Contenido de metales y elementos traza en aguas subterráneas de abastecimiento de la isla de El Hierro (Islas Canarias, España): e202010119

Laura Padrón Armas; Soraya Paz Montelongo; Ángel J. Gutiérrez Fernández; Carmen Rubio Armendáriz; Dailos González Weller; Arturo Hardisson de la Torre

Authors

Laura Padrón Armas Área de Toxicología. Facultad de Ciencias de la Salud. Universidad de La Laguna. Santa Cruz de Tenerife. España.
Soraya Paz Montelongo Área de Toxicología. Facultad de Ciencias de la Salud. Universidad de La Laguna. Santa Cruz de Tenerife. España.
Ángel J. Gutiérrez Fernández Área de Toxicología. Facultad de Ciencias de la Salud. Universidad de La Laguna. Santa Cruz de Tenerife. España.
Carmen Rubio Armendáriz Área de Toxicología. Facultad de Ciencias de la Salud. Universidad de La Laguna. Santa Cruz de Tenerife. España.
Dailos González Weller Servicio de Inspección y Laboratorio de Santa Cruz de Tenerife. Servicio Canario de Salud. Santa Cruz de Tenerife. España.
Arturo Hardisson de la Torre Área de Toxicología. Facultad de Ciencias de la Salud. Universidad de La Laguna. Santa Cruz de Tenerife. España.

Keywords:

Groundwater, Volcanic eruption, Metals, Fluoride

Abstract

Background: Volcanic eruptions are a natural source of substances potentially dangerous to human health. The island of El Hierro (Canary Islands, Spain) suffered a marine volcanic eruption in 2012, making it necessary to monitor the levels of certain elements that can alter the quality of groundwater supply. The objective of this work was to determine the content of metals and trace elements in the groundwater supply of the Isla del Hierro and to check if they met the quality parameters established in Spanish legislation.
Methods: The content of metals and trace elements (aluminum, lead, cadmium, calcium, potassium, sodium, magnesium, boron, barium, cobalt, chromium, copper, iron, lithium, manganese, molybdenum, nickel, strontium, vanadium, zinc, fluorine) in a total of 60 samples of groundwater supply and agriculture from six different sampling points on the island. The determination was carried out by inductively coupled plasma optical emission spectrophotometry (ICP-OES) and by fluoride ion selective potentiometry. The data were statistically analyzed applying the Kolmogorov-Smirnov test, Levene’s statistic, Kruskal-Wallis, Mann-Whitney U, ANOVA and Tukey’s test. Significant differences were those that
met p<0.05.
Results: The highest mean concentration of lead was recorded in the Tigaday samples (0.003±0.0005 mg/L), finding statistically significant differences (p<0.05) in the lead levels between the sampling points. The elements analyzed were below the parametric values set in Royal Decree 140/2003.
Conclusions: The results obtained reflect that, in all the samples analyzed, the quality parameters established in the Spanish legislation (RD 140/2003) are met, being, therefore, waters suitable for human consumption.

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References

BOC (Boletín Oficial de Canarias). DECRETO 52/2015, de 16 de abril, por el que se dispone la suspensión de la vigencia del Plan Hidrológico Insular de El Hierro, aprobado por el Decreto 102/2002, de 26 de julio, y se aprueban las Normas Sustantivas Transitorias de Planificación Hidrológica de la Demarcación Hidrográfica de El Hierro, con la finalidad de cumplir la Directiva 2000/60/CE, del Parlamento Europeo y del Consejo, de 23 de octubre de 2000, por la que se establece un marco comunitario de actuación en el ámbito de la política de aguas. Bol Of Can. 2015; 86.

Fraile-Nuez E, González-Dávila M, Santana-Casiano JM, Arístegui J, Alonso-González IJ, Hernández León S, Eugenio F. The submarine volcano eruption at the island of El Hierro: physico-chemical perturbation and biological response. Sci Rep. 2012; 2: 486.

Robock P. Introduction: Mount Pinatubo as a test of climate feedback mechanism. In: Robock, A., Oppenheimer, C. (Eds). Volcanism and the Earth’s Atmosphere. AGU Geophysical Monograph. 2003; 139:1-8.

D’Alessandro W. Human fluorosis related to volcanic activity: a review. En: Environmental Toxicology. Kunglos AG, Brebbia CA, Samaras V, Propov (Eds.), WIT Press Southampton, Reino Unido; 2006. p.21-30.

Fewtrell L. Smith S, Kay D, Bartram J. An attempt to estimate the global burden of disease due to fluoride in drinking water. J Water Health. 2006; 4:533-542.

Inkielewicz I, Krechniak J. Fluoride content in soft tissues and urine of rats exposed to sodium fluoride in drinking water. Fluoride. 2002; 36: 263-266.

Urbanska B, Czarnowski W, Krechniak J, Inkielewicz I, Stolarska K. Skeletal metabolism and bone mineral density in fluoride-exposed rats. Fluoride. 2001; 34: 95-102.

González Sacramento N, Rubio Armendáriz C, Gutiérrez Fernández A J, Luis Gonzáles G, Hardisson de la Torre A, Revert Gironés C. El agua de consumo como fuente de exposición crónica a fluoruros en Tenerife; evaluación del riesgo. Nutr Hosp. 2015; 31(4): 1787–1794.

BOE (Boletín Oficial de España). Real Decreto 140/2003, por el que se establecen los criterios sanitarios de la calidad del agua de consumo humano. BOE. 2003; 45.

Ahn JS. Geochemical occurrences of arsenic and fluoride in bedrock groundwater: a case study in Geumsan County, Korea. Environ Geochem Health. 2012;34: 43–54.

Armienta MA, Segovia N. Arsenic and fluoride in the groundwater of Mexico. Environ Geochem Health. 2008; 30:345–353.

Wen D, Zhang F, Zhang E, Wang C, Han S, Zheng Y. Arsenic, fluoride and iodine in groundwater of China. J Geochem Explor. 2013; 135:1–21.

Pan G. Confidence intervals for comparing two scale parameters based on Leven´s statistics. J Nonparam Statistic. 2002; 4:459-476.

Choy EHS, Scott DL, Kingsley GH, Thomas A, Murphy AGU, Staimos N. Control of rheumatoid arthritis by oral tolerance. Arthritis Rheum. 2001; 44:1993-1997.

Martínez Álvarez JR, Villarino Marín AL, Polanco Allué I, Iglesias Rosado C, Gil Gregorio P, Ramos Cordero P, López Rocha A, Ribera Casado JM et al. Recomendaciones de bebida e hidratación para la población española. Nutr Clín Diet Hosp. 2008; 28:3-19.

EFSA (European Food Safety Authority). Scientific Opinion on Lead in Food. EFSA J. 2010; 8(4): 1570.

SCHER (Scientific Committee on Health and Environmental Risk). Assessment of the Tolerable Daily Intake of Barium. European Commission. 2012;

http://doi.org/10.2772/49651

IOM (Institute of Medicine). Food and Nutrition Board of the Institute of Medicine of the National Academies. Dietary Reference Intakes for Vitamin A, Vitamin K, Arsenic, Boron, Chromium, Copper, Iodine, Iron, Manganese, Molybdenum, Nickel, Silicon, Vanadium, and Zinc. 2001; National Academy Press, Washington, USA.

WHO (World Health Organization). Strontium and strontium compound. Concise International Chemical Assessment Document. 2010; 77: 1-63.

FESNAD (Federación Española de Sociedades de Nutrición, Alimentación y Dietética). Ingestas dietéticas de referencia (IDR) para la población española. Act Diet. 2010; 14: 196-197.