光谱学与光谱分析 |
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Examination of Correlation between Histidine and Cadmium Absorption by Eleagnus angustifolia L., Vitisvinifera L. and Nerium oleander L. Using HPLC-MS and ICP-MS |
Sukran Akkus Ozen, Mehmet Yaman* |
Firat University, Faculty of Science, Department of Chemistry, Elazig, Turkey |
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Abstract In this study, HPLC-MS and ICP-MS methods wereused for the determination of histidine and cadmiumin Eleagnusangustifolia L., Vitisvinifera L. and Nerium oleander L. leaves taken from industrial area including Gaziantep and Bursa cities. To histidine determination by HPLC-MS, flow rate of mobile phase, fragmentor potential, injection volume and column temperature were optimized as 0.2 mL·min-1, 70 V, 15 μL and 20 ℃, respectively. For extraction of histidine from plants, distilled water was used by applying on 90 ℃ and 30 min. The concentrations (as mg·kg-1) of histidine were found to be in range of 8~22 for Eleagnusangustifolia L., 10~33 for Vitisvinifera L. and 6~11 for Nerium oleander L. The concentrations of cadmium were found to be in ranges of 6~21 μg·kg-1 for Vitisvinifera L. 15~110 μg·kg-1 for Eleagnusangustifolia L. and 63~218 μg·kg-1 for Nerium oleander L.
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Received: 2015-08-20
Accepted: 2015-10-09
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Corresponding Authors:
Mehmet Yaman
E-mail: ijpacmy@gmail.com; myaman@firat.edu.tr
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[1] Mertz W. Academic Press, Newyok. Fifth Ed, 1987. [2] Yaman M. Current Medical Chem., 2006, 13(21): 2513. [3] Rani A, Kumar A, Lal A, et al. International Journal of Environmental Health Research, 2014, 24(4): 378. [4] Huff,et al. Int. J. Occup. Environ. Health., 2007, 13(2): 202. [5] Mulligan C N,et al. Engineering Geology, 2001, 60: 193. [6] Gunawardana B,et al. Plant Soil, 2010, 329: 283. [7] Pilon-Smils E, Pilau M. Critical Reviews in Plant Sciences, 2002, 21: 439. [8] Shah K, Nongkynrih J M. Biologia Plantarum, 2007, 51(4): 618. [9] Krmer U, Chardonnens A N. Appl. Microbiol. Biotechnol.,2001, 55: 661. [10] Haydon M J, Cobbett C S. New Phytol., 2007, 174(3): 499. [11] Callahan D L, Baker A J M, Kolev S D, et al. Journal of Biological Inorganic Chemistry, 2006, 11: 2. [12] Ugulu I. Applied Spectroscopy Reviews, 2015, 50: 113. [13] Hall J L. Journal of Experimental Botany, 2002, 366: 1. [14] Krmer U, et al. Nature, 1996, 379: 635. [15] Kaya G, Okumus N, Yaman M. Fresenius Environ. Bull., 2010, 19(4):669. [16] Kaya G, Yaman M. Trace Elements and Electrolytes, 2008, 25(3): 156. [17] Kaya G, Yaman M. Talanta, 2008, 75: 1127. [18] Kaya G, Ozcan C, Yaman M. Bull. Environ. Contam Toxicol, 2010, 84(2): 191. [19] Kaya G, Yaman M. Spectrosc. Spectral Anal., 2012, 32(1): 229. [20] Kaya G, Yaman M. Instrumentation Science & Technology, 2012, 40(1): 61. [21] Kabata-Pendias A. Trace Elements in Soils and Plants, Fourth Edition, Taylor and Francis Group, 2011. [22] Dong J, Mao W H, Zhang G P,et al. Plant Soil and Environment, 2007, 53(5): 193. [23] Bargagli R. Plants as Biomonitors, in: Trace Elements in Terrestrial Plants: an Ecophysiological Approach to Biomonitoring and Biorecovery. Springer, Berlin Heideberg New York, 1998. [24] Mulgrew A, Willeams P. Biomononitoring of Air Quality Using Plants, Air Hygiene Report no:10 Berlin, Germany WHO CC. 165, 2000. [25] Mertens J, et al. Environmental Pollution, 2005, 138: 1. [26] Clemens S, Palmgren M G, Kramer U. Trends Plant Sci., 2002, 7: 309. [27] Onianwa P C, Fakayode S O. Environmental Geochemistry and Health, 2000, 22: 211. [28] Boyd R S. J. Chem. Ecol., 2010, 36(1): 46. [29] Yaman M, Kaya G, Yekeler H. World J. Gastroentor., 2007, 13(4): 612. [30] Er C, Senkal B F, Yaman M. Food Chem., 2013, 137(1-4): 55. [31] Ozen O A, Songur A, Sarsilmaz M, et al. Trace Elem. Med. Biol., 2003, 17(3): 207. [32] Yaman M, Cokol N. At. Spectrosc., 2004, 25(4): 185. [33] Yaman M, Bakirdere S. Mikrochim. Acta, 2003, 141: 47. |
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