros I, Ferre MA (1998) Quantitative determination of Escherichia coli and fecal coliforms in water using a chromogenic medium. J Environ Sci Health A 33(6):1229–1248
Araujo RM, Arribas RM, Lucena F, Pares R (1989) Relation between Aeromonas and faecal coliforms in fresh waters. J Appl Bacteriol 67:213–217
Arvanitidou M, Kanellou K, Vagiona DG (2005) Diversity of Salmonella spp. and fungi in northern Greek rivers and the correlation to faecal pollution indicators. Environ Res 99:278–284
Badra B, Mukherjee S, Chakraborty R, Nanda AK (2003) Physicochemical and bacteriological investigation on the river Torsa of North Bengal. J Environ Biol 24:125–133
Baghel VS, Gopal K, Dwivedi S, Tripathi RD (2005) Bacterial indicators of faecal contamination of the Gangetic river system right at its source. Ecol Indic 5:49–56
Barcina I (1986) Factors affecting the survival of Escherichia coli in a river. Hydrobiologia 141:249–253
Cairneross S, Carruthers I, Curtis D, Feachem R, Bradley D, Baldwin G (1980) Evaluation for Village Water Supply Planning. Wiley, Chichester, p 277
Chahlaoui A (1996) Hydrological study of river Boufekrane (Meknes), Impact on Environment and Health. Dissertation, Fac Sc, Meknes, Universite Moulay Ismail, Morocco
Chandran A, Hath AAM, Varghese S (2008) Increased prevalence of indicator and pathogenic bacteria in Vembanadu Lake: a function of salt water regulator, along south west coast of India. J Water Health 06:539–546
Chigor VN, Sibanda T, Okoh AI (2013) Studies on the bacteriological qualities of the Buffalo River and three source water dams along its course in the Eastern Cape Province of South Africa. Environ Sci Pollut Res 20:4125–4136
Craun GF (1986) Water borne disease in the United States. CRC Press, Boca Raton
Economou V, Gousia P, Kansouzidou A, Sakkas H, Karanis P, Papadopoulou C (2013) Prevalence, antimicrobial resistance and relation to indicator and pathogenic microorganisms of Salmonella enterica isolated from surface waters within an agricultural landscape. Int J Hyg Environ Health 26(4):435–444
Fernandez-Alvarez RM, Carballo-Cuervo S, De la Rosa-Jorge MC, Rodriguez de Lecea J (1991) The influence of agricultural run-off on bacterial populations in a river. J Appl Bacteriol 70:437–442
Fleisher JM, Jones F, Kay D, Stanwell-Smith R, Wyer M, Morano R (1993) Water and non-water-related risk factors for gastroenteritis among bathers exposed to sewage-contaminated marine waters. Int J Epidemiol 22:698–708
Geldreich EE (1974) Microbiology of water. J Water Pollut Control Fed 46:1355–1372
Geldreich EE (1976) Faecal coliform and faecal streptococcus density relationships in waste discharges and receiving waters. Critical Rev Environ Contr 6:349–369
Geldreich EE, Clarke NA (1966) Bacterial pollution indicators in the intestinal tract of freshwater fish. Appl Microbiol 14:429–437
Hansen B, Bech G (1996) Bacteria associated with a marine planktonic copepod in culture. I. Bacterial genera in seawater, body surface, intestines and faecal pellets and succession during faecal pellet degradation. J Plankton Res 18:257–273
Harakeh S, Yassine H, El-Fadel M (2006) Antimicrobial-resistant patterns of Escherichia coli and Salmonella strains in the aquatic Lebanese environments. Environ Pollut 143:269–277
Harwood VJ, Brownell M, Perusek W, Whitelock JE (2001) Vancomycin-resistant Enterococcus sp. isolated from waste water and chicken feces in the United States. Appl Environ Microbiol 67:4930–4933
Hodegkiss IJ (1988) Bacteriological monitoring of Hong Kong marine water quality. Environ Int 14:495–499
Hunter C, Perkins J, Trunter J, Gunn J (1999) Agricultural land-use effects on the indicator bacterial quality of an upland stream in the Derbyshire Peak District in the UK. Water Res 33(17):3577–3586
ISI (1991) Indian Standard Specification for drinking water, IS: 10500. New Delhi
Islam MS, Siddika A, Khan MNH, Goldar MM, Sadique MA, Kabir ANMH, Huq A, Colwell RR (2001) Microbiological analysis of tube-well water in a rural area of Bangladesh. Appl Environ Microbiol 67:3328–3330
John TJ, Rajappan K, Arjunan KK (2004) Communicable diseases monitored by disease surveillance in Kottayam district, Kerala state, India. Indian J Med Res 120:86–93
Jurzik L, Hamzaa IA, Puchertb W, Überlac K, Wilhelma M (2010) Chemical and microbiological parameters as possible indicators for human enteric viruses in surface water. Int J Hyg Environ Health 213:210–216
Karanis P, Papadopoulou C, Kimura A, Economou E, Kourenti C, Sakkas H (2002) Cryptosporidium and Giardia in natural, drinking, and recreational water of Northwestern Greece. Acta Hydrochim et Hydrobiolog 30(1):49–58
Kay D, Fleisher JM, Salmon RL, Jones F, Wyer MD, Godfree AF, Zelenauch-Jacquotte Z, Shore R (1994) Predicting likelihood of gastroenteritis from sea bathing, results from randomised exposure. Lancet 344(8927):905–909
Kistemann T, Claben T, Koch C, Dangendorf F, Fischeder R, Gebel J, Vacata V, Exner M (2002) Microbial load of drinking water reservoir Tributaries during extreme rainfall and runoff. Appl Environ 66(5):2188–2197
Lanusse A (1987) Microbial contamination of a tropical lagoon (lagoon Ebrié, Ivory Coast) - Influence of hydroclimate. Ph.D. Thesis, University of Provence, Aix-Marseille-I, France
Legendre P, Baleux B, Troussellier M (1984) Dynamics of pollution indicator and heterotrophic bacteria in sewage treatment lagoons. Appl Environ Microbiol 48:586–593
Massoud MA, El-Fadel M, Scrimshaw MD, Lester JN (2006) Factors influencing development of management strategies for the Abou Ali River in Lebanon: i. Spatial variation and land use. Sci Total Environ 362:15–30
McLellan SL, Daniels AD, Salmore AK (2001) Clonal populations of thermotolerant enterobacteriaceaes in recreational water and their potential interference with fecal Escherichia coli counts. Appl Evniron Microbiol 67:4934–4938
Milovanovic M (2007) Water quality assessment and determination of pollution sources along the Axios/Vardar River, Southeastern Europe. Desalination 213:159–173
Moe CL, Sobsey MD, Samsa GP, Mesolo V (1991) Bacterial indicators of risk of diarrhoeal disease from drinking water in the Philippines. Bull WHO 69(3):305–317
Mohamed H, Abirosh H, Sherin V (2008) Increased prevalence of indicator and pathogenic bacteria in the Kumarakam Lake: a function of salt water regulator in Vembanadu Lake, A Ramsar Site, along West coast of India. In: Sengupta M, Dalwani R (eds) Proceedings of Taal 2007, the 12th World Lake Conference. pp 250–256
Nagvenkar GS, Ramaiah N (2009) Abundance of sewage-pollution indicator and human pathogenic bacteria in a tropical estuarine complex. Environ Monit Assess 155:245–256
Pathak SP, Gopal K (2001) Rapid detection of Escherichia coli as an indicator of faecal pollution in water. Ind J Microbiol 41:139–151
Pathak SP, Mathur N, Dev B (1991) Effect of socio biological activities on microbial contamination of river water in different reasons. Environ Pollut Resour Lan Water :245–254
Pipes WO (1981) Bacterial indicators of pollution. CRC Press Inc., Boca Raton, p 242
Rajkumar B, Sharma GD (2013) Seasonal bacteriological analysis of Barak River, Assam, India. Appl Water Sci 3:625–630
Ramanibai R (1996) Seasonal and spatial abundance of pollution indicator bacteria in Buckingham canal madras. Indian J Environ Prot 17(2):110–114
Randall SS, Ward MP, Maldonado G (2006) Can landscape ecology untangle the complexity of antibiotic resistance. Nat Rev Microbiol 4(12):943–952
Ravichandran S, Ramanibai PS (1988) Plankton and related parameters of Buckingham canal a canonical correlation analysis. Arch Hydrobiol 114:117–123
Schets FM, van Wijnen JH, Schijven JF, Schoon H, de Roda Husman AM (2008) Monitoring of waterborne pathogens in surface waters in Amsterdam, The Netherlands, and the potential health risk associated with exposure to Cryptosporidium and Giardia in these waters. Appl Environ Microbiol 74:2069–2078
Scott TM, Salina P, Portier KM, Rose JB, Tamplin ML, Farrah SR, Koo A, Lukasik J (2003) Geographical variation in ribotype profiles of Escherichia coli isolates from human, swim, poultry, beef and dairy cattle in Florida. Appl Environ Microbiol 69(2):1089–1092
Servais P, Garcia-Armisen T, George I, Billen G (2007) Fecal bacteria in the rivers of the Seine drainage network (France): sources, fate and modelling. Sci Total Environ 375:152–167
Shylaja K (2009) Combating communicable diseases. Kerala Calling July, 46–47
Sigua GC, Palhares JCP, Kich JD, Mulinari MR, Mattei RM, Klein JB, Muller S, Plieske G (2010) Microbiological quality assessment of watershed associated with animal-based agriculture in Santa Catarina, Brazil. Water Air Soil Pollut 210:307–316
Sood A, Singh KD, Pandey P, Sharma S (2008) Assessment of bacterial indicators and physicochemical parameters to investigate pollution status of Gangetic river system of Uttarakhand (India). Ecol Indic 8:709–717
US EPA (1978) Microbiological Method for Monitoring the Environment: Water and Wastes. Envir. Monitor. and Supp. Lab., Off. Res and Dev., US Envir. Protect. Agen., Cincinnati. Ohio
Vaidya SY, Vala AK, Dube HC (2001) Bacterial indicators of faecal pollution and Bhavnagar Coast, India. J Microbiol 41:37–39
Wang X, Lu Y, Han J, He G, Wang T (2007) Identification of anthropogenic influences on water quality of rivers in Taihu watershed. J Environ Sci 19:475–481
WHO (1983) Guidelines for drinking water quality, vol 3. World Health Organization, Geneva
WHO (1992) Our planet, our health. World Health Organization, Geneva
Author information
Authors and Affiliations
Corresponding author
Electronic supplementary material
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
About this article
Cite this article
Vincy, M.V., Brilliant, R. & Pradeepkumar, A.P. Prevalence of indicator and pathogenic bacteria in a tropical river of Western Ghats, India. Appl Water Sci 7, 833–844 (2017). https://doi.org/10.1007/s13201-015-0296-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s13201-015-0296-9