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Arsenic (III) removal potential of natural and modified fungal biomass from aqueous solution

By: Abdul Rehman Khan, Muhammad Mahmood–ul-Hassan, Rizwan Ahmad, AnjumMunir

Key Words: Fungi, As (III) tolerance, As (III) removal, Aqueous solution

Int. J. Biosci. 12(3), 97-109, March 2018.

DOI: http://dx.doi.org/10.12692/ijb/12.3.97-109

Certification: ijb 2018 0002 [Generate Certificate]

Abstract

The removal of arsenic,a widely occurring natural poisonous metalloid, from water employing biological sorbents having low cost and higher sorption capacity has become an important field of research as arsenic is significantly endangering human health by contaminating drinking water. Filamentous fungi have gained important place as a bio-remedial due to their fine pores, large surface area and metal sorption capacity. In present study, arsenic (As-III) tolerance of 18 indigenous filamentous fungi was explored by exposing them to As concentrations of 50 to 5600 mg kg-1.Out of 18 isolates, 12 belonged to genus Aspergillus, 3 to Fusarium, 2 to Curvularea and one to Penicillium. The fungal isolates (G-2, M-4, I-5) identified as Aspergillus fumigatus and (G-5) as Fusarium oxysporum showed highest As (III) tolerance. The fungal biomasses of highly tolerant fungi, untreated and treated with NaOH and FeCl3, ware then assessed for their arsenic removal capacity from aqueous solutions. The fresh wet biomass of natural and treated fungus was equilibrated with aqueous solutions of varying As (III) concentrations (0-1000 mg L-1).. The maximum As (III) (3.2 mg g-1) was removed by FeCl3-treated Aspergillus fumigatus (G-2) biomass followed by NaOH-treated (2.83 mg g-1) and untreated biomass (2.66 mg g-1). Maximum increase in As (III) removal (33.65 % over untreated) was observed in FeCl3-treatmentedfungal biomass over untreated whereas NaOH treatment enhanced 22.27 %. Arsenic sorption parameters i.e. maximum sorption capacity and binding strength of fungal biomasses were calculated using Langmuir and Freundlic hsorption models. Langmuir regression coefficient (r2) (0.97-0.99) indicated its better fitness to adsorption data than Freundlich model with r2 values (0.85-0.93).The tested arsenic tolerant fungal strains removed significant amounts of arsenic from arsenic enriched media in laboratory conditions and may be used as an effective sorbent in arsenic removal technology from arsenic contaminated waters.

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Arsenic (III) removal potential of natural and modified fungal biomass from aqueous solution

Adriano DC. 2001. Trace elements in terrestrial environments. Biogeochemistry, bioavailability and risks of metals. 2nd  edition. Springer Science+Business Media, LLC, New York, USA.229 p.

Ahamed S, Sengupta MK, Mukherjee A, Hossain MA, Das B, Nayak B, Pal A, Mukhejee SC, Pati S, Dutta RN, Chattejee G, Srivastava R, Chakraborti D. 2006. Arsenic groundwater contamination and its health effects in the state of Uttar Pradesh (UP) in upper and middle Ganga plain, India: A severe danger. Scienceof the Total Environement 370, 310-322.

Akhter S, Mahmood-ul-Hassan M, Ahmad R, Suthor V, Yasin M. 2013. Metal tolerance potential of filamentous fungi isolated from soils irrigated with untreated municipal effluent. Soil and Environment 32(1), 55-62.

Amacher MC. 1996.Nickel, Cadmium and Lead.In: Methods of Soil Analysis. Part 3, SSSA: 739-768.

Amini M, Abbaspour KC, Berg M, Winkel L, Hug SJ, Hoehn E,  Yang H, Johnson CA. 2008. Statistical modeling of global geogenic fluoride in groundwater. Journal of Environmental Science and Technology. 42(10), 3662-3668.

Arica MY, Bayramoglu G, Yilmaz M, Gen CO, Bektas S. 2004. Biosorption   of   Hg2+, Cd2+ and Zn2+ by Ca alginate and immobilized wood rotting fungus Funaliatrogii. Journal of Hazardous Materials. 109, 191–199.

ATSDR. 2002. Arsenic Toxicity: Case studies in environmental medicine. Agency for Toxic Substances and Disease Registry.  USA.

Azcue JM, Nriagu JO, Schiff S. 1994. Role of Sediment Porewater in the Cycling of Arsenic in a Mine-Polluted Lake. Environment International 20, 517-527.

Baldrian P. 2003. Interactions of heavy metals with white-rot fungi, Enzyme. Microbiology Technology 32, 78–91.

Barnett HL, Hunter BB. 1999. Illustrated genera of Imperfect fungi. 4th Ed. Prentice Hall Inc.

Benefield LD, Morgan JS. 1990.  Chemical precipitation in water quality and treatment, in: R.D. Letterman (Ed.) AWWA. 4th Ed. Mc Graw-Hill. New York.

Bodek I, Lyman WJ, Reehl WF, Rosenblatt DH. 1998. Environmental Inorganic Chemistry: Properties, Processes and Estimation Methods. Pergamon Press, USA.

British Geological Survey, Mott MacDonald Ltd. 1999.Groundwater Studies for Arsenic Contamination in Bangladesh. Final Report. In: British Geological Survey, London, UK.

Cernansky S, Urik M, Seve J, Littera P, Hiller E. 2007. Biosorption of arsenic and cadmium from aqueous solution. African Journal of Biotechnology 6, 1932-1934.

Chatterjee A, Das D, Chakraborti. 1993. A study of ground water contamination by arsenic in the residential area of behala, Calcutta due to industrial pollution. Environmental Pollution 80, 57-65.

Clifford DA. 1999. Ion-exchange and inorganic adsorption, in: Water Quality and Treatment: A Handbook of Community Water Supplies. 5thed.  American Water Works Association. Mc Graw-Hill. New York.

Couto SR, Sanroman SA, Hofer D, Gubitz GM. 2004. Stainless steel: A novel carrier for the immobilization of the white rot fungus Trameteshirsute for decolorization of textile dyes.  Bioresource Technology 95, 67–72.

Dhar RK, Biswas BK, Samanta G, Mandal B. K, Chakraborti D, Roy S, Jafar A, Islam A, Ara G, Kabir S. 1997. Groundwater arsenic calamity in Bangladesh. Current Science 73, 48-59.

FAO/WHO. 2001. Codex alimentarius commission. Food additives and contaminants. Jooint FAO/WHO Food Standards Program 2001. FAO Vialedelle Terme di Caracalla, Rome, Italy.

FAO. 2006. Arsenic contamination of irrigation water, soil and crops in Bangladesh: risk implications for sustainable agriculture and food safety in Asia. ISBN.974-9746-88-2.

FAO. 2007.  Remediation of Arsenic for Agriculture, Sustainability, Food security and Health in Bangladesh. Available at

www.fao.org/3/a-ap102e.pdfon 01-12-2015

Gadd GM, White C. 1993. Microbial treatment of metal pollution -a working biotechnology? Trends in Biotechnology.11, 353-359.

Gadd GM, Gharieb MM, Ramsay LM, Sayer JA, Whatley AR, White C.. 1993. Fungal Processes for Bioremediation of Toxic Metal and Radionuclide Pollution. Journal of Chemical Technology and Biotechnology 71, 364-5.

Ge W, Zamri D, Mineyama H, Valix M. 2011. Bioaccumulation of heavy metals on adapted Aspergillus foetidus. Adsorption.17, 901–910.

Giller KE, Witter E, McGrath SP. 1998. Toxicity of heavy metals to microorganisms and microbial processes in agricultural soils: a review. Soil Biology

and Biochemistry 30(10-11), 1389–1414.

Iram S, Ahmad I, Stuben D. 2009. Analysis of mines and contaminated agricultural soil samples for fungal diversity and tolerance to heavy metals. Pakistan Journal of Botany 41(2), 885-895.

Jain K, Ali I. 2000. Arsenic occurrence, toxicity and speciation techniques. Water Research. 34, 4304–4312.

Kadukova J, Vircikova E. 2005. Comparison of differences between copper bioaccumulation and biosorption. Environment International. 31(2), 227–232.

Kim DH, Kim KW, Cho J. 2006. Removal and transport mechanisms of arsenics in UF and NF membrane processes. Journal of Water Health.4 (2): 215–223.

Krznaric E, Verbruggen N, Wevers JH, Carleer R, Vangronsveld J, Colpaert JV. 2009. Cd-tolerant Suillusluteus: a fungal insurance for pines exposed to Cd. Environmental Pollution. 157, 1581–1588.

Maheswari S, Murugesan AG. 2011. Removal of arsenic (III) from aqueous solutions using Aspergillus flavus isolated from arsenic contaminated sites. Indian Journal of Chemical Technology. 18, 45-52.

Maheswari S, Murugesan AG. 2009. Remediation of arsenic in soil by Aspergillus nidulans isolated from an arsenic-contaminated site. Environemental Technology 30(9), 921–926.

Maheswari S, Murugesan AG. 2009. Biosorption of arsenic (III) ion from aqueous solution using Aspergillus fumigatus isolated from arsenic contaminated site. Desalination and Water Treatment 11, 1-3, 294-301.

Malik A, Jiswal R.2000. Metal resistance in pseudomonas strains isolated from soil treated with industrial wastewater. World Journal of Microbiology and Biotechnology 30, 261- 278.

Mandal BK, Suzuki KT.2002. Arsenic round the world: a review. Talanta 58, 201-235.

Martino E, Turnau K, Girlanda M,  Bonfateand P, Perroto S. 2000. Ericoid mycorrhizal fungi from heavy metal polluted soils: their identification and growth in the presence of zinc ions. Mycological Research 184, 338-44.

Morley GF, Gadd GM. 1995. Sorption of toxic metals by fungi and clay minerals. Mycological Research 99, 1429-1438.

Mukherjee KK, Das D, Samal AC, Santra SC. 2013. Isolation and characterization of Arsenic tolerant fungal strains from contaminated sites around urban environment of Kolkata. Journal of Environemental Science and Food Technology 7(5),  33-37.

PCRWR. 2007. Arsenic Monitoring and Mitigation in Pakistan.  Pakistan Council of Research on Water Resources. Annual Report 2005-2006.136-140.

Razak AA, Bachman G,  Farrag R. 1999. Activities of microflora in soils of upper and lower Egypt. African Journal of Mycology and Biotechnology 7, 1-19.

Sathishkumar M, Binupriya AR, K. Swaminathan JG, Choi, Yun SE. 2008. Bio-Separation of Toxic Arsenate Ions from Dilute Solutions by Native and Pretreated Biomass of Aspergillus fumigatusin Batch and Column Mode: Effect of Biomass Pretreatment. Bull Environment. Contam. Toxicol.

http://dx.doi.org/10.1007/s00128-008-9496-4.

Sag Y. 2001. Biosorption of heavy metals by fungal biomass and modeling of fungal biosorption: A review. Purification Methods 30(1), 1–48.

Say R, Yilmaz N, Denizli A. 2003. Biosorption of cadmium, lead, mercury, nd arsenic ions by fungus Penicillium purpurogenum. Separation Science and Technology 38(9), 2039–2053.

Smedley PL, Kinniburgh DG. 2002. A review of the source, behavior and distribution of arsenic in natural waters. Applied Geochemistry 17, 517-568.

Smedley PL, Nicolli HB, Macdonald DMJ, Barros AJ, Tullio JO. 2002. Hydro geochemistry of arsenic and other inorganic constituents in ground waters from La Pampa, Argentina.  Applied Geochemistry 17(3), 259–284.

Smith AL, Lopipero PA, Bates MN, Steinmaus CM. 2002. Arsenic epidemiology and drinking water standards. Science 296, 2145– 2146.

Smith E, Naidu R, Alston AM. 1998. Arsenic in the soil environment; a review. Advances in Agronomy 64, 149-195.

Suzuki TM, Bomani JO, Matsunaga H, Yokoyama T. 2000. Preparation of porous resin loaded with crystalline hydrous zirconium oxide and its application to the removal of arsenic. Reactive and Functional Polymers 43(1–2), 165–172.

Thomas GW. 1996. Soil pH and soil acidity. In: Methods of Soil Analysis. Part 3. Chemical Methods. Ed. J.M. Bartels. SSSA-ASA, Medison, Wisconsin, USA: 475-490.

Valix M, Loon LO. 2003. Adaptive tolerance behavior of fungi in heavy metals. Minerals Engineering 16, 193–198.

Veglio F, Beolchini F. 1997. Removal of metals by biosorption: a review, Hydrometallurgy 44, 301–316.

Visoottiviseth P, Panviroj N. 2001. Selection of fungi capable of removing toxic arsenic compounds from liquid medium. Science Asia 27, 83–92.

WHO. 2003. Source and behaviour of arsenic in natural waters. In: Ch.1.United Nations synthesis report on arsenic in drinking water.

WHO. 2001. Arsenic and Arsenic Compounds. Environment Health Criteria. 2nd Ed. World Health Organization. Geneva.

WHO. 1999. Arsenic in drinking water. Fact sheet No.210. Available at

www.knowledgebank.irri.org/factsheetsPDF/Health_and_Nutrition/whoFS_arsenic.pdf.on2-10-2015.

Xu X, Xia L, Huang Q, Gu JD, Chen W. 2012. Biosorption of cadmium by a metal-resistant filamentous fungus isolated from chicken manure compost. Environmental Technology 33, 1661–1670.

Yazdani M, Yap CK, Abdullah F, Tan SG. 2010. An in vitro study on the adsorption, absorption and uptake capacity of Zn by the bioremediator Trichodermaatroviride. Environment Asia.3:53–59.

Yoshida N, Ikeda R, Okuno T. 2006. Identification and characterization of heavy metal resistant unicellular algae isolated from soil and its potential for phytoremediation. Bioresource Technology 97, 1843-1849.

Zafar S, Aqil F, Ahmad I. 2007. Metal tolerance and biosorption potential of filamentous fungi isolated from metal contaminated agricultural soil. Bioresource Technology 98, 2557–61.

Zaw M, Emett MT. 2002. Arsenic removal from water using advanced oxidation processes. Toxicology Letters. 133(1), 113–118.

Abdul Rehman Khan, Muhammad Mahmood–ul-Hassan, Rizwan Ahmad, AnjumMunir.
Arsenic (III) removal potential of natural and modified fungal biomass from aqueous solution.
Int. J. Biosci. 12(3), 97-109, March 2018.
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