ANALYTICAL METHOD VALIDATION OF ICP-AES FOR ANALYSIS OF CADMIUM, CHROMIUM, CUPRUM, MANGAN AND NICKEL IN MILK
DOI:
https://doi.org/10.22159/ijap.2019v11i4.29503Keywords:
Validation, ICP-AES, Heavy metals, Wet digestion, MilkAbstract
Objective: The aim of this research was to validate inductively coupled plasma-atomic emission spectroscopy (ICP-AES) for quantitative analysis of cadmium (Cd), chromium (Cr), cuprum (Cu), mangan (Mn) and nickel (Ni) in milk products.
Methods: The heavy metals in milk were determined using ICP-AES at optimized wavelength. The method was validated by assessing several validation parameters which included linearity and range, accuracy, precision and sensitivity expressed by the limit of detection and limit of quantification. The validated method was then used for the analysis of milks commercially available.
Results: ICP-AES for determination of Cd, Cr, Cu, Mn, and Ni was linear over a certain concentration range with a coefficient correlation value of>0.997. The limit of quantification values of Cd, Cr, Cu, Mn, and Ni were 0.0047; 0.0050; 0.0066; 0.0061; and 0.0169 µg/ml, respectively. The precision of analytical method exhibited relative standard deviation (RSD) values of 3.18%; 4.17%; 3.05%; 2.93%; and 4.47% during repeatability test and 5.28%; 5.06%; 3.67%; 3.67%; and 11.17% during intermediate precision of Cd, Cr, Cu, Mn, and Ni respectively. The recoveries of these metals assessed using standard addition method were 92.25; 90.88; 102.87; 94.50; and 86.85%, respectively.
Conclusion: ICP-AES offered a reliable and fast method for the determination of heavy metals in milk products. The developed method could be proposed as an official method for determination of heavy metals in milk products.
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Suturovic Z, Kravic S, Milanovic S, Ðurovic A, Brezo T. Determination of heavy metals in milk and fermented milk products by potentiometric stripping analysis with the constant inverse current in the analytical step. Food Chem 2014;155:120–5.
Khan N, Jeong IS, Hwang IM, Kim JS, Choi JS, Nho EY, et al. Analysis of minor and trace elements in milk and yogurts by inductively coupled plasma-mass spectrometry (ICP-MS). Food Chem 2014;147:220–4.
Pilarczyk R, Wojcik J, Czerniak P, Sablik P, Pilarczyk B, Tomza Marciniak A. Concentrations of toxic heavy metals and trace elements in raw milk of simmental and holstein-friesian cows from organic farm. Environ Monitor Asses 2013;185:8383–92.
Kazi TG, Jalbani N, Baig JA, Kandhro GA, Afridi HI, Arain MB. Assessment of toxic metals in raw and processed milk samples using electrothermal atomic absorption spectrophotometer. Food Chem Toxicol 2009;47:2163–9.
Zhai Y, Liu Y, Chang X, Chen S, Huang X. Selective solid-phase extraction of trace cadmium (II) with an ionic imprinted polymer prepared from a dual-ligand monomer. Anal Chim Acta 2007;593:123–8.
Sarker KC, Ullaha MR. Determination of trace amount of copper (Cu) using Uv-Vis spectrophotometric method. Int J Sci Res Manag 2013;1:23-44.
Narayana B, Cherian T. Rapid spectrophotometric determination of trace amounts of chromium using variamine blue as a chromogenic reagent. J Braz Chem Soc 2005;16:197-201.
Marbaniang DG. Spectrophotometric determination of manganese in groundwater in shillong city using bismuthate oxidation method. Int J Environ Protec 2012;2:22-6.
Barreto WJ, Barreto SRG, Scarminio IS, Ishikawa DN, de FátimaSoares M, de Proença MVB. Determination of Ni(II) in metal alloys by spectrophotometry uv-vis using dopasemiquinone. Quimica Nova 2010;33:109-13.
Tajkarimi M, Ahmadi Faghih M, Poursoltani H, Salah Nejad A, Motallebi AA, Mahdavi H. Lead residue levels in raw milk from different regions in Iran. Food Control 2008;19:495–8.
Maas S, Lucot E, Gimbert F, Crini N, Badot PM. Trace metals in raw cow´s milk and assessment of transfer to Comte cheese. Food Chem 2011;129:7–12.
Abdulkhaliq A, Swaileh KM, Hussein RM, Matani M. Levels of metals (Cd, Pb, Cu and Fe) in cow’s milk, dairy products and hen’s eggs from the West Bank, Palestine. Int Food Res J 2012;19:1089-94.
Kira CS, Maihara VA. Determination of major and minor elements in dairy products through inductively coupled plasma optical emission spectrometry, after wet partial digestion and neutron activation analysis. Food Chem 2007;100:390–5.
Patricia Cava Montesinos M, Rodenas Torralba E, Morales Rubio A, Luisa Cervera M, de la Guardia M. Cold vapour atomic fluorescence determination of mercury in milk by slurry sampling using multi-commutation. Anal Chimica Acta 2004;506:145–53.
Muñoz E, Palmero S. Determination of heavy metals in milk by potentiometric stripping analysis using a home-made flow cell. Food Control 2004;15:635–41.
Tripathi RM, Raghunath R, Sastry VN, Krishnamoorthy UTM. Daily intake of heavy metals by infants through milk and milk products. Sci Total Environ 1999;227:229–35.
Nogueira Rita de Araujo A, Mockiuti F, Batista de Souza G, Primavesi O. Flow injection spectrophotometric catalytic determination of iodine in milk. Anal Sci 1998;14:559–64.
Suárez Luque S, Mato I, Huidobro JF, Simal Lozano J. Determination of major metal cations in milk by capillary zone electrophoresis. Int Dairy J 2007;17:896–901.
Syroeshkin AV, Pleteneva TV, Uspenskaya UV, Levitskaya OV, Tribot Laspiere MA, Zlatsky IA, et al. Polarimetric research of pharmaceutical substances in aqueous solutions with different water isotopologues ratio. Int J Appl Pharm 2018;10:243-8.
Saeed AM, Hamzah MJ, Ahmed NQ. Quantitative assay of aspirin and (salicylic acid and heavy metals as impurities) in Iraqi’s market aspirin tablets using different analytical methods. Int J Appl Pharm 2018;10:167-72.
Noviana E, Pranowo HD, Astuti A, Rohman A. Validation of mercury analyzer for the determination of mercury in snake fruit. Int Food Res J 2012;18:933-6.
Miller JN, Miller JC. Statistics and chemometrics for analytical chemistry, Prentice Hall, England; 2010.
Gonzalez AG, Herrador MA. A practical guide to analytical method validation, including measurement uncertainty and accuracy profiles. Trends Anal Chem 2007;26:227-38.
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