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Analysis of Copper (II) in Pharmaceutical Products using Micelle form with the Turbidity Method
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A modern and easy procedure performed using the turbidity method for the pre-concentration and estimating of Cu (II) in pharmaceutical samples. The limited solubility complex formed by the reaction of copper ions with cysteine and SDS as the surfactant. The copper content measured using the turbidity method. The effect of chemical and physical parameters including grouping of the ligand, SDS, pH, equilibration temperature and time and effect of salting are studied. The analytical qualities of the technique have been determined, which includes linear range (the range was between 0.158 -47.625μgmL-1), the coefficient of turbidity (k=13.21), limit of detection (LOD=0.1767 μg ml-1nd LOQ=0.5355 μg mL-1).All values are calculated using statistical programs, but the detection limit for Cu(II) ions based on eight times the standard deviation of the blanks (N:8) characterized as 3Sb/m (where Sb is the standard deviation of the blank and m is the slope of the calibration curve) is 0.0096μg mL-1 (3σ). The method employed successfully for the determination of Cu2+ in different local pharmaceutical formations.
Keywords
Copper in Pharmaceutical Products, Turbidity, Micelle.
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- Eric, J., Underwood, 4th Ed., 1977, Trace Elements in Human and Animal Nutrition, academic press New York.
- Linder, M., C., Wooten, L., Cerveza, P., Cotton, S., Shulze, R., Lomeli, N., 1998, Copper transport, The American Journal of Clinical Nutrition, 67 (5): 965S–971S.
- Brewer, G., J., 2012, Copper excess, zinc deficiency, and cognition loss in Alzheimer's disease. Bio. Factors, 38(2), 107–113.
- Rickett, B. I., Payer, J. H., 1995, Composition of Copper Tarnish Products Formed in Moist Air with Trace Levels of Pollutant Gas: Hydrogen Sulfide and Sulfur Dioxide/Hydrogen Sulfide, Journal of the Electrochemical Society, 142 (11), 3723–3728.
- Kay, S., Walther, B., Peter, K., Peter, M., Dieter K., Saran, D., 2000, Cellulose Solutions in Water Containing Metal Complexes, Macromolecules, 33, 4094–4107.
- Yin, K., Li, B., Wang, X., Zhang, W., Chen, L., 2015, Ultrasensitive colorimetric detection of Cu2+ ion based on catalytic oxidation of l-cysteine, Biosensors and Bioelectronics, 64, 81–87.
- Khudhair, A. F., Saeed, S. I., Abbas S. K, Mohsin, H. M., 2017, Strontium (II) Ion Analysis by Using Schiff Base Derivative and Turbidimetric Method, Asian J. Chem., 29 (5), 1065-1068.
- Khudhiar, A. F., Hassan, A. F., 2017, Cloud Point Extraction and Determination Trace Iron (III) in Urine Samples by Spectrophotometry and Flame Atomic Absorption Spectrometry, Asian J. Chem.., 29 (12), 2725-2733.
- Khudhair, A. F., Saeed, S. I., 2016, Quantitative Analysis of Bismuth (III) Ion by Coupling Turbidity Method with Cloud Point Extraction Mode, International Journal of Science and Research, 5(4):218-222.
- Prochazkova S, and Halko, R., 2016, Determination of Copper in Human Urine by Cloud Point Extraction and Flame Atomic Absorption Spectrometry, Analytical letters, 49, (11), 1656–1668.
- Cunha, F.A. S., Ferreira, D. T., Andrade, W. C., Fernandes J. P., Lyra, W. S., Pessoa, A. G., de Arauj, M. C. 2018, Macroemulsion-based dispersive magnetic solid phase extraction for preconcentration and determination of copper(II) in gasoline, Microchimica Acta, 185(2):99, 1-8.
- Gouda, A. A., Amin A. S. 2014, Cloud-point extraction, preconcentration and spectrophotometric determination of trace quantities of copper in food, water and biological samples, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 120, 88–96.
- Paulo, R. O., Alyne C. L., Edivaltrys I. P., Antonio S. M., Luiz H. M., Márcio F.B., 2015, Electrochemical determination of copper ions in spirit drinks using carbon paste electrode modified with biochar, Food Chemistry, 171(15), 426-431.
- Inês C.S., Raquel B.R., António O.S., 2015, Micro solid phase spectrophotometry in a sequential injection lab-on-valve platform for cadmium, zinc, and copper determination in freshwaters, Analytica Chimica Acta, 891( 3), 171-178.
- Cennet K. Derya K., Ganesh S., Kamble Sanjay S., Kolekar Mansing A. A., 2011, Synergistic extraction and spectrophotometric determination of copper(II) using 1-(2′, 4′-dinitro aminophenyl)-4, 4, 6-trimethyl-1, 4-dihydropyrimidine-2-thiol: Analysis of alloys, pharmaceuticals and biological samples, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 78 ( 5), 1455-1466.
- Kocharekar, A. R. Thakkar, N.V., 2004, Extractive spectrophotometric determination of copper(II) and its applications in pharmaceutical samples and alloys, Journal of Scientific and Industrial Research (JSIR), 63(3), 283-286.
- Cennet, K., Derya, K., 2017, Dispersive liquid–liquid microextraction based on solidification of floating organic drop for preconcentration and determination of trace amounts of copper by flame atomic absorption spectrometry, Food Chemistry, 220, 242-248.
- Yunus E., U., , Mustafa S., Mustafa T., Baki H., 2015, Determination of Lead, Copper, and Iron in Cosmetics, Water, Soil, and Food Using Polyhydroxybutyrate-B-polydimethyl Siloxane Preconcentration and Flame Atomic Absorption Spectrometry, Analytical Letters, 48(7), 1163-1179.
- Coast O. M., Ahlam H., Rim H., 2017, Analyze Study of Water in Emergency Departments at General Hospitals of the Syrian, Research J. Pharm. and Tech., 10(1), 1-4.
- Ram, P., Neelam S., Tyagi, D.K. and Yadav, O.P., 2012, Surface and Thermodynamic Properties of Cetyl Pyridinium Chloride (CPC) in Aqueous Sodium Chloride Solutions at Various Temperatures, Asian J. Research Chem., 5(1)3-37.
- Farhat H. K. and Mahboob A., 2011, Kinetics and Mechanism of Micelle-Catalysed Oxidation of DL-Alanine and Glycine by Chloromine-T, Asian J. Research Chem., 4(3), 468-480.
- Raghunathan M., Vashantha. R., 2018, Spectrophotometric Determination of Trace Amounts of Cu (II) in Water Samples after Micelle-Mediated Extraction, Asian J. Research Chem., 11(2), 355-359.
- Shuchi G., Seema A., 2018, Spectrofluorimetric Analysis of Interaction of Benzo(a) Pyrene and Surfactant Micelles, Asian J. Research Chem., 11(3), 355-359.
- T. Vinod Kumar, A. Rajeshwar R., Badhe S. and C. Rajeshwari, 2015, Assessment of Physico – Chemical Parameters of Priyadarshini Jurala Project Waters in Mahabubnagar District, Telangana State, India, Asian J. Research Chem., 8(8), 521-524.
- Roopa R., A. Chakradhar1, K.C. Rajanna, P. K. Saiprakash, Ramchander M., 2018, Cetyltrimethylammonium bromide promoted Selective Bromination of Aromatic Compounds in presence of Zirconyl Nitrate and Ammonium Molybdate under solvent –free conditions, Asian J. Research Chem.11(1), 51-54.
- Bhaskar K., Sandesh S., Nilesh J., 2014, Micellar Drug Delivery System, Research Journal of Pharmaceutical Dosage Forms and Technology. 6(4), 267-281.
- S.K. Jain, R Chandra and A. K. Rai, 2008, Characterization of Ocular Delivery of Reverse Micelles Bearing Insulin, Research J. Pharm. and Tech., 1(4), 370-373.
- Soumya K., Amit A., Nisha A, 2014, Biomedical Applications of Nanobiotechnology for Drug Design, Delivery and Diagnostics, Research J. Pharm. and Tech., 7(8).915-925.
- N. V. Kumar, Prathiba S., S. Prabhu, 2013, Nanoparticle-Mediated Drug Delivery Systems S. Viswanathan, Research J. Engineering and Tech.4(4), 295-299.
- Buckee, G.K., Morris T.M., Bailey, P., 1986, Calibration and evaluation of hazemeters, J. Inst. Brew., 92, 475 – 482.
- Ahmed, M., Iqbal, M. S., Tahir, N., Islam A., .2011, solvent free synthesis of copper (II) cysteine, World Applied Sciences Journal, 14 (2) 210 -214.
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