Phytoremediation and Bioconcentration of Mineral and Heavy metals in Zea mays Inter-planted with Striga hermonthica in Soils from Mechanic Village Wukari

E. A. Yerima; A. U.  Itodo; R. Sha’Atob; R. A. Wuana; G. O. Egah; S. P. Ma’ajia

doi:10.46481/asr.2022.1.2.9

Authors

E. A. Yerima
[email protected]

Department of Chemical Sciences, Federal University Wukari, PMB 1020, Taraba State, Nigeria
A. U. Itodo
Department of Chemistry, Federal University of Agriculture, Makurdi, PMB 2373, Benue State, Nigeria
R. Sha’Atob
Department of Chemistry, Federal University of Agriculture, Makurdi, PMB 2373, Benue State, Nigeria
R. A. Wuana
Department of Chemistry, Federal University of Agriculture, Makurdi, PMB 2373, Benue State, Nigeria
G. O. Egah
Department of Chemical Sciences, Federal University Wukari, PMB 1020, Taraba State, Nigeria
S. P. Ma’ajia
Department of Chemical Sciences, Federal University Wukari, PMB 1020, Taraba State, Nigeria

Keywords:

Minerals, Potentially toxic metals, Bio-concentrations, Phytoremediation

Abstract

Phytoremediation involves the use of plants to remediate contaminated sites. This study evaluates the effect of phytoremediation on mineral and heavy metal concentration in agricultural soil within the vicinity of mechanic village Wukari using Zea mays interplanted with Striga hermonthica (SMV-MS), Zea mays alone (SMV-M), Zea mays inter-planted with Striga hermonthica alongside the application of fertilizer (SMV-MSF) and Zea mays alone alongside fertilizer application (SMV-MF). The bioconcentration of mineral and heavy metal and their translocation factors from the root to shoot of maize plants were estimated using empirical models. The result reveals that the efficiency of phytoextraction of the mineral and heavy metals were within the range: P (3.12 – 44.71 %), K (16.89 – 96.32 %), Mg (0.013 – 94.12 %), Mn (2.31 – 99.98 %), Si (20.92 – 52.07 %), Zn (2.74 – 21.65 %), Pb (10.44 – 100 %), Cd (0.75 – 42.85 %), Fe (7.42 – 98.57 %) and Al (19.14 – 98.69 %) respectively. The mean root and shoot bioconcentration factors (BCFs) of K, Mg, Mn and Al were greater than one indicating higher accumulation of the elements in the root and shoot of the maize plants. The root BCF of the elements was generally in the order: Mn > K > Mg > Cd > S i > Al > P > Fe > Zn > Pb while the shoot BCF was in the order: Mn > K > Mg > Al > Fe > Cd > S i > P > Zn > Pb. The mean root to shoot translocation factors (TF) of P, Mn, Zn, Pb, Cd, Fe and Al were greater than one indicating effective translocation of the elements from the root to shoots. The translocation factors were generally in the order: Fe > Al > Pb > Mn > Zn > P > Cd > Mg > S i > K.

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REFERENCES

H. Garelick, H. Jones, A. Dybowska & E. Valsami-Jones, “Arsenic pollution sources”, In arsenic pollution and remediation: An international perspective; Garelick, H., Jones, H., Eds; Springer; New York, USA, (2009) 17.

M. H. Fulekar, A. Singh, & A. M. Bhaduri, “Genetic engineering strategies for enhancing phytoremediation of heavy metals”, African Journal of Biotechnology; 8 (2009) 529.

A. P. G. C. Marques, A. O. S. S. Rangel, & P. M. L. Castro, “Remediation of heavy metal contaminated soils: phytoremediation as a potentially promising clean-up technology”, Critical Reviews in Environmental Science and Technology; 39 (2009) 622.

L. Lu, S. Tian, X. Yang, X. Wang, P. Brown, & T. Li, “Enhanced root-to- shoot translocation of cadmium in the hyperaccumulating ecotype of Sedum alfredii”, Journal of Experimental Botany;59 (2008) 3203.

D. Deng, J. Deng, J. Li, J. Zhang, M. Hu, & Z. Lin, “Accumulation of zinc, cadmium and lead in four populations of Sedum alfredii growing on lead/zinc mine spoils”, Journal Integrated Plant Biology, 50 (2008) 691.

P. B. A. N. Kumar, V. Dushenkovn, H. Motto, & I. Raskin, “Phytoextraction: the use of plants to remove metals from soils”, Environmental Science and Technology, 29 (1995) 1232.

F. Pedron, M. V. Barbafieri, M, Petruzzelli, G, Rosellini, “Applicability of a Freundlich-like Model for plant uptake at an industrial contaminated site with a high variable arsenic concentration”, Environment, 4 (2017) 67, https://doi.org/10.3390/environments4040067

J. Yoon, X. Cao, Q. Zhou & L.Q. Ma, Accumulation of Pb, Cu, and Zn in native plant growing on a contaminated Florida site”, Science of Total Environment, 368 (2006) 456.

V. Subhashini & A. V. V. S. Swamy, “Phytoremediation of Metal (Pb, Ni, Zn,Cd and Cr) Contaminated Soils Using Canna indica. ”Current World Environment, 9 (2014) 780.

M. I. Arowojolu, S. M. Tongu, A. U. Itodo, F. S. Fernando, A. K. Barnabas, & C. N. Raymond, “Investigation of sources, ecological and health risks of sedimentary polycyclic aromatic hydrocarbons in River Benue, Nigeria”, Environmental Technology and Innovation, 22 (2021) 101457, https://doi.org/10.1016/j.eti.2021.101457

E. A. Yerima, A. U. Itodo, R. Sha’Ato, & R. A. Wuana, “Ecological risk assessment of mineral and heavy metals level of soil around auto mechanic village Wukari, Nigeria”, Academic Journal of Chemistry, 5 (2020) 81.

P. K. Rai, “An eco-sustainable green approach for heavy metals management: two case studies of developing industrial region”, Environmental Monitoring Assessment, 184 (2012) 421.

F. L. Fu, & Q. Wang, “Removal of heavy metal ions from wastewaters”. A review, Journal of Environmental Management, 92 (2011) 407.

X. J. Xue, & H. X. Cheng, “Global Geochemical Mapping and its Implementation in the Asia-Pacific Region”, Applied Geochemistry, 16 (2001) 1309.

E. A. Yerima, E. Ogah, C. V. Ogbodo, H. Ataitiya, & J. D. Ani, “Heavy metal speciation and potential impact of rice milling operation on metals concentration on soils around Kilema rice milling industry Lafia, Nasarawa state, Nigeria”, International Journal of Current Research, 11 (2019) 1243.

A. U. Itodo, R. Sha’Ato, R. A. Wuana, & E. A. Yerima, “Effect of phytoremediation on PAHs levels of agricultural soil around mechanic village Wukari, Nigeria”, Journal of environmental analytical chemistry, 7 (2020) 1, https://doi.org/10.37421/jreac.2020.7.265.

P. Zhuang, Z. H. Ye, C. Y. Lan, Z. W. Xie, & W.S. Hsu, “Chemically assisted phytoextraction of heavy metal contaminated soils using three plant species”, Plant Soil, 276 (2005) 153.

W. Yang, H. Li, T. Zhang, L. Sen, & W. Ni, “Classification and identification of metal accumulating plant species by cluster analysis”, Environmental Science and Pollution Research, 21 (2014) 10626.

W. Zhang, Y. Cai, C. Tu, & L. Q. Ma, “Arsenic speciation and distribution in an arsenic hyperaccumulating plant”, Science of Total Environment, 300 (2002) 167.

Y. Lu, H. Yao, D. Shan, Y. Jiang, S. Zhang, & J. Yang, “Heavy Metal Residues in Soil and Accumulation in Maize at Long-Term Wastewater Irrigation Area in Tongliao, China”, Journal of Chemistry (2015), https://doi.org/10.1155/2015/628280

E. E. Awokunmi, O. S. Adefemi & S. S. Asaolu “Tissues accumulation of heavy metals by maize (Zea mays L.) cultivated on soil collected from selected dumpsites in Ekiti State, Nigeria”, American Chemical Science Journal, 5 (2015) 156.

N. A. Oladejo, B. Anegbe & O. Adeniyi, “Accumulation of heavy metals in soil and maize plant (Zea Mays) in the vicinity of two government approved dumpsites in Benin City, Nigeria”, Asian Journal Chemical Science, 3 (2015) 1.

M.Wahsha, C. Bini, E. Argese, F. Minello, S. Fontana, & H.Wahsheh, “Heavy metals accumulation in willows growing on Spolic Technosols from the abandoned Imperina Valley mine in Italy,” Journal of Geochemical Exploration, 123 (2012) 19.

Phytoremediation and Bioconcentration of Mineral and Heavy metals in Zea mays Inter-planted with Striga hermonthica in Soils from Mechanic Village Wukari

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