SciELO - Scientific Electronic Library Online

 
 issue103Analysis of beam-column elements on non-homogeneous soil using the differential transformation methodOn the issue of automatic form accuracy during processing on CNC machines author indexsubject indexarticles search
Home Pagealphabetic serial listing  

Services on Demand

Journal

Article

Indicators

Related links

  • On index processCited by Google
  • Have no similar articlesSimilars in SciELO
  • On index processSimilars in Google

Share


Revista Facultad de Ingeniería Universidad de Antioquia

Print version ISSN 0120-6230On-line version ISSN 2422-2844

Rev.fac.ing.univ. Antioquia  no.103 Medellín Apr./June 2022  Epub Feb 21, 2022

https://doi.org/10.17533/udea.redin.20210217 

Artículo original

Water quality in the municipalities of Sincerín and Gambote, Bolívar, Colombia (2017-2018)

Calidad del agua de los corregimientos de Sincerín y Gambote, Bolívar, Colombia (2017-2018)

Laura Duarte-Jaramillo1  2 

María Angélica Mendoza-Atencio1  2 

Beatriz Eugenia Jaramillo-Colorado1  * 

Álvaro González-Álvarez3 

1Grupo de Investigaciones Agroquímicas, Programa de Química, Facultad de Ciencias Exactas y Naturales, Universidad de Cartagena. Carrera 50 #24-120. C. P. 1382. Cartagena, Colombia.

2Programa de Ingeniería Ambiental, Universidad Tecnológica de Bolívar. Parque Industrial y Tecnológico Carlos Vélez Pombo Km 1 Vía Turbaco. Bolívar, Colombia.

3Water and Wastewater Department Project Engineer, Boswell Engineering, 330 Phillips Ave. P. C. 07606. South Hackensack, United States.


ABSTRACT

This study evaluates the water quality for human consumption in the municipalities of Sincerín and Gambote. It was measured through physico-chemical (color, turbidity, conductivity, pH, dissolved oxygen, hardness, and heavy metals) and microbiological (total coliforms, Escherichia coli) parameters before and after a partial form of water treatment was used (alum and chlorine addition in Gambote and Sincerín municipalities, respectively). This investigation was done in accordance with the maximum permissible values established by the Resolution 2115 of 2007 of the Ministry of Environment, Housing, and Territorial Development of Colombia (MAVD in Spanish). Additionally, the IRCA (Water Quality Risk Index) was calculated to determine the degree of risk of disease occurrence. The results indicated concentrations higher than the recommended values for: (a) hardness (in Sincerín); (b) iron (Fe), turbidity (only before being treated), E. coli (in Gambote); and (c) mercury (Hg), and total coliforms. The water supplies of the municipalities presented unsafe IRCA. Therefore, it is expected that the results of this study could be used for proposing strategies for improving these conditions by means of the design and implementation of an adequate treatment system.

Keywords: Water analysis; water treatment; drinking water; surface water; groundwater

RESUMEN

Este estudio evaluó la calidad del agua para consumo humano en los corregimientos de Sincerín y Gambote. Algunos parámetros fisicoquímicos (color, turbidez, conductividad, pH, oxígeno disuelto, dureza y metales pesados) y microbiológicos (coliformes totales, Escherichia coli) fueron medidos durante las etapas de pre y post tratamiento parcial usado (alumbre y tabletas de cloro en Gambote y Sincerín, respectivamente). Esta investigación fue hecha de acuerdo con los valores máximos permisibles establecidos por la Resolución 2115 de 2007 del Ministerio de Ambiente, Vivienda y Desarrollo Territorial de Colombia. Adicionalmente, se calculó el IRCA (Índice de Riesgo de la Calidad del Agua) con el fin de determinar el grado de riesgo a la ocurrencia de enfermedades. Los resultados indicaron concentraciones por encima de las recomendables para: (a) la dureza (en Sincerín), (b) hierro (Fe), turbiedad (únicamente antes de ser tratada) y E. coli (en Gambote) y (c) mercurio (Hg) y los coliformes totales (en Sincerín y Gambote). Los suministros de agua de los corregimientos presentaron un IRCA inseguro. Por tanto, se espera que los resultados de este estudio puedan contribuir al mejoramiento de estas condiciones a través del diseño e implementación de un sistema de tratamiento.

Palabras claves: Análisis del agua; tratamiento del agua; agua potable; agua superficial; agua subterránea

1. Introduction

Water is the essence of life; international legislation includes specific obligations to States regarding safe water supply for personal and domestic use. Nevertheless, 884 million people lack adequate sources, and 2.5 billion do not have improved sanitation services[1]. Only until the end of the 18th century did basic processes for water treatment begin to be developed[2].

Water for human consumption refers to that used for direct drinking, food manufacturing or preparation, personal hygiene, and cleaning of utensils[3]. Water used for this purpose can be either from surface or underground sources. When it is contaminated with pathogenic microorganisms, it can cause various pathologies such as hepatitis A, cholera, Typhoid, and paratyphoid fever, and, in a large percentage of cases, acute diarrheal diseases[4]. The pollution of the anthropic and natural origin of water sources limits their use mainly for human consumption; quick diagnostic tools and representative as water quality indices (ICA, for its acronym in Spanish) guarantee a comprehensive evaluation of the resource, essential in taking actions to manage and control the sanitary risk through the different purification processes[5, 6].

Water pollution can be found in the form of dissolved or dispersed compounds that come from different activities, such as domestic, agricultural, industrial, and soil erosion wastes. These compounds can be either inorganic (chlorides, sulfates, nitrates, among others) or organic (human, animal, slaughterhouse waste, food, and product processing natural chemicals, etc.) that consume dissolved oxygen and affect aquatic life[2]. The World Health Organization (WHO) developed a water safety plan (WSP); this relates the risk assessment and management to provide water quality from basin to consumer. It has five stages: assembling a WSP team, describing the existing DWSS, identifying hazards and dangerous events, evaluating risks, and planning risk management[7]. Cities in developing countries often suffer from poor water quality. Therefore, it is necessary to have the capacity to make decisions about the current state of urban water quality, as well as the implementation of new infrastructure[8].

In Colombia, the risk associated with the water characteristics for human consumption is evaluated through the Risk Index for Water Quality for Human Consumption (IRCA, for its acronym in Spanish), calculated as a weighted linear combination of various parameters, including total coliforms and E. coli[9]. This index is interpreted as the evaluation of the chemical, physical and biological nature of the water in relation to the natural quality, human effects, and possible uses. The IRCA assigns a score to the variables that do not comply with the acceptable values determined by resolution 2115 of 2007 (Colombian standard for the quality of water for human consumption)[10], which establishes the acceptable values for the quality of the water for human consumption that do not represent known health risks. This resolution also presents the characteristics, basic instruments, and frequencies of the system control and surveillance. The IRCA is one of these instruments designed to evaluate the degree of risk of the occurrence of diseases related to non-compliance with the physical, chemical, and microbiological characteristics of water for human consumption as follows: 80.1-100 % (sanitary infeasible), 35.1-80 % (high), 14.1-35 % (medium), 5.1-14 (low), and 0-5 (no risk)[7, 10-12]. Concerning the IRCA, the calculation, and reporting mechanism are constantly flawed due to the lack of stricter regulation on updating information, notifications, and improvement actions. Also influencing the non-existence of the aqueduct service in municipalities with low economic level, failure in the regular municipal conduits, and the lack of trained personnel to take samples[13]. According to the Comptroller General of the Nation’s reports, the majority of Colombian municipalities do not comply with the established water quality parameters[12]. The spoilage of the water resources in Colombia is mostly attributed to industrial, domestic, and agricultural wastewater discharges and activities such as fluvial, terrestrial, and maritime transport of hazardous substances, mining extraction, and solid residue disposed of in sanitary landfills[5].

On the other hand, the Colombian Ministry of Health and Social Protection has been carrying out for several periods the national report on the quality of water for human consumption (INCA, for its acronym in Spanish); the results indicate a medium risk level (country average) for the year 2016. It is also observed that this deterioration increases as the degree of rurality is greater, in such a way that the Water Quality Risk Index (IRCA) in these areas is predominantly high and, in some cases, sanitary unfeasible[11]. For the rural area of the Department of Bolívar (political and administrative unit of the study area), an average Water Quality Risk Index of 47.4 (high-risk level) has been reported[11].

The Municipalities of Sincerín and Gambote are part of the Town of Arjona (Department of Bolívar)[14-17]. The source of supply for the town of Gambote is surface water from the Canal del Dique; this is a human-made canal connected to the Magdalena River, the most important in Colombia (the largest). This river presents a growing deterioration in its basin due to the socio-economic activities developed along its route. It also has a significant environmental impact on the adjacent ecosystems[18]. In the case of Sincerín town, the water source comes from a 50-m deep well. These two municipalities are mostly composed of low-income families with no access to drinking water and basic sanitation services. In these communities, a partial treatment for the purification of water has been implemented, consisting of adding (a) sodium hypochlorite (groundwater source in Sincerín) and (b) alum (surface water source in Gambote).

This study aims to assess the water quality in these two municipalities by analyzing various physical-chemical (turbidity, apparent color, electrical conductivity pH, dissolved oxygen, and total hardness) and microbiological (total coliforms, Escherichia coli) parameters: Moreover, some heavy metals (Cr, Fe, Ni, Cu, Pb, Hg) and other inorganic ions (chlorides, fluorides, sulfates, nitrates, and bromides). Samples were collected before and after the current partial form of treatment implemented to evaluate its efficacy to improve the drinking water quality delivered to these communities. In addition, the values of the water quality parameters were: (a) compared with the maximum acceptable values established by Resolution 2115 of 2007 and (b) used to calculate the IRCA to determine the level of health risk.

2. Materials and methods

2.1 Study area

Gambote and Sincerín are located in the north of the Department of Bolívar, Colombia; they have a population of approximately 4030 (census of 2019) and 2100 (current population based on the average growth rate of the census carried out by DANE in 2005), respectively[15-17].

Figure 1 depicts the geographical location of Sincerín (geographic coordinates of 10° 8'38.89"N; 75°16'34.64"W) and Gambote (geographical coordinates 10° 9'47.63"N; 75°17'54.99"W).

Figure 1 Geographical location of Sincerín and Gambote (Source: adapted from Google Earth) 

Neither Sincerín nor Gambote has access to safe drinking water, despite the fact that Aguas de Cartagena (the company that provides drinking water to the City of Cartagena, located at nearly 36 km) has a water pumping station in Gambote. It is an important fluvial artery of the Magdalena River (that flows from south to north of Colombia), providing fresh water to Cartagena[18]. In Gambote, raw water from the Canal del Dique is pumped to a water storage tank and then distributed via gravity pipe without any treatment. Each family adds a random amount of alum to remove turbidity. As for Sincerín, raw groundwater is pumped to a 50-m3 water storage tank where sodium hypochlorite (NaClO) is added (1.5 kg of NaClO at 70% is diluted into 60 L of water), and then distributed via gravity pipe.

2.2 Sampling and sample preparation

Six samples were collected for each of the municipalities: three (3) before and three (3) after the partial treatment provided at each municipality. The samples were collected in plastic bottles, glass bottles, and Ziploc® bags for physical-chemical, heavy metals, and microbiological analysis, respectively. Table 1 summarizes the information on parameters measured, preservation, and analytical methods used in this study, and Table 2 describes the type of sample, frequency, date, type of sample, and time of taking.

Table 1 Parameters measured, methods used, and preservation of samples 

Table 2 Description of the samples taken in the study 

The raw water samples of Gambote (GAMB) were collected directly from the Canal del Dique [Figure 2a) before the residents added alum to it. The so-called treated water (after alum addition, GAMBT) samples were collected at a house near the Canal del Dique [Figure 2b). For Sincerín, the raw water samples (SINC) were collected directly from the underground water well [Figure 2c and Figure 2d) through a tube [Figure 2e). The treated water samples -after the addition of NaOCl- (SINCT) were collected from one of the taps at the aqueduct offices [Figure 2f).

Figure 2 Sampling locations (a) Gambote’s raw water sampling point (GAMB); (b) House near the Canal del Dique after alum addition (GAMBT); (c) Sincerín’s well location; (d) Closeup of Sincerín’s Well; (e) Pipeline connected to Sincerín’s well where raw groundwater samples were collected (SINC); (f) Aqueduct offices (SINCT). Own photo 

2.3 Determination of IRCA

The IRCA is a drinking water quality index that ranges from zero to 100 (0-100) [Table 3]. It reduces a total of 22 physical-chemical and microbiological parameters of water quality into a simple expression that can be easily interpreted and understood. Each parameter is allocated a risk score [Table 4] to those parameters that do not have the maximum permissible values established in Resolution 2115 of 2007. Suppose the chemical characteristics of the substances that have a recognized adverse effect on human health exceed the maximum acceptable (articles 5 to 8); in that case, the IRCA value will be assigned the score maximum of 100 points, regardless of the other results. Likewise, if Giardia and Cryptosporidium are present[10, 19], the IRCA is calculated by Equation (1).

Table 3 Classification of the level of health risk according to the IRCA per sample, and actions to be taken. Source: Resolution 2115 of 2007[10]. 

Table 4 IRCA’s risk scores. Source: Resolution 2115 of 2007(10)

*These parameters do not have a risk score assigned by Resolution 2115 of 2007; for this reason, they are not taken into account in the sum of the total assigned score. The resolution determines that physical, chemical, and biological characteristics with the maximum acceptable values, the IRCA value is zero (0), and when none of them is found, the value will be one hundred points (100)[7].

3. Results and Discussion

The values of the three samples of each parameter for both raw water and after the partial treatment (GAMBT and SINCT) were averaged and compared with the maximum acceptable values (MAV) established by the Resolution 2115 of 2007. This resolution does not provide specific risk level for some compounds, such as lead, chromium, mercury, and cadmium; if these exceed the MAV, the resolution establishes that they will be assigned the maximum score of 100 points, regardless of the results obtained[10]. Table 5 shows the water quality evaluation and calculation of the IRCA from Gambote and Sincerin, and Table 6 exhibits the compliance with Resolution 2115 of 2007; underlined cells in the tables indicate concentrations above the established MAV.

Table 5 Water quality evaluation and calculation of the IRCA 

T.Col.: Total Coliforms; ND: Not Detected; NM: Not Measured; N/A: Not applicable; S.I: Sanitary Infeasible. (*) In the legislation, there is no maximum allowable value for bromide. However, since it is a monoatomic ion and belongs to the halogens group, like fluoride, the value of 1 mg/L will be taken as a reference. Gray cells indicate values above those established by Res. 2115 of 2007.

Table 6 Compliance with Resolution 2115 of 2007. 

Elec. Cond.: electrical conductivity. Gray cells indicate non-compliance with Res. 2115 of 2007

The measured values of electrical conductivity and dissolved oxygen were not presented in Table 5 since they are not necessary to calculate the IRCA. The results obtained for the municipality of Gambote (GAMB and GAMBT) oscillated approximately between 180 and 230 µS/cm, which are below the limits established by the legislation (1000 µS/cm. As for Sincerín (SINC and SINCT), electrical conductivity values ranged between 450 and 1100 µS/cm. The value of 1100 µS/cm, which exceeded the MAV, was observed in one sample. The considerable difference in reported values of electrical conductivity from Gambote and Sincerín is attributed to the fact that groundwater typically has more dissolved ions than surface water, which can also be seen in the higher concentrations of hardness reported in groundwater (Sincerín) when compared to surface water in Gambote.

The range for hardness in Gambote and Sincerín were 99.5-120.1 and 220.2-360.3 mg/L respectively, [Table 5]. In fact, five of the six samples (the value of 298.2 was assumed to be 300 mg/L) collected in Sincerín reported values of hardness above MAV (300 mg/L), which indicates that softening must be part of any treatment system to be implemented in Sincerín. Regarding reported concentrations of dissolved oxygen, the water sources of both municipalities were within the range of 6.9 and 8.3 mg/L, which classifies both sources as acceptable (≥ 4 mg/L), according to MinVivienda[20, p.64).

The GAMB (raw water) reported turbidity values, color, iron, mercury, total coliforms, and E. coli did not comply with their corresponding MAV [Table 5]. The high values of turbidity and color are typical of surface water, such as the “Canal del Dique” since they are generally in contact with organic material (tannins from leaves, wood, roots, etc.), humic acids, and some industrial waste. Water quality studies carried out in some rivers in Colombia, such as Magdalena, Cauca, and Córdoba, where most of the turbidity values were above Colombian regulations, indicate that many rivers present suspended particles that reduce the transparency of the water, generated by dragging processes such as soil removal, and in other cases, by industrial and/or urban dumping[21-22]. In addition, a climatological influence could not be detected for the turbidity parameter; however, the highest value was obtained in sampling 2 (195 NTU), which was carried out in the dry season. For this reason, the precipitation records were reviewed of the IDEAM on the sampling days: August 18, 2017, February 14, 2018 and April 26, 2018, which were 0 mm, 0 mm and 4 mm respectively, which in hydrological terms is a negligible value. Therefore, it was determined that for the samples taken in this study, there was no incidence of the climatological seasons since no rains were recorded on the sampling days or previous days.

The values reported above the limit for total coliforms and, especially, E. coli indicate fecal contamination, which is a danger to the inhabitants’ health since they can generate diseases such as gastroenteritis, which is especially harmful to children under five years old[2, 23]. In this context, the risk is even higher given that the Canal del Dique is not only used as a source of drinking water and food (fishing, irrigation, and livestock watering), but also for recreational purposes (both primary and secondary contact) by some of the locals. Similarly, high concentrations of Fe and Hg were found, which are also harmful to human health. Although iron is one of the most abundant metals on earth and is found in freshwater in concentrations of 0.5 to 50 mg/L, the intake of large amounts of iron can cause poisoning, leading to vomit and liver failure, among others[24].

In the case of mercury, the ingestion of high concentrations leads to higher risks since it tends to bioaccumulate through the food chain and can cause mutations (teratogenicity)[25]. It has been reported that up to 90% of the bioaccumulated mercury is incorporated into the digestive system through food[26]. These results are in agreement with the ones reported in several studies performed in the Canal del Dique, Cartagena bay, and the Magdalena river basin, where high mercury concentrations have been found not only in the water but also in the river’s own fish species, such as bocachico, herring, and catfish. The origin of these metals goes from artisanal mining to tannery industries and industrial dumping[26-33]. As for the other heavy metals assessed, the values obtained did not exceed the MAV. In Table 5, it can be seen that there was no significant decrease in the concentration values, which is not surprising given that coagulation is not efficient at eliminating dissolved substances. Regarding hardness concentration, as previously discussed, reported values indicated that Gambote’s water is moderately hard (between 76-100 mg CaCO3/L); therefore, softening is not required[34].

In the case of GAMBT samples, as expected, the addition of a random concentration of alum decreased the measured values of turbidity and color[35]. The turbidity changed from a range of 48.9-95.0 NTU (before addition, GAMB) to 1.79-2.16 NTU and for color from 75-125 PCU to 10-15 PCU. Despite the improvement, it can be observed that a value of 2.16 NTU is not only above the established MAV of 2.0 NTU, but also higher than the typical turbidity values of 1.0 NTU (or less) reached at conventional water treatment plants[36]. Furthermore, an increase of sulfate concentrations was detected (from 4.15 mg/L to 22.52 mg/L), perhaps, due to the formation of calcium sulfate (CaSO4) from the reaction of alum with the natural alkalinity[37] of the water in the Canal del Dique, which, in turn, implies that the dose of alum is not optimal. It was also noticed that pH values did not decrease much even though coagulants tend to lower pH as they consume alkalinity. This indicates a high buffer capacity of this water. With respect to the microbiological parameters, total coliform and E. coli, levels higher than those allowed by the current regulations were found, except in SINCT samples for E. coli.

The assessment of Gambote’s water by means of the IRCA revealed that they are not suitable for human consumption, which is mainly due to the concentrations of mercury exceeding the MAV[7]. These results are in line with the IRCA value of a 100 obtained in the municipality of Mahates[38], which also uses the Canal del Dique as a source of drinking water. Mercury is accumulated through the Magdalena River basin upstream due to gold mining within the watershed[27, 39].

The water supplies of Sincerín, as expected, showed lower values of color and turbidity when compared to Gambote’s, with ranges of 10-100 PCU (SINC) and 5-10 PCU (SINCT) for color, and 0.08-7.14 NTU (SINC) and 0.35-3.92 NTU (SINCT) for turbidity. As to the concentration of hardness and previously discussed, five of the six samples analyzed reported values near or above 300 mg/L, which classifies Sincerín’s water as within the category of hard and very hard, implying the need for softening[34].

Regarding the microbiological parameters, the total coliforms reported values for both SINC (33-100 CFU/100 mL) and SINCT (3-100 CFU/100 mL) exceeded the MAV [Table 5]. The addition of sodium hypochlorite seemed to be not completely efficient in reducing total coliforms. This might be due to the presence of both substances/particles that caused color and turbidity and the high concentrations of hardness, which are known to reduce the biocidal effect of sodium hypochlorite[40]. The values of E. coli exceeded the MAV once (raw water first sample at a value of 100 CFU/100 mL). This result is indicative of (a) the aquifer susceptibility for fecal contamination, which is not surprising given that the basic sanitation services of the municipality are deficient, and (b) the chlorine dosage is not optimal as it is a random concentration, not the result of a dosage obtained, for instance, via chlorination breakpoint curve. In general, and according to the IRCA, Sincerín’s water is also classified as sanitary infeasible (a value of 100) chiefly due to the above-the-limit concentrations of mercury reported in the samples analyzed. This result is also in agreement with other groundwater sources used in various municipalities located within the Department of Bolívar, namely San Joaquín, Malagana, and San Basilio de Palenque[38].

The results obtained in this study showed that the water sources of both municipalities (Sincerín and Gambote) are sanitarily infeasible for human consumption, which poses a high risk to human health. These findings coincide with a study carried out in seven municipalities of the Caribbean region between 2005 and 2008, including some belonging to the department of Bolívar (study site) such as Puerto Badel, Bocachica, San Jacinto, among others; the samples indicated that the water for human consumption evaluated is not in ideal conditions for consumption. The risk factors associated with this contamination are associated with the lack of an aqueduct, limited availability of water, prolonged periods in the storage and conservation of water, and the lack of physical or chemical treatment for purification[41]. In general, it can be seen that for populations located in rural areas the level of risk of IRCA increases, which happens in many parts of the country where different geographical and weather conditions are present. This is the case of the Amazon and Orinoquia region, where many municipalities do not have an optimal drinking water supply system, as well as sanitary networks, causing the inhabitants to live in precarious conditions[42]. The implementation and intensification of surveillance actions in environmental health carried out by the competent authorities, such as sanitary inspection visits and acceptable hygienic practices, can reduce the risk level of the water quality risk index[43].

On the other hand, the values notified in the national report[11] for the town of Arjona were classified as drinking water with no risk. This information reveals that drinking water quality in rural areas is not accurately assessed, which confirms these communities’ vulnerability problems. In Colombia, the average urban IRCA nationwide in 2008 was 16.7%; in 2009, 13.8 %; in 2010, 11.9%; in 2011, 11.5%, and in 2012, of 13.2%, classifying the country, in these years, at medium and low risk[13]. In general, the IRCAs reported by some departments in the period 2007 to 2013 were, in Nariño, 39.20%; Huila, 33.07%; Casanare, 29.86%; Boyacá, 15.26%; Santander, 15.09%, and Cundinamarca, 7.16%[44].

Some studies have shown that in rural regions, access to improved water sources is predominantly scarce, so the inhabitants of these areas have developed their own collecting systems (self-sufficiency)[45], taking water from springs and streams, as is the case of Gambote where they collect the water directly from the Canal del Dique. The other main problem in our study sites is coliform contamination; to face this issue, it is necessary to implement alternatives for biological treatment that show the best economic, functional, and operational profitability. The most widely used in Colombian territory are usually stabilization lagoons, wetlands, and activated sludge, which when used together reflect optimal results greater than 90% in the treatment of domestic wastewater, in case of water shortage (a common situation in rural regions) an alternative water resource may be to reuse the latter[45-46]. Quality control through physicochemical and microbiological analyzes is essential; however, it is not enough to guarantee the final quality of drinking water; it is just as important to have comprehensive management in drinking water distribution systems (WDS)[47-48].

4. Conclusions

The Risk Index of Water Quality for Human Consumption (IRCA) calculated for the water supplies of Sincerin and Gambote classified the waters as unfit for human consumption; most of the parameters measured in raw water exceeded the maximum acceptable values established by the corresponding Colombian legislation. Furthermore, the partial treatment used in both municipalities did not improve the water quality.

The high incidence of pathogenic microorganisms on the final value of IRCAs highlights the need to apply efficient strategies for the management of discharges of domestic and livestock origin in order to improve the water quality from Sincerin and Gambote.

6. Acknowledgements

We want to thank to the University of Cartagena who financed this research, the Agrochemical Research Group. To the Environmental Engineer Program of the Technological University of Bolivar. Specially, thanks to the residents in charge of supplying and distributing water in the townships of Sincerín and Gambote.

References

[1] El derecho al agua, Oficina del Alto Comisionado de las Naciones Unidas para los Derechos Humanos, Naciones Unidas Derechos Humanos, Organización de las Naciones Unidas, Organización Mundial de la Salud, Ginebra, CH, 2010. [ Links ]

[2] S. Cairncross and et al, “Water, sanitation and hygiene for the prevention of diarrhea,” Int. J. Epidemiol, vol. 39, Suppl 1, March 23 2010. [Online]. Available: http://dx.doi.org/10.1093/ije/dyq035Links ]

[3] Alcaldía Mayor de Bogotá D.C. (1984, Jul. 26) Decreto 1594 de 1984. [Online]. Available: https://bit.ly/3lnn4a9Links ]

[4] Ministerio de Salud y Protección Social. Subdirección de Salud Ambiental, “Informe nacional de calidad del agua para consumo humano (INCA) 2015,” Ministerio de Salud y Protección Social. Subdirección de Salud Ambiental, Bogotá, D. C. Col., Tech. Rep., Dec. 2016. [ Links ]

[5] P. Torres, C. H. Cruz, P. Patiño, J. C. Escobar, and A. Pérez, “Aplicación de índices de calidad de agua - ICA orientados al uso de la fuente para consumo humano,” Ing. Inv., vol. 30, no. 10, pp. 86-95, Dec. 2010. [ Links ]

[6] M. Castro, J. Almaida, J. Ferrer, and D. Díaz, “Indicadores de la calidad del agua: Evolución y tendencias a nivel global,” Ingeniería Solidaria, vol. 10, no. 17, December 2014. [Online]. Available: http://dx.doi.org/10.16925/in.v9i17.811Links ]

[7] A. Pérez , J. C. Escobar , andP. Torres , “Development and implementation of a water-safety plan for drinking-water supply system of Cali, Colombia,” Int. J. Hyg. Environ. Health, vol. 224, March 2020. [Online]. Available: https://doi.org/10.1016/j.ijheh.2019.113422Links ]

[8] N. Rodríguez, L. A. Camacho, J. P. Rodríguez, and J. E. McCray, “Integrated urban water resources model to improve water quality management in data-limited cities with application to Bogotá, Colombia,” J. Sustain Water Built Environ., vol. 4, no. 2, May 2018. [Online]. Available: http://dx.doi.org/10.1061/JSWBAY.0000846Links ]

[9] J. Wright and et al, “Water quality laboratories in Colombia: A GIS-based study of urban and rural accessibility,” Sci Total Environ, vol. 485, July 1 2014. [Online]. Available: https://doi.org/10.1016/j.scitotenv.2014.03.127Links ]

[10] Ministerio de la Protección Social, Ministerio de Ambiente, Vivienda y Desarrollo Territorial. (2007, Jun. 22) Resolución número 2115. [Online]. Available: https://bit.ly/2GwFBC2Links ]

[11] Ministerio de Salud y Protección Social. Subdirección de Salud Ambiental, “Informe nacional de calidad del agua para consumo humano (INCA) 2016,” Ministerio de Salud y Protección Social. Subdirección de Salud Ambiental, Bogotá, D. C. Col., Tech. Rep., May 2018. [ Links ]

[12] Contraloría General de la República, “Informe sobre el estado de los Recursos Naturales y del Ambiente 2015-2016,” Contraloría General de la República, Tech. Rep., 2016. [ Links ]

[13] E. T. Diaz, L. I. Loaiza, and J. A. Torres, “Evaluación del proceso del reporte del IRCA a las plataformas SUI y SIVICAP WEB desde el marco del INCA en los años 2016-2019, caso de estudio-Magdalena, zona bananera, 2019,” in 2019: Encuentro Internacional de Educación en Ingeniería ACOFI 2019. [ Links ]

[14] W. Barragán. (2008) Arjona Bolívar, Municipio de Arjona división político-administrativa. [blogspot.com]. Accessed May. 04, 2020. [Online]. Available: Available: https://bit.ly/33EgJRHLinks ]

[15] FEM Fundación por la Educación Multidimensional. (2019) Diagnóstico situacional de sincerín, corregimiento de arjona, bolívar, colombia. FEM Fundación por la Educación Multidimensional. Bolívar, Col. [Online]. Available: https://bit.ly/3d4dYw0Links ]

[16] J. Romero, “Educación ambiental y desarrollo humano en el corregimiento de Gambote,” M.S. thesis, Facultad de Economía y Negocios, Universidad Tecnológica de Bolívar, Cartagena de Indias, Colombia, 2017. [ Links ]

[17] Departamento Administrativo Nacional de Estadística (DANE), “Análisis de contexto de los cambios demográficos, 2007,” Departamento Administrativo Nacional de Estadística (DANE), Tech. Rep. DT-CGRAL-REG-8, Sep. 2007. [ Links ]

[18] M. M. Aguilera, Ed., El canal del dique y su subregión: Una economía basada en la riqueza hídrica, ser. Documentos de Trabajo sobre Economía Regional. Cartagena de Indias, Col: Banco de la República - Sucursal Cartagena, 2006, p. 87. [ Links ]

[19] C. A. García and J. C. García and J. P. Rodríguez and R. Pacheco and M. C. García, “Limitaciones del IRCA como estimador de calidad del agua para consumo humano,” Rev. Salud Pública, vol. 20, no. 2, 2018. [Online]. Available: http://dx.doi.org/10.15446/rsap.v20n2.65952Links ]

[20] Ministerio de Vivienda, Ciudad y Territorio, “Reglamento técnico del sector de agua potable y saneamiento básico: TÍTULO C. Sistemas de potabilización,” Ministerio de Ambiente, Vivienda y Desarrollo Territorial, Bogotá, D.C., Col, Tech. Rep., Dec. 2013. [ Links ]

[21] L. E. Gualdrón, “Evaluación de la calidad de agua de ríos de Colombia usando parámetros fisicoquímicos y biológicos,” Dinámica ambiental, no. 1, December 2016. [Online]. Available: https://doi.org/10.18041/2590-6704/ambiental.1.2016.4593Links ]

[22] F. A. Fontalvo and C. E. Tamaris, “Calidad del agua de la parte baja del río Córdoba (Magdalena, Colombia), usando el ICA-NSF,” Intropica, vol. 13, no. 2, July 2018. [Online]. Available: https://doi.org/10.21676/23897864.2510Links ]

[23] P. Ramya, S. Roy, R. Thamizhmani, and A. Purushothaman, “Diarrheagenic Escherichia coli infections among the children of Andaman Islands with special reference to pathotype distribution and clinical profile,” J. Epidemiol. Glob. Health, vol. 7, no. 4, December 2017. [Online]. Available: https://doi.org/10.1016/j.jegh.2017.07.003Links ]

[24] V. Kumar, P. Bharti, M. Talwar, A. Tyagi, and P. Kumar, “Studies on high iron content in water resources of Moradabad district (UP),” Water Sci., vol. 31, no. 1, 2017. [Online]. Available: https://doi.org/10.1016/j.wsj.2017.02.003Links ]

[25] J. L. Marrugo, J. A. Ruiz, and A. C. Ruiz, “Biomagnification of mercury in fish from two gold mining-impacted tropical marshes in northern Colombia,” Arch. Environ. Contam. Toxicol., vol. 74, no. 1, January 2018. [Online]. Available: https://doi.org/10.1007/s00244-017-0459-9Links ]

[26] C. Salazar, M. Salas, J. Marrugo, S. Marrugo, and S. Diez, “Dietary human exposure to mercury in two artisanal small-scale gold mining communities of northwestern Colombia,” Arch. Environ. Contam. Toxicol. , vol. 107, October 2017. [Online]. Available: https://doi.org/10.1016/j.envint.2017.06.011Links ]

[27] S. Alvarez, A. S. Kolok, L. F. Jimenez, C. Granados, and J. A. Palacio, “Mercury concentrations in muscle and liver tissue of fish from marshes along the Magdalena River, Colombia,” Bull. Environ. Contam. Toxicol., vol. 89, no. 4, October 2012. [Online]. Available: https://doi.org/10.1007/s00128-012-0782-9Links ]

[28] S. Español, “Contaminación con mercurio por la actividad minera,” Biomédica, vol. 32, no. 3, 2012. [Online]. Available: https://doi.org/10.7705/biomedica.v32i3.1437Links ]

[29] P. Cogua, N. H. Campos, and G. Duque, “Concentración de mercurio total y metilmercurio en sedimento y seston de la bahía de Cartagena, Caribe Colombiano,” Bol. Invest. Mar. Cost., vol. 41, no. 2, pp. 267-285, Mar. 2012. [ Links ]

[30] A. Persaud and K. Telmer, “Mercury watch portal: Charting the improvement of artisanal and small-scale gold mining,” Artisanal Gold Council, Victoria, CA, Tech. Rep. 106616-139, Feb. 2014. [ Links ]

[31] L. Tejeda, R. Flegal, K. Odigie, and J. Olivero, “Pollution by metals and toxicity assessment using Caenorhabditis elegans in sediments from the Magdalena River, Colombia,” Environ. Pollut., vol. 212, May 2016. [Online]. Available: https://doi.org/10.1016/j.envpol.2016.01.057Links ]

[32] J. D. Restrepo, Los sedimentos del rio Magdalena: Reflejo de la crisis ambiental, 1st ed. Fondo Editorial Universidad EAFIT, 2005. [ Links ]

[33] J. D. Restrepo, R. Escobar, and M. Tosic, “Fluvial fluxes from the Magdalena River into Cartagena Bay, Caribbean Colombia: Trends, future scenarios, and connections with upstream human impacts,” Geomorphology, vol. 302, February 1 2018. [Online]. Available: https://doi.org/10.1016/j.geomorph.2016.11.007Links ]

[34] J. Rodríguez, “Parámetros fisicoquímicos de dureza total en calcio y magnesio, pH, conductividad y temperatura del agua potable analizados en conjunto con las Asociaciones Administradoras del Acueducto, (ASADAS), de cada distrito de Grecia, cantón de Alajuela, noviembre del 2008,” Revista Pensamiento Actual, vol. 9, no. 12-13, pp. 125-134, 2009. [ Links ]

[35] J. M. Cogollo, “Clarificación de aguas usando coagulantes polimerizados: Caso del Hidroxicloruro de aluminio,” Dyna, vol. 78, no. 165, pp. 18-27, Feb. 2011. [ Links ]

[36] J. P. Rodino, J. J. Feria, R. J. Paternina, andJ. L. Marrugo , “Sinú River raw water treatment by natural coagulants,” Revista Facultad de Ingeniería Universidad de Antioquia, no. 72, July 2015. [Online]. Available: http://dx.doi.org/10.17533/udea.redin.n76a11Links ]

[37] L. Drbal, K. Westra, and P. Boston, Power Plant Engineering, 1st ed. Springer, US, 1996. [ Links ]

[38] J. Martínez, B. E. Jaramillo, and R. Fernández, “Water quality of five rural Caribbean towns in Colombia,” Environ. Earth Sci., vol. 78, no. 575, July 15 2019. [Online]. Available: https://doi.org/10.1007/s12665-019-8580-xLinks ]

[39] J. Marrugo , J. Pinedo, R. Paternina, L. Quiroz, and S. Pacheco, “Spatial distribution and evaluation of environmental pollution by mercury in the Mojana region, Colombia,” Rev. MVZ Córdoba, vol. 23(Supl), 2018. [Online]. Available: https://doi.org/10.21897/rmvz.1481Links ]

[40] M. C. Collivignarelli, A. Abbà, I. Benigna, S. Sorlini, and V. Torretta, “Overview of the main disinfection processes for wastewater and drinking water treatment plants,” Sustainability, vol. 10, no. 1, 2018. [Online]. Available: https://doi.org/10.3390/su10010086Links ]

[41] P. A. Franco, L. A. López, and M. E. Orozco, “Calidad microbiológica del agua destinada para consumo humano en siete municipios de la región Caribe Colombiana,” Ciencia Actual, vol. 3, August 8 2014. [Online]. Available: https://doi.org/10.21500/2248468X.1593Links ]

[42] D. Sabogal, J. F. Montilla, and V. Ibarra, “El IRCA y las inversiones en saneamiento básico en la región de la Amazonia y Orinoquía,” in Encuentro Internacional de Educación en Ingeniería ACOFI 2019, Cartagena de Indias, Colombia, 2019. [ Links ]

[43] M. Y. Dueñas, L. M. Dorado, P. Macanal, and S. H. Carrero, “Índice de riesgo de la calidad del agua para consumo humano en zonas urbanas del departamento de Boyacá, Colombia 2004-2013,” Revista Facultad Nacional de Salud Pública, vol. 36, no. 3, September 2018. [Online]. Available: https://doi.org/10.17533/udea.rfnsp.v36n3a10Links ]

[44] I. Domínguez, W. Torres, I. Restrepo, C. Patterson, and J. Gowing, “Autoabastecimiento como un enfoque alternativo para el acceso al agua en regiones rurales dispersas: Evidencia de una microcuenca rural en Colombia,” Revista Ingenieria y Universidad, vol. 20, no. 1, pp. 175-198, Jan. 2016. [ Links ]

[45] A. K. Vargas, J. Calderón, D. Velásquez, M. Castro , and D. A. Núñez, “Análisis de los principales sistemas biológicos de tratamiento de aguas residuales domésticas en Colombia,” Ingeniare. Revista Chilena de Ingeniería, vol. 28, no. 2, June 2020. [Online]. Available: http://dx.doi.org/10.4067/S0718-33052020000200315Links ]

[46] J. Manga, N. Logreira, and J. Serralt, “Reúso de aguas residuales: Un recurso hídrico disponible,” Ingeniería y Desarrollo, no. 9, pp. 12-21, Jul. 2001. [ Links ]

[47] A. Pérez , C. P. Amézquita, andP. Torres , “Identificación y priorización de peligros como herramientas de gestión de riesgos en los sistemas de distribución de agua potable,” Revista Ingenieria y Universidad , vol. 16, no. 2, pp. 449-469, 2012. [ Links ]

[48] The Human Right to Water and Sanitation, 2010 United Nations, UN-Water Decade Programme on Advocacy and Communication and Water Supply and Sanitation Collaborative Council. [ Links ]

Received: June 12, 2020; Accepted: February 06, 2021

* Corresponding author: Beatriz Eugenia Jaramillo Colorado, e-mail: bjaramilloc@unicartagena.edu.co

5. Declaration of competing interest

We declare that we have no significant competing interests including financial or non-financial, professional, or personal interests interfering with the full and objective presentation of the work described in this manuscript.

Creative Commons License This is an open-access article distributed under the terms of the Creative Commons Attribution License