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01.12.2017 | Original Article

Evaluation of the removal of heavy metals in a natural wetland impacted by mining activities in Mexico

verfasst von: Juan Miguel Gómez-Bernal, Esther Aurora Ruiz-Huerta, María Aurora Armienta-Hernández, Víctor Manuel Luna-Pabello

Erschienen in: Environmental Earth Sciences | Ausgabe 23/2017

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Abstract

This research is focused on evaluating heavy metals (Cd, Cu, Fe, Mn, Pb, and Zn) uptake and removal by Eleocharis ovata, Cyperus manimae, Typha dominguensis, and Pteridium aquilinum in a natural wetland impacted by mining activities. We analyzed heavy metals content and distribution in native plants, soils, and water of a semipermanent natural wetland in Taxco de Alarcón, Guerrero, and we also determined the physicochemical characteristics of the water. Translocation factor (TF) and bioconcentration factor (BCF) were evaluated. Results showed that physical and chemical conditions are favorable for plants development. Correlation analysis showed a good and positive relation (0.95) between Cu and Pb in soils and plants. In the analyzed matrices: Zn (0.62–2.20 mg/L) exceeded the permissible limits in water, high concentrations of Pb and Zn (26.57–525.67 and 266.67–983.33 mg/kg, respectively) were detected in the studied soils, and Pb exceeded the normal range for E. ovata and P. aquilinum in the analyzed plants. Uptake of heavy metals in the tissues of different species was found in the following order: root > leaf. Data of TF and BCF showed that E. ovata is a tolerant plant with respect to heavy metals exposure since TF value was greater than 1. This study showed that E. ovata could be considered as a bioaccumulator of heavy metals in contaminated soils.

Vorheriger Artikel Impact of mechanochemical treatment of organophilic Indian bentonites: implications for their rheology

Nächster Artikel Spatial distribution, mineralogy, and weathering of heavy metals in soils along zinc-concentrate ground transportation routes: implication for assessing heavy metal sources

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Ahmad JU, Goni MA (2010) Heavy metal contamination in water, soil, and vegetables of the industrial areas in Dhaka, Bangladesh. Environ Monit Asses 166:347–357CrossRef

Aksoy A, Demirezen D, Duman F (2005) Bioaccumulation, detection and analyses of heavy metal pollution in Sultan Marsh and its environment. Water Air Soil Pollut 164:241–255CrossRef

Allen SE (1989) Chemical analysis of ecological materials. Blackwell Scientific, Oxford

Alloway BJ (1995) Heavy metals in soils. Chapman and Hall, CambridgeCrossRef

American Public Health Association (APHA), American Water Works Association (AWWA), Water Environment Federation (WEF) (2005) Standard methods for the examination of water and wastewater, vol 1, 21st edn. American Public Health Association, Washington

Andersen E, Küpper H (2013) Cadmium toxicity in plants. In: Sigel A, Sigel H, Sigel RKO (eds) Cadmium: From toxicity to essentiality. Springer, pp 395–413

Anteproyecto de Norma Oficial Mexicana (2003) Que establece criterios para determinar niveles de limpieza para la remediación de suelos contaminados por metales y metaloides. Secretaría del Medio Ambiente y Recursos Naturales

Armienta MA, Zamora V, Juárez F (1987) Manual para el Análisis Químico de Aguas Naturales, en el Campo y en el Laboratorio, instituto de Geofísica. Universidad Nacional autónoma de México, Comunicaciones técnicas, Serie Docencia y Divulgación No. 4

Awashthi SK (2000) Prevention of Food Adulteration Act No 37 of 1954. Central and state rules as amended for 1999. Ashoka Law House, New Delhi

Baldantoni D, Alfani AD, Tommasi P et al (2004) Assessment of macro and microelement accumulation capability of two aquatic plants. Environ Pollut 130:149–156CrossRef

Beckett HT, Davis RD (1977) Upper critical levels of toxic elements in plants. New Phytol 79:95–106CrossRef

Benavides MP, Gallego SM, Tomaro ML (2005) Cadmium toxicity in plants. Braz J Plant Physiol 17:21–34CrossRef

Bonanno G, Giudice RL (2010) Heavy metal bioaccumulation by the organs of Phragmites australis (common reed) and their potential use as contamination indicators. Ecol Indic 10:639–645CrossRef

Borkert CM, Cox FR, Tucker Mr (1998) Zinc and copper toxicity in peanut, soybean, rice, and corn in soil mixtures. Commun Soil Sci Plant Anal 29:2991–3005CrossRef

Carranza-Alvarez C, Alonso-Castro AJ, Alfaro-De La Torre MC, García-De La Cruz RF (2008) Accumulation and distribution of heavy metals in Scirpus americanus and Typha latifolia from an artificial lagoon in San Luis Potosí, México. Water Air Soil Pollut 188:297–309CrossRef

Chandanshive VV, Rane NR, Tamboli AS, Gholave AR, Khandare RV, Govindwar SP (2017) Co-plantation of aquatic macrophytes Typha angustifolia and Paspalum scrobiculatum for effective treatment of textile industry effluent. J Hazard Mater 338:47–56CrossRef

Clemens S (2006) Toxic metal accumulation, responses to exposure and mechanisms of tolerance in plants. Biochimie 88:1707–1719CrossRef

Clemens S, Ma JF (2016) Toxic heavy metal and metalloid accumulation in crop plants and foods. Annu Rev Plant Biol 67:489–512CrossRef

Consejo de Recursos Minerales (CRM) (2003) Carta Geológico-Minera Taxco E14-A68 Secretaria de Economía –CRM

Das P, Samantaray S, Rout GR (1997) Studies on cadmium toxicity in plants: a review. Environ Pollut 98:29–36CrossRef

Dorlodot S, Lutts S, Bertin P (2005) Effects of ferrous iron toxicity on the growth and mineral composition of an inter specific rice. J Plant Nutr 28:1–20CrossRef

Engin MS, Uyanik A, Kutbay HG (2015) Accumulation of heavy metals in water, sediment and wetland plants of Kizilirmak delta (Samsun, Turkey). Int J Phytoremediation 17:66–75CrossRef

European Union (2006) Commission Regulatory (EC)No. 1881/2006 of 19 December 2006 setting maximum levels for certain contaminants in foodstuffs. Off J Eur Union 364:5–24

Ganjali S, Tayebi L, Atabati H et al (2014) Phragmites australis as a heavy metal bioindicator in the Anzali wetland of Iran. Toxicol Environ Chem 96:1428–1434CrossRef

Gómez-Bernal JM, Morton-Bermea O, Ruiz-Huerta EA et al (2014) Microscopic evidences of heavy metals distribution and anatomic alterations in breaching-leaves of Cupressus lindleyi growing around mining wastes. Microsc Res Tech 77:714–726CrossRef

Gómez-Bernal JM, Ruiz-Huerta EA, Armienta-Hernandez Ma et al (2017) Phytoavailability index of heavy metals and arsenic in Pioneer plants of a semi-permanent natural wetlands. Environ Prog Sustain Energy. https://doi.org/10.1002/ep.12759. Version of Record online: 21 Sept 2017

Guo J, Dai X, Xu W et al (2008) Over expressing GSHI and AsPCSI simultaneously increases the tolerance and accumulation of cadmium and arsenic in Arabidopsis thaliana. Chemosphere 72:1020–1026CrossRef

Ha NTH, Sakakibara M, Sano S (2011) Accumulation of Indium and other heavy metals by Eleocharis acicularis: an option for phytoremediation and phytomining. Bioresour Technol 102:2228–2234CrossRef

INEGI (Instituto Nacional de Estadística, Geografía e Informática) (1999) Síntesis Geográfica del Estado de Guerrero. Instituto Nacional de estadística, Geografía e Informática, Aguascalientes, México

Kabata-Pendias A, Pendias H (2001) Trace elements in soils and plants. CRC Press, Washington

Khan S, Waqas M, Ding F, Shamshad I, Arpd HPH, Li G (2015) The influence of various biochars on the bioaccessibility and bioaccumulation of PAHs and potentially toxic elements to turnips (Brassica rapa L.). J Hazard Mater 300:1–11CrossRef

Klink A, Maciol A, Wislocka M, Krawczyk J (2013) Metal accumulation and distribution in the organs of Typha latifolia L. (cattail) and their potential use in bioindication. Limnol Ecol Manag Inland Waters 43:164–168CrossRef

Lasat MM, Pence NS, Garvin DF et al (2000) Molecular physiology of zinc transport in the Zn hyperaccumulator Thlaspi caerulescens. J Exp Bot 51:71–79CrossRef

Lewis S, Donkin ME, Depledge MH (2001) Hsp 70 expression in Enteromorpha intestinalis (Chlorophyta) exposed to environmental stressors. Aqua Toxicol 51:277–291CrossRef

Loneragan JF (1988) Distribution and movement of manganese in plants. In: Graham RD, Hannam RJ, Uren NC (eds) Manganese in soils and plants. Springer, Berlin

Lottermoser BG, Ashley PM (2011) Trace element uptake by Eleocharis equisetina (spike rush) in an abandoned acid mine tailings pond, northeastern Australia: implications for land and water reclamation in tropical regions. Environ Pollut 159:3028–3035CrossRef

Mishra VK, Tripathi BD (2008) Concurrent removal and accumulation of heavy metals by the three aquatic macrophytes. Bioresour Technol 99:7091–7097CrossRef

Mohanpuria P, Rana NK, Yadav SK (2007) Cadmium induced oxidative stress influence on glutathione metabolic genes of Camella sinensis (L.) O Kuntze. Environ Toxicol 22:368–374CrossRef

Morton-Bermea O, Gómez-Bernal JM, Armienta MA et al (2014) Metal accumulation by plant species growing on a mine contaminated site in Mexico. Environ Earth Sci 71:5207–5213CrossRef

Neelima P, Reddy KJ (2002) Interaction of copper and cadmium with seedlings growth and biochemical responses in Solanum melongena. Environ Pollut Technol 1:285–290

Norma Oficial Mexicana NOM-147-SEMARNAT/SAA1-2004 (2007) Que establece criterios para determinar las concentraciones de remediación de suelos contaminados por Arsénico, Bario, Berilio, Cadmio, Cromo hexavalente, Mercurio, Níquel, Plata, Plomo, Selenio, Talio y Vanadio. Publicado en el Diario Oficial de la Federación el viernes 2 de marzo de

Outridge PM, Noller BN (1991) Accumulation of toxic trace elements by freshwater vascular plants. In: Ware GW (ed) Reviews of environmental contamination and toxicology. Springer, Berlin, pp 1–63

Pais I, Jones JB (2000) The handbook of trace elements. St. Luice Press, Florida

Popescu IV, Stihi C, Cimpoca GhV et al (2009) Environmental samples analysis by atomic absorption spectrometry (AAS) and inductively coupled plasma-optical emission spectroscopy (ICP_AES). Rom J Phys 54:7–8

Reeves RD, Baker AJM (2000) Metal-accumulating plants. In: Raskin I, Ensley BD (eds) Phytoremediation of toxic metals: using plants to clean up the environment. Wiley, New York, pp 193–229

Romero FM, Armienta MA, Gutierrez ME et al (2008) Factores geológicos y climáticos que determinan la peligrosidad y el impacto ambiental de jales mineros. Rev Int Contam Ambient 24(2):43–54

Ruiz-Huerta EA, Armienta-Hernández MA (2012) Acumulación de arsénico y metales pesados en maíz en suelos cercanos a jales o residuos mineros. Rev Int Contam Ambient 28:103–117

Sanita di Toppi L, Gabbrielli R (1999) Response to cadmium in higher plants. Environ Exp Bot 41:105–130CrossRef

Sasmaz A, Obek E, Hasar H (2008) The accumulation of heavy metals in Typha latifolia L. grown in a stream carrying secondary effluent. Ecol Eng 33:278–284CrossRef

Sawidis T, Chettri MK, Papaioannou A et al (2001) A study of metal distribution from lignite fuels using trees as biological monitors. Ecotoxicol Environ Saf 48:27–35CrossRef

Secretaría de Medio Ambiente y Recursos Naturales (SEMARNAT) (1997) Norma Oficial Mexicana NOM-001-SEMARNAT-1996, Que establece los límites máximos permisibles de contaminantes en las descargas de agua residuales en aguas y bienes nacionales. Diario Oficial de la Federación. 6 de enero de 1997

SEDUE (Secretaría de Desarrollo Urbano y Ecología) (1990) Acuerdo por el que se establecen los Criterios Ecológicos de Calidad del Agua. CE-CCA-001/89. Gaceta Ecológica

Siedlecka A, Tukendorf A, Skórzyńska-Polit E et al (2001) Angiosperms (Asteraceae, Convolvulaceae, Fabaceae and Poaceae; other than Brassicaceae). In: Prasad MNV (ed) Metals in the environment. Analysis by biodiversity. Marcel Dekker Inc, New York, pp 171–217

Sukreeyapongse O, Holm PE, Strobel BW et al (2002) pH-dependent release of cadmium, copper, and lead from natural and sludge-amended soils. J Environ Qual 31:1901–1909CrossRef

U.S. Environmental Protection Agency (EPA) (1986) Quality criteria for water. Office of Water Regulations and Standards, Washington

U.S. Environmental Protection Agency (EPA) (2005) Guidance for developing ecological soil screening levels. Office of Solid Waste and Emergency Response, Washington

US EPA (1992) Technical support document for land application of sewage sludge, Document No. EPA-822/R0-93-001a

Wintz H, Fox T, Vulpe C (2002) Responses of plants to iron, zinc and copper deficiencies. Portland Press Limited, London

World Health Organization (1980) Recommended health-based limits in occupational exposure to heavy metals: report of a WHO study group [meeting held in Geneva from 5 to 11 June 1979]

Wu S (1994) Effect of manganese excess on the soybean plant cultivated under various growth conditions. J Plant Nutr 17:993–1003

Xie Z, Jiang Y, Zhang H et al (2016) Assessing heavy metal contamination and ecological risk in Poyang Lake area, China. Environ Earth Sci 75:549CrossRef

Yanqun Z, Yuan L, Jianjun C et al (2005) Hyperaccumulation of Pb, Zn and Cd in herbaceous grown on lead–zinc mining area in Yunnan, China. Environ Int 31:755–762CrossRef

Zhuang W, Gao XL (2014) Integrated assessment of heavy metal pollution in the surface sediments of the Laizhou Bay and the coastal waters of the Zhangzi Island, China: comparison among typical marine sediment quality indices. PLoS ONE 9(4):e94145CrossRef

Titel: Evaluation of the removal of heavy metals in a natural wetland impacted by mining activities in Mexico
verfasst von: Juan Miguel Gómez-Bernal
Esther Aurora Ruiz-Huerta
María Aurora Armienta-Hernández
Víctor Manuel Luna-Pabello
Publikationsdatum: 01.12.2017
Verlag: Springer Berlin Heidelberg
Erschienen in: Environmental Earth Sciences / Ausgabe 23/2017
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-017-7144-1

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