Assessment of heavy metals concentrations in different parts of Diplazium esculentum in selected riverine system of Bunawan, Agusan del Sur, Philippines

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Research Paper 01/12/2021
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Assessment of heavy metals concentrations in different parts of Diplazium esculentum in selected riverine system of Bunawan, Agusan del Sur, Philippines

Vivian C Peligro
J. Bio. Env. Sci.19( 6), 106-114, December 2021.
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Abstract

Heavy metals are essential for the proper functioning of the biological systems but their deficiency or excess could lead to several disorders. Thus, this study aimed to assess the levels of heavy metals (lead, chromium, cadmium) concentrations of Diplazium esculentum in the selected riverine system of Bunawan, Agusan del Sur. Three (3) sub-stations were established in each area. Selected physicochemical parameters were determined. Two (2) kilograms of plant samples were collected in each site separating the roots, stems, and fronds. Both water and plant samples were subjected to acid digestion and were analyzed using the MP-AES method. Results revealed that all the physicochemical properties were within the desirable limits except for the dissolved oxygen in station 1 (Agsao River). Heavy metals concentrations were compared to the standard value set by USEPA and WHO. Lead and chromium concentrations in water samples were within the standard limit. However, cadmium was below the detectible limit in both water and plant samples in all stations. Moreover, lead and chromium contents of D. esculentum in all parts across all stations were remarkably higher than tolerable limits. The highest accumulation was on its roots because it is responsible for the uptake of nutrients including pollutants. Hence, D. esculentum is a good Pb and Cr accumulator. Furthermore, constant monitoring and evaluation for the heavy metal’s concentrations in the sampling stations both in water and plant samples are necessary. Likewise, the levels of heavy metal pollutants must be checked before consumption to ensure safe use of this plant.

VIEWS 71

Copeland EB. 1942. “Edible Ferns”. American Fern Journal 32(4), 121-126. doi:10.2307/1545216.

Das DK. 2015. In: Introductory Soil Science, 4 edn; Kalyani Publishers, Ludhiana/New Delhi, India.

Das DK. 2016. Assessment of heavy metal accumulation in medicinal plants and possible remedial measures. Journal of Pharmaceutical Research 15(3), 63-66.

Garbisu C, Alkorta I. 2001. Phytoextraction: A cost effective plant-based technology for the removal of metals from the environment. Biores. Technol 77(3), 229-236. [doi:10.1016/S0960-8524(00)00108-5].

Gisbert C, Ros R, de Haro A, Walker DJ, Pilar Bernal M, Serrano R, Avino JN. 2003. A plant genetically modified that accumulates Pb is especially promising for phytoremediation. Biochem. Biophys. Res. Commun 303(2), 440-445. DOI: 10.1016/S0006 -291X(03)00349-8.

Jasim HS, Idris M, Abdullah A, Kadhum AAH. 2014. Effects of Physicochemical Soil Properties on the Heavy Metal Concentrations of Diplaziumesculentum (medicinal plant) from the UKM and TasikChini, Malaysia. International Journal of ChemTech Research 6(14), 5519-5527; ISSN : 0974-4290.

Jasim HS, Idris M, Abdullah A, Kadhum AAH. 2014. Determination of Heavy Metals in Soil and Different Parts of Diplazium esculentum (Medicinal Fern). AIP Conference Proceedings 1614, 713.

Kachenko AG, Singh B, Bhatia NP. 2007. Heavy metal tolerance in common fern species. Australia Journal of Botany 300, 207-219.

Klaassen CD. 2001. Casarett and Doull’s toxicology: the basic science of poisons. (New York, USA: McGraw-Hill).

Lone MI, He Z, Stoffella PJ, Yang X. 2008. Phytoremediation of heavy metal polluted soils and water: Progresses and perspectives. Journal of Zhejiang University SCIENCE B ISSN 1673-1581 (Print); ISSN 1862-1783.

Mahmoud AS, Emmanuel E, Joseph J, Bobby LW. 2001. Chemical Evaluation of Commercial Bottled Drinking Water from Egypt, J. Food Composition Analysis 14, 127-152.

McGrath SP, Zhao FJ, Lombi E. 2001. Plant and rhizosphere process involved in phytoremediation of metal-contaminated soils. Plant Soil 232(1/2), 207-214. [doi:10.1023/A:1010358708525.

Neeratanaphan L. 2016. Cadmium, chromium, and lead accumulation in aquatic plants and animals near a municipal landfill. Human and Ecological Risk Assessment: An International Journal. DOI: doi.org/10.1080/10807039.2016.1248893.

Nriagu JO, Pacyna JM. 1988. Quantitative assessment of worldwide contamination of air water and soils by trace metals. Nature 333(6169), 134-139. DOI: doi:10.1038/333134 a0.

Peligro VC, Jumawan JC. 2015. Aquatic macroinvertebrates diversity and Riparian Channel and Environmental Inventory in Gibong River, Philippines. Journal of Entomology and Zoology Studies 3(5), 398-405.

Prasannakumari AA, Gangadevi T, Jayaraman PR. 2014. Absorption potential for heavy metals by selected ferns associated with Neyyar River (Kerala), South India. International Journal of Environmental Sciences 5(2), ISSN 0976 – 4402.

Promsid P. 2014. Chromosomal Aberration Assessment of Fish in Reservoir Affected by Leachate in Municipal Landfill. Master’ Thesis, Department of Environmental Science, Faculty of Science, Khon Kaen University, Nong Khai, Thailand.

Rai V, Agnihotri AK, Khatoon S, Rawat AK, Mehrotra S. 2005. Chromium in some herbal drugs. BullEnviron Contam Toxicol 74, 464-469.

Reddy AM, Kumar SG, Jyonthsnakumari G. 2005. Lead induced changes in antioxidant metabolism of horsegram (Macrotyloma uniflorum (Lam.) Verdc.) and bengalgram (Cicer arietinum L.). Chemosphere 60, 97-104.

Schalscha E, Ahumada I. 1998. Heavy metals in rivers and soils of central chile. Water Sci. Technol 37(8), 251-255. [doi:10.1016/S0273-1223(98)00255-8].

Shanker AK, Cervantes C, Loza-Tavera H, Avudainayagam S. 2005. Chromium toxicity in plants. Environ Int 31, 739-753.

Sriuttha M, Tengjaroenkul B, Intamat S, Phoonaploy U, Thanomsangad P, Singh KP, Bhattacharya S, Sharma P. 2014;Assessment of heavy metal contents of some Indian medicinal plants. American-Eurasian J Agric Environ Sci 14, 1125-1129.

Tantemsapya N, Naksakul Y, Wirojanagud W. 2011. Mathematical modeling of heavy metals contamination from MSW landfill site in Khonkaen, Thailand. Water Sci Technol 64(9), 1835-42.

Tepe Y, Mutlu E. 2005. Physico-chemical characteristics of Hatay Harbiye Spring water, Turkey, J of the Inst. Of Sci and Tech. of Dumlupinar University 6, 77-88.

Tiwari KK, Singh NK, Patel MP 2011. Metal contamination of soil and translocation in vegetables growing under industrial wastewater irrigated agricultural field of Vadodara, Gujarat, India. Ecotoxicol Environ Saf 74, 1670-7.

Tiwari KK, Singh NK, Patel MP. 2011. Metal contamination of soil and translocation in vegetables growing under industrial wastewater irrigated agricultural field of Vadodara, Gujarat, India. Ecotoxicol Environ Saf 74, 1670-7.

Tong S, von Schirnding YE, Prapamontol T. 2000; Environmental lead exposure: a public problem of global dimension. Bull World Health Organ 78, 1068-1077.

Vanek A, Boruvka L, Drabek O, Mihaljevic M, Komarek M. 2005. Mobility of Lead, Zinc and Cadmium in Alluvial Soils Heavily Polluted by Smelting Industry, Plant, Soil and Environment 51(7), 316-321.

WHO. 2007. WHO Guidelines for Assessing Quality of Herbal Medicines with Reference to Contaminants and Residues. (Geneva, Switzerland; World Health Organization).

Wold F, Ayenew B, Ahmad T. 2016. Assessment of heavy metals concentration in Togona river of goba town, oromia region, Ethiopia. Int. J. Chem. Sci 14(4), 3207-3214; ISSN 0972-768X.

Yap CK, Fitri MRM, Mazyhar Y, Tan SG. 2010; Effects of metal-contaminated soils on the accumulation of heavy metals in different parts of Centella asiatica: A laboratorystudy. Sains Malaysiana 39, 347-352.