Foodborne Viruses and Somatic Coliphages Occurrence in Fresh Produce at Retail from Northern Mexico.

Foodborne disease outbreaks linked to consumption of vegetables have been often attributed to human enteric viruses, such as Norovirus (NoV), Hepatitis A virus (HAV), and Rotavirus (RoV). Information about the occurrence of these viruses is scarce in many fresh-producing countries. Viral contamination detection of indicators, such as somatic coliphages, could indirectly reflect the presence of viral pathogens, being a valuable tool for better viral risk assessment in food industry. This study aimed to establish the occurrence and correlation of foodborne viruses and somatic coliphages in leafy greens in northern Mexico. A total of 320 vegetable samples were collected, resulting in 80 composite rinses, 40 of lettuce and 40 of parsley. Somatic coliphages were determined using the EPA 1602 method, while foodborne viruses (HAV, RoV, NoV GI, and GII) were determined by qPCR. The occurrence of RoV was 22.5% (9/40, mean 2.11 log gc/g) in lettuce and 20% (8/40, mean 1.91 log gc/g) in parsley. NoV and HAV were not detected in any samples. Somatic coliphages were present in all lettuce and parsley samples, with mean levels of 1.85 log PFU/100 ml and 2.28 log PFU/100 ml, respectively. Spearman analysis established the correlation of somatic coliphages and genomic copies of RoV, resulting in an r2 value of - 0.026 in lettuce and 0.349 in parsley. Although NoV or HAV were undetected in the samples, the presence of RoV is a matter of concern as leafy greens are usually eaten raw, which poses a potential risk of infection.

Somatic Coliphages as an Operational Tool to Assess Loss of Bathing Water Quality after Heavy Rain Events.

Rapid population growth and coastal development has led to increased fecal contamination of coastal surface waters worldwide, enhancing the potential risk of waterborne human pathogens in bathing areas. More frequent heavy rainfall events, attributed to global warming, have further exacerbated the problem by causing sometimes sewer overflows into recreational waters. As traditional bacterial indicators have limited accuracy for predicting health risks associated with waterborne viruses, the additional use of viral indicators such as coliphages is recommended. In this study, we compared the behavior of bacterial and viral indicators of water quality at 10 Barcelona beaches during three bathing seasons, in dry conditions, and after four rainstorms that caused specific pollution events due to rain runoff with combined sewer overflows (CSO). Levels of all target indicators increased after the rainstorms, but compared to Escherichia coli and intestinal enterococci, somatic coliphages exhibited a slower decline and higher environmental persistence following a rain event. Daily continuous sampling carried out during the days following a rainstorm allowed not only the determination of the decay kinetics of each target indicator but also the day when the water quality recovered the values established in the current European regulation in approximately 2 -3 days after each CSO. These observations indicate that the combined use of bacterial and viral indicators can enhance the surveillance of microbial quality of bathing waters. Moreover, coliphages can swiftly provide insights into transient fecal pollution linked to rainfall episodes, thanks to available analytical techniques that enable same-day recommendations. The management of urban wastewater and recreational water regulations should consistently employ microbial indicators to address rainwater runoff or sewer overflows resulting from heavy rainfall.

A new understanding of somatic coliphages belonging to the Microviridae family in urban wastewater.

Somatic coliphages (SC) and F-specific RNA coliphages (FRNAPH) have been included in regulations or guidelines by several developed countries as a way of monitoring water safety and the microbiological quality of shellfish harvesting waters. SC are highly diverse in their morphology, size and genome. The Microviridae family contains three genera of phages (Alphatrevirus, Gequatrovirus, and Sinsheimervirus), all having a capsid of similar morphology (icosahedral) and size (25-30 nm in diameter) to that of common pathogenic enteric viruses. Three PCR assays specific for each genus of Microviridae were designed to study these phages in raw and treated wastewater (WW) in order to gain knowledge about the diversity and prevalence of Microviridae among SC, as well as their inactivation and removal during WW treatments. Among the four wastewater treatment plants (WWTPs) monitored here, two WWTPs applied disinfection by UV light as tertiary treatment. First, we noticed that Microviridae represented 10 to 30 % of infectious SC in both raw and treated WW. Microviridae appeared to behave in the same way as all SC during these WW treatments. As expected, the highest inactivation, at least 4 log10, was achieved for infectious Microviridae and SC in both WWTPs using UV disinfection. PCR assays showed that the highest removal of Microviridae reached about 4 log10, but the phage removal can vary greatly between WWTPs using similar treatments. This work forms the basis for a broader evaluation of Microviridae as a viral indicator of water treatment efficiency and WW reuse.

Modeling human pollution in water bodies using somatic coliphages and bacteriophages that infect Bacteroides thetaiotaomicron strain GA17.

The ability to detect human fecal pollution in water is of great importance when assessing the associated health risks. Many microbial source tracking (MST) markers have been proposed to determine the origin of fecal pollution, but their application remains challenging. A range of factors, not yet sufficiently analyzed, may affect MST markers in the environment, such as dilution and inactivation processes. In this work, a statistical framework based on Monte Carlo simulations and non-linear regression was used to develop a classification procedure for use in MST studies. The predictive model tested uses only two parameters: somatic coliphages (SOMCPH), as an index of general fecal pollution, and human host-specific bacteriophages that infect Bacteroides thetaiotaomicron strain GA17 (GA17PH). Taking into account bacteriophage dilution and differential inactivation, the threshold concentration of SOMCPH was calculated to be around 500 PFU/100 mL for a limit of detection of 10 PFU/100 mL. However, this threshold can be lowered by increasing the analyzed volume sample, which in turn lowers the limit of detection. The resulting model is sufficiently accurate for application in practical cases involving MST and could be easily used with markers other than those tested here.

Somatic coliphages are conservative indicators of SARS-CoV-2 inactivation during heat and alkaline pH treatments.

High concentrations of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) genome have been described in wastewater and sewage sludge. It raises the question of the security of land sludge disposal practices during a pandemic. This study aimed to compare SARS-CoV-2's resistance to the main inactivating factors in sludge treatments, pH and heat, to that of native wastewater somatic coliphages. The latest can be easily used as an indicator of treatment efficiency in the field. The effects of heat treatment and pH on the survival of SARS-CoV-2 and somatic coliphages were investigated in simple media. The T90 value (time required for a 90% reduction in the virus or a 1 × log10 decline) at 50 °C was about 4 min for infectious SARS-CoV-2, and around 133 min for infectious somatic coliphages, with no decrease in SARS-CoV-2 genome. For infectious SARS-CoV-2, a slight decrease (<1 log10 unit) was observed at pH 9 or 10 for 10 min; the decrease was over 5 log10 units at pH 11. However, both SARS-CoV-2 genome and infectious somatic coliphages decreased by less than 1 log10 unit at pH 12. All thermal or pH-based treatments that can remove or significantly reduce infectious somatic coliphages (>4 log10) can be considered efficient treatments for infectious SARS-CoV-2. We concluded that somatic coliphages can be considered highly conservative and easy to use indicators of the inactivation of SARS-CoV-2 during treatments based on heat and alkaline pH.

Evaluation of New Components in Modified Scholten's Medium for the Detection of Somatic Coliphages.

Enteric bacteriophages (somatic coliphages, F-specific coliphages or both together) are now recognized as useful viral indicators in water, shellfish, and biosolids and are being progressively included in national and international sanitary regulations. Among them, somatic coliphages have an advantage in that they usually outnumber F-RNA coliphages in water environments. Their enumeration using Modified Scholten's (MS) media, following the ISO 10705-2 standard for the growth of Escherichia coli host strain WG5, is highly efficient and a common practice worldwide. These media contain a high concentration of nutrients, which may be modified to save costs without loss of bacterial growth host efficiency. This study explored reducing the concentration of nutrients in the current formulation and/or incorporating new components to improve the host bacterial growth and/or the enumeration of somatic coliphages at an affordable analytical cost. A twofold dilution of the original MS media was found not to affect the bacterial growth rate. The addition of combinations of assayed compounds to twofold diluted MS media slightly enhanced its analytical performance without altering bacterial growth. By generating savings in both cost and time while maintaining optimal results, media dilution could be applied to design new simple applications for coliphage enumeration.

Enteric viruses, somatic coliphages and Vibrio species in marine bathing and non-bathing waters in Italy.

Microbial safety of recreational waters is a significant public health issue. In this study we assessed the occurrence and quantity of enteric viruses in bathing and non-bathing waters in Italy, in parallel with microbial faecal indicators, somatic coliphages and Vibrio spp. Enteric viruses (aichivirus, norovirus and enterovirus) were detected in 55% of bathing water samples, including samples with bacterial indicator concentrations compliant with the European bathing water Directive. Aichivirus was the most frequent and abundant virus. Adenovirus was detected only in non-bathing waters. Somatic coliphages were identified in 50% bathing water samples, 80% of which showed simultaneous presence of viruses. Vibrio species were ubiquitous, with 9 species identified, including potential pathogens (V. cholerae, V. parahaemoylticus and V. vulnificus). This is the first study showing the occurrence and high concentration of Aichivirus in bathing waters and provides original information, useful in view of a future revision of the European Directive.

New approach for the simultaneous detection of somatic coliphages and F-specific RNA coliphages as indicators of fecal pollution.

Two groups of coliphages have been recently included in different water management policies as indicators of viral fecal pollution in water and food: somatic coliphages, which infect E. coli through cell wall receptors, and F-specific RNA coliphages, which infect through the F-pili. Somatic coliphages are more abundant in fecally contaminated waters, except reclaimed waters, those disinfected by UV irradiation, and some groundwater samples that show a higher level of F-specific coliphages. Somatic coliphages are morphologically similar to DNA enteric viruses while F-specific coliphages are similar to RNA viruses such as norovirus and hepatitis A viruses, which are the viral pathogens of concern in sewage. The use of strains sensitive to both types of phages has been proposed for total coliphage enumeration, thereby avoiding double analysis. The standardized methods available for coliphage detection are robust and cost-effective, but the introduction of ready-to-use methods would facilitate routine implementation in laboratories. The fastest available tool for somatic coliphage enumeration is the recently developed Bluephage, which uses a modified ß-glucuronide-overexpressing E. coli strain unable to take up the glucuronide substrate. The overexpressed enzyme accumulates inside the bacterial cells until released by phage-induced cell lysis, whereupon it encounters its substrate and the medium changes from yellow to blue. The present method uses E. coli strain CB12, sensitive to somatic coliphages and F-specific coliphages due to the expression of the F-pili. The Bluephage approach incorporating CB12 detects both types of coliphages in a time range of 1:30 to 4:00 h, as assayed with coliphages from raw sewage, river water, sludge and mussels. This strategy can be applied to obtain qualitative and quantitative results and is applicable to microplates as well as to large sample volumes (100 ml). Moreover it can provide monitoring of water bodies at real time, as for example for ambient recreational beach monitoring.

Human adenoviruses as waterborne index pathogens and their use for Quantitative Microbial Risk Assessment.

The current microbial water quality standards are based on the monitoring of fecal indicator organisms, which are mainly bacterial indicators (i.e., Escherichia coli, intestinal enterococci), however epidemiological data indicate that viruses are important etiological agents of waterborne illnesses. Among waterborne viruses, human adenovirus can be considered as an index pathogen, owing to its abundance in sewage and persistence in the environment, as well as its potential infectivity. In this study, data on human adenoviruses from different water matrices (the entrance and exit of a water treatment plant, rivers and seawaters) were analyzed, in parallel with traditional fecal bacterial indicators and somatic coliphages. The results showed a 64% frequency of positive adenovirus samples, decreasing from the sewage system (100% at the entrance and 94% at the exit) to rivers (92% and 72% for different rivers) and seawater (21%). Adenovirus concentrations showed a significant correlation with somatic coliphages in one river and seawater, thus supporting the recent inclusion of coliphages as viral indicators in water safety guidelines. The data collected were used to estimate adenovirus to indicator ratios, which could be used as input in Quantitative Microbial Risk Assessment (QMRA) studies.

Use of coliphages to investigate norovirus contamination in a shellfish growing area in Republic of Korea.

A number of severe norovirus outbreaks due to the consumption of contaminated shellfish have been reported recently. In this study, we evaluated the distribution of coliphage densities to determine their efficacy as fecal indicators of enteric viruses, including noroviruses, in water samples collected from a shellfish growing area in Republic of Korea over a period of approximately 1 year. Male-specific and somatic coliphages in water samples were analyzed using the single agar layer method, and norovirus genogroups I and II, which infect mainly humans, were analyzed using duplex reverse transcription quantitative PCR. Male-specific and somatic coliphages were detected widely throughout the study area. Several environmental parameters, including salinity, precipitation, temperature, and wind speed were significantly correlated with coliphage concentrations (P < 0.05). Moreover, the concentrations of male-specific coliphages were positively correlated with the presence of human noroviruses (r = 0.443; P < 0.01). The geospatial analysis with coliphage concentrations using a geographic information system revealed that densely populated residential areas were the major source of fecal contamination. Our results indicate that coliphage monitoring in water could be a useful approach to prevent norovirus contamination in shellfish.

Reduction of bacteria and somatic coliphages in constructed wetlands for the treatment of combined sewer overflow (retention soil filters).

Combined sewer overflows (CSOs) introduce numerous pathogens from fecal contamination, such as bacteria and viruses, into surface waters, thus endangering human health. In Germany, retention soil filters (RSFs) treat CSOs at sensitive discharge points and can contribute to reducing these hygienically relevant microorganisms. In this study, we evaluated the extent of how dry period, series connection and filter layer thickness influence the reduction efficiency of RSFs for Escherichia coli (E. coli), intestinal enterococci (I. E.) and somatic coliphages. To accomplish this, we had four pilot scale RSFs built on a test field at the wastewater treatment plant Aachen-Soers. While two filters were replicates, the other two filters were installed in a series connection. Moreover, one filter had a thinner filtration layer than the other three. Between April 2015 and December 2016, the RSFs were loaded in 37 trials with pre-conditioned CSO after dry periods ranging from 4 to 40 days. During 17 trials, samples for microbial analysis were taken and analyzed. The series connection of two filters showed that the removal increases when two systems with a filter layer of the same height are operated in series. Since the microorganisms are exposed twice to the environmental conditions on the filter surface and in the upper filter layers, there is a greater chance for abiotic adsorption increase. The same effect could be shown when filters with different depths were compared: the removal efficiency increases as filter thickness increases. This study provides new evidence that regardless of seasonal effects and dry period, RSFs can improve hygienic situation significantly.

The application of phage-based faecal pollution markers to predict the concentration of adenoviruses in mussels (Mytilus edulis) and their overlying waters.

AIM: This study set out to determine whether phage-based indicators may provide a 'low-tech' alternative to existing approaches that might help maintain the microbial safety of shellfish and their overlying waters. METHODS AND RESULTS: Mussels and their overlying waters were collected biweekly from an estuary in southeast England over a 2-year period (May 2013-April 2015) (n = 48). Levels of bacterial indicators were determined using membrane filtration and most probable number methods and those of bacteriophages were determined by direct plaque assay. The detection of adenovirus was determined using real-time polymerase chain reaction. The results revealed that somatic coliphages demonstrated the most significant correlations with AdV F and G in mussels (ρ = 0·55) and overlying waters (ρ = 0·66), followed by GB124 phages (ρ = 0·43) while Escherichia coli showed no correlation with AdV F and G in mussels. CONCLUSION: This study demonstrates that the use of somatic coliphages and GB124 phages may provide a better indication of the risk of adenovirus contamination of mussels and their overlying waters than existing bacterial indicators. SIGNIFICANCE AND IMPACT OF THE STUDY: Phage-based detection may be particularly advantageous in low-resource settings where viral infectious disease presents a significant burden to human health.

Development of multiple linear regression models as predictive tools for fecal indicator concentrations in a stretch of the lower Lahn River, Germany.

Since rivers are typically subject to rapid changes in microbiological water quality, tools are needed to allow timely water quality assessment. A promising approach is the application of predictive models. In our study, we developed multiple linear regression (MLR) models in order to predict the abundance of the fecal indicator organisms Escherichia coli (EC), intestinal enterococci (IE) and somatic coliphages (SC) in the Lahn River, Germany. The models were developed on the basis of an extensive set of environmental parameters collected during a 12-months monitoring period. Two models were developed for each type of indicator: 1) an extended model including the maximum number of variables significantly explaining variations in indicator abundance and 2) a simplified model reduced to the three most influential explanatory variables, thus obtaining a model which is less resource-intensive with regard to required data. Both approaches have the ability to model multiple sites within one river stretch. The three most important predictive variables in the optimized models for the bacterial indicators were NH4-N, turbidity and global solar irradiance, whereas chlorophyll a content, discharge and NH4-N were reliable model variables for somatic coliphages. Depending on indicator type, the extended mode models also included the additional variables rainfall, O2 content, pH and chlorophyll a. The extended mode models could explain 69% (EC), 74% (IE) and 72% (SC) of the observed variance in fecal indicator concentrations. The optimized models explained the observed variance in fecal indicator concentrations to 65% (EC), 70% (IE) and 68% (SC). Site-specific efficiencies ranged up to 82% (EC) and 81% (IE, SC). Our results suggest that MLR models are a promising tool for a timely water quality assessment in the Lahn area.

Bacteriophages as indicators of human and animal faecal contamination in raw and treated wastewaters from Tunisia.

AIMS: We aimed at quantifying bacteriophages in raw and treated wastewaters of human and animal origin in Tunisia to assess their usefulness for tracking the origin of faecal pollution and in the follow-up of effectiveness of water treatments process. METHODS AND RESULTS: The concentrations of bacteriophages in wastewater samples were determined by double layer agar technique. Somatic coliphages and F-specific RNA bacteriophages were present in all types of samples in high concentrations. The values of Escherichia coli were variable depending on geographical location. On the other hand, bacteriophages infecting strain GA17 were detected preferably when human faecal contamination was occurred. CONCLUSIONS: Bacteriophages appear as a feasible and widely applicable manner to detect faecal contamination in Tunisia. On the other hand, phages infecting GA17 could be good markers for tracking the origin of faecal pollution in the area studied. SIGNIFICANCE AND IMPACT OF THE STUDY: The reuse of treated wastewaters can be a solution to meet the needs of water in the geographical area of study. Bacteriophages seem to predict differently the presence of faecal contamination in water than bacterial indicators. Consequently, they can be a valuable additional tool to improve water resources management for minimizing health risks.

Bacteriophages infecting Bacteroides as a marker for microbial source tracking.

Bacteriophages infecting certain strains of Bacteroides are amid the numerous procedures proposed for tracking the source of faecal pollution. These bacteriophages fulfil reasonably well most of the requirements identified as appropriate for a suitable marker of faecal sources. Thus, different host strains are available that detect bacteriophages preferably in water contaminated with faecal wastes corresponding to different animal species. For phages found preferably in human faecal wastes, which are the ones that have been more extensively studied, the amounts of phages found in waters contaminated with human fecal samples is reasonably high; these amounts are invariable through the time; their resistance to natural and anthropogenic stressors is comparable to that of other relatively resistant indicator of faecal pollution such us coliphages; the abundance ratios of somatic coliphages and bacteriophages infecting Bacteroides thetaiotaomicron GA17 are unvarying in recent and aged contamination; and standardised detection methods exist. These methods are easy, cost effective and provide data susceptible of numerical analysis. In contrast, there are some uncertainties regarding their geographical stability, and consequently suitable hosts need to be isolated for different geographical areas. However, a feasible method has been described to isolate suitable hosts in a given geographical area. In summary, phages infecting Bacteroides are a marker of faecal sources that in our opinion merits being included in the "toolbox" for microbial source tracking. However, further research is still needed in order to make clear some uncertainties regarding some of their characteristics and behaviour, to compare their suitability to the one of emerging methods such us targeting Bacteroidetes by qPCR assays; or settling molecular methods for their determination.

A comparison of two extraction methods for the detection of Enteroviruses in raw sludge.

The aim of this study was to compare two viral extraction methods for the detection of naturally occurring Enteroviruses in raw sludge. The first method (M1) is based on an ultracentrifugation step. In the second one (M2), viral RNA was extracted directly after viral elution from suspended solids. Genomes of enteroviruses were quantified by a quantitative real time PCR (qRT-PCR) in sludge samples. Somatic coliphages and F-specific RNA phages, considered as viral indicators of enteric viruses in sludge, were enumerated by the double layer agar technique. Results showed that direct assay of RNA extraction yielded higher genomic copies of enteric viruses (with an average of 5.07Log10 genomic copies/100 mL). After the ultracentrifugation assay in the second method, genomic copies number decreases (with an average of 4.39Log10 genomic copies/100 mL). This can be explained by an eventual concentration of inhibitors existing in sludge samples. Phages enumeration results showed their presence in all sludge samples with an average of (5.69Log10 PFU/100 mL) for somatic coliphages and (4Log10 PFU/100 mL) for F-specific RNA phages. This emphasizes the use of somatic coliphages as viral indicators for enteroviruses in environmental samples and especially in raw sludge samples in wastewater treatment plants prior to agricultural use.

Implementación de dos métodos de recuento en placa para la detección de colifagos somáticos, aportes a las metodologías estándar

Los métodos de recuento en placa capa doble y capa simple de agar, para la cuantificación de colifagos somáticos en aguas, fueron implementados utilizando como base metodologías estándar. Diferentes variables fueron ensayadas, lo cual permitió la precisión en algunos pasos no incluidos en metodologías estándares. De los hallazgos de mayor importancia, se exponen las consecuencias de utilizar un cultivo de Escherichia coli excesivamente concentrado y se describe la obtención de un cultivo en fase logarítmica en solo 4 horas de incubación, ajustando la concentración a una densidad óptica de 0,3 a 600nm (3,1 x 10(8)UFC/ mL), o a un McFarland 1 (3,0 x10(8)UFC/ mL). Se determinó que los controles de colifagos deben ser almacenados a -70 °C para reducir su degradación y que se deben evitar cantidades superiores a 20 mL de mezcla de reacción por plato de Petri, para reducir las burbujas que pueden interferir con la lectura de unidades formadoras de placas (UFP). Se demostró que los colifagos de las muestras de agua pueden almacenarse 48 horas a 4 °C sin que sufran degradación y que en las muestras con altas concentraciones de colifagos no se observa UFP porque se da una lisis confluente de la capa bacteriana. No se encontraron diferencias significativas en la recuperación de colifagos al utilizar un método u otro, pero dichos métodos deben ser evaluados por medio de controles, antes de aplicarlos directamente en el análisis de muestras de agua.

Two plate count methods, double layer and single layer of agar for quantification of somatic coliphages in water, were implemented using standard methodologies. Several variables were tested and provided valuable information that was not included in standard methodologies. The most important findings are described, such as the effect of using an excessively concentrated culture of E. coli and production of a log phase culture in only 4 hours of incubation, adjusting the concentration to an optical density of 0.3 at 600 nm (3.1 x 108 CFU / mL), or to McFarland 1 (3.0 x 108 CFU / mL). It was determined that coliphages controls must be stored at -70 °C to reduce its degradation. Quantities of reaction mixture exceeding 20 mL per Petri dish must be avoided to prevent interfere with bubbles during the counting of plate forming units (PFU). It was demonstrated that coliphages isolated from water samples can be stored for 48 hours at 4 °C without any degradation, and PFU are not observed in samples with high concentrations of coliphages, because a confluent lysis of the bacterial layer. There was no significant difference in the recovery of coliphages using doble layer or single layer methods, but such methods should be evaluated by means of controls, before applying them directly in the analysis of water samples.

Detection of somatic coliphages as indicators of faecal contamination in estuarine waters / Detección de colifagos somáticos como indicadores de contaminación fecal en aguas estuarinas

The appearance of enteric disease outbreaks associated with the use of waters considered bacteriologically suitable, calls for the search of new and more precise indicators. Samples of estuarine water were collected in order to quantify E. coli and E. coli ATCC 13706 somatic coliphages and to compare the usefulness of the latter to detect faecal contamination when the concentration of traditional indicators is not quantifiable. Statistical analyses suggested the division of sampling sites into two groups: group I and group II, according to the minor or major level of faecal pollution respectively registered. In group II a high correlation between the coliphages and E. coli (r: 0.73 p<0.01) was detected. E. coli always exceeded coliphage abundance. In group I, this relationship was statistically significant (r: 0.55 p< 0.05), coliphage counts were higher than those of E. coli and were detected in the absence of the latter. In summary, the use of E. coli ATCC 13706 somatic coliphages is proposed as a complementary tool for the diagnosis of the level of faecal contamination of estuarine waters, especially in areas of low pollution.

La aparición de brotes de enfermedades víricas entéricas asociadas al uso de aguas bacteriológicamente aptas impone la búsqueda de nuevos y más precisos indicadores de contaminación. Se recolectaron muestras de agua estuarina, donde se cuantificaron simultáneamente la bacteria E. coli y los colifagos somáticos de E. coli ATCC 13706, a fin de evaluar la utilidad de estos últimos para detectar contaminación fecal cuando la concentración de los indicadores tradicionales no es cuantificable. Los resultados estadísticos sugirieron la división de las estaciones de muestreo en dos grupos, I y II, de acuerdo con el menor o mayor nivel de contaminación fecal registrado, respectivamente. En el grupo II se detectó una alta correlación entre los recuentos de colifagos y de E. coli (r: 0,73 p<0,01). Asimismo, en este grupo la abundancia de E. coli siempre superó a la de colifagos. En el grupo I la correlación fue estadísticamente significativa (r: 0,55 p < 0,05), pero de mediana magnitud, los recuentos de colifagos superaron a los de E. coli, y éstos fueron detectados aun en ausencia de la bacteria. En conclusión, los colifagos somáticos de E. coli ATCC 13706 serían una herramienta accesoria en el diagnóstico del nivel de contaminación fecal de aguas estuarinas, sobre todo en áreas donde ésta es baja.