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Anal. Method Environ. Chem. J. 3 (4) (2020) 17-29
6. References
[1] S. Morais, F.G. Costa, M.L. Pereira, Heavy
metals and human health, Intech publisher,
pp. 227–246, 2012.
[2] K. Rehman, F. Fatima, I. Waheed, Prevalence
of exposure of heavy metals and their impact
on health consequences, J. Cell. Biochem., 119
(2018) 157–184.
[3] F. Zhushan, X. Shuhua, The effects of heavy
metals on human metabolism, Toxicol. Mech.
Meth., 30 (2020) 167–176.
[4] W. Liu, J.P. Tian, L.J. Chen, Y. Guo, Temporal
and spatial characteristics of lead emissions
from the leadacid battery manufacturing
industry in China, Environ. Pollut., 220 (2017)
696–703.
[5] P.V. Bossche, F. Vergels, J.V. Mierlo, J.
Matheys, W.V. Autenboer, An assessment
of sustainable battery technology, J. Power
Sources, 162 (2006) 913–919.
[6] A.l.Wani,A.Ara,J.A.Usmani,Leadtoxicity:
A review, Int. Toxicol., 8 (2015) 55–64.
[7] J.w.Lee,H.Choi,U.K.Hwank,J.C.Kang,Y.J.
Kang, K.I. Kim, J.H. Kim,. Toxic effects of
lead exposure on bioaccumulation, oxidative
stress, neurotoxicity, and immune responses in
sh:A review, Environ.Toxicol. Pharmacol.,
68 (2019) 101–108. [
[8] Lead toxicity, what Is the biological fate of lead
in the body, environmental health and medicine
education, Agency for toxic substances and
disease registry (ATSDR), 2017. https://www.
atsdr.cdc.gov/csem/csem.aspcsem=34&po=9
[9] M. Giel-Pietraszuk, K. Hybza, M.
Chełchowska, J. Barciszewski, Mechanisms
of lead toxicity, Adv. Cell Biol., 39 (2012) 17–
248.
[10] M. Irberger, J.J. Yang, Structural differences
between Pb
2+
- and Ca
2+
-binding sites in
proteins: implications with respect to toxicity,
J. Inorg. Biochem., 102 (2008) 1901–1909.
[11] Elemental impurities guidance for industry,
department of health and human services, food
and drug administration (FDA), 2017.
[12] Atlanta centers for disease control (ACDC),
USdepartmentofhealthandhumanservices,
national institute for occupational safety
and health (NIOSH), Adult blood lead
epidemiology and surveillance (ABLES),
2017.
[13] R.A. Zounr, M. Tuzen, M.Y. Khuhawar, A
simple and green deep eutectic solvent based
air assisted liquid phase microextraction for
separation, preconcentration and determination
of lead in water and food samples by graphite
furnace atomic absorption spectrometry, J.
Mol. Liq., 259 (2018) 220–226.
14] J.S. Mandlate, B.M. Soares, T.S. Seeger, P.D.
Vecchia, P.A. Mello, E.M.M. Flores, F.A.
Duarte, Determination of cadmium and lead
at sub-ppt level in soft drinks: An efcient
combination between dispersive liquid-liquid
microextraction and graphite furnace atomic
absorption spectrometry, Food Chem., 221
(2017) 907–912
[15] M.A. Habila, Z.A. AlOthman, M. Soylak,
Fe3O4nanoparticles and ultrasound assisted
dispersive liquid-liquid microextraction of
lead(ii) for its microsampling ame atomic
absorption spectrometric determination in
food and environmental samples, RSC Adv., 4
(2014) 55610–55614.
[16] M.A. Habila, Z.A. ALOthman, A.M. El-
Toni, J.P. Labis, X. Li, F. Zhang, M. Soylak,
Mercaptobenzothiazole-functionalized
magnetic carbon nanospheres of type Fe
3
O
4
@
SiO
2
@C for the preconcentration of nickel,
copper and lead prior to their determination by
ICP-MS, Microchim. Acta, 183 (2016) 2377–
2384.
[17] M. García, M. Ángel Aguirre, A
multinebulization technique for the
determination of trace metals in a marine biota
sample by on-line isotope dilution inductively
coupled plasma mass spectrometry (OID-ICP-
MS), J. Anal. At. Spectrom., 35 (2020) 2509-
2516.
[18] Y. Yamini, M. Rezazadeh, S. Seidi, Liquid-
phase microextraction–The different principles
andcongurations,TrendsAnalytChem.,112
(2019) 264–272.
[19] S.Z. Mohammadi, T. Shamspur, Y.M.
Baghelani, Combination of ame atomic
absorption spectrometry with ligandless-
dispersive liquid-liquid microextraction for
preconcentration and determination of trace