ABSTRACT
Plottier y Senillosa son dos localidades contiguas que forman parte del área de producción agrícola del Alto Valle de Río Negro y Neuquén, Patagonia Norte. Entre los plaguicidas más utilizados predominan las familias de neonicotinoides, carbamatos y organofosforados. El conocimiento de los niveles de estos compuestos en aguas superficiales y subterráneas se ha convertido en un tema de interés social debido a su posible impacto en el ambiente y la salud. El objetivo del presente trabajo fue determinar niveles de residuos de plaguicidas en agua subterránea utilizada para bebida en zonas rurales de Plottier y Senillosa. Se analizaron carbamatos: propoxur, carbofuran, pirimicarb, carbaril y organofosforados: clorpirifos, dimetoato, metidation, fenaminfos, triazofos, fosmet y metil azinfos, por cromatografía gaseosa (GC), en seis sitios de muestreo, durante la época de aplicación y no aplicación de insecticidas. No se detectaron residuos de los plaguicidas estudiados por el método analítico utilizado. El límite de detección fue 0,010 µg/L para organofosforados y 0,030 µg/L para carbamatos. Estos resultados indican que las buenas prácticas agrícolas aplicadas en la zona así como las características fsicoquímicas del suelo, su espesor y el contenido de materia orgánica y las propiedades fsicoquímicas de los plaguicidas estudiados son factores que contribuyen favorablemente a la calidad del agua de bebida de la población rural.
Plottier and Senillosa are two adjoining towns that belong to the agricultural production area of Upper Valley, Río Negro and Neuquén, North Patagonia. Among the most widely used pesticides, neonicotinoids, carbamates and organophosphates are predominant. The levels of these compounds in surface and groundwater have become a topic of public concern, since the possible impact on health and environment. The aim of this study was the determination of pesticide residue levels in drinking ground-water in the rural areas of Plottier and Senillosa. Carbamates: propoxur, carbofuran, pirimicarb, carbaryl and organophosphate: chlorpyrifos, dimethoate, methidathion, fenaminfos, triazophos, phosmet, azinphos methyl, were analyzed by GC in six sampling sites during insecticide application and non-application season. No pesticide residues were detected by the analytical method used. The detection limit for organophosphates was 0.010 µg/L and 0.030 µg/L for carbamates. These results indicate that good agricultural practices, the physicochemical characteristics of the soil, its thickness, the content of organic matter and the physicochemical properties of pesticides studied are factors that positively contribute to the drinking water quality in the rural population.
Subject(s)
Organophosphorus Compounds/isolation & purification , Pesticides/toxicity , Groundwater/analysis , Carbamates/isolation & purification , Carbamates/toxicity , Pesticides/analysis , Drinking Water , Chromatography, Gas/methodsABSTRACT
Organophosphorus pesticides are one of the most prevalent usages for pest control in the country. Such pesticides enter into water sources by different routes. Since drinking of contaminated water at the higher doses than the standard level, may causes undesirable effects to human health and ecosystem. The object of this research was to investigate the effect of various parameters including time, power and concentration on sonodecomposition of malathion insecticide in the water. The sonochemical degradation of malathion was investigated using acoustic wave technology [AWT]. AWT with 130 kHz was used to study the decomposition of insecticide solution. Samples were analyzed using HPLC at different intervals times. Effectiveness of AWT at different times [20, 40, 60, 80, 100, and 120 minutes], concentrations of malathion at 2, 4 and 8 mg/L as well as powers of device [300W, 400W, 500W] are compared. These findings showed that the degradation of the malathion insecticide at lower concentrations was greater in comparison to higher concentrations. Also, there was positive correlation between power increasing and the ability to malathion degradation. The sonodegradation of malathion at different concentrations and powers was successfully achieved. It has been shown that acoustical wave technology can be used to reduce the concentration of dissolved insecticide using high frequency