Microdetermination of Piroxicam in Pharmaceutical Formulations by Complexation with Fe(III) and Image Scanning Densitometry
Year 2024,
Volume: 11 Issue: 3, 1245 - 1254, 30.08.2024
Jamıl Anwar
,
Amara Dar
,
Ramna Mumtaz
,
Jesús Anzano
,
Ayesha Mohyuddin
Abstract
Piroxicam is a nonsteroidal anti-inflammatory drug (NSAID) that is used to relieve pain or inflammation due to osteoarthritis or rheumatoid arthritis. Assay of piroxicam in pharmaceutical formulations can be performed by using a number of analytical techniques. This work estimates the drug in commercial samples using a novel method, Computational Image Scanning Densitometry (CISD). Micro-volumes of the aqueous solution of piroxicam were reacted with iron(III) sulfate solution under optimum conditions on a white Teflon well plate to form a pink-colored mononuclear complex. By using a smartphone, the picture of the colored complex in the well plate was taken and transferred to an attached computer. The overall optical density resulting from red, green, and blue (RGB) components from a specific area of the colored image was measured and digitalized with the help of custom-made software. A standard curve was prepared by plotting optical density against piroxicam concentration. The method was simple, fast, adequately precise, and accurate for the assay of the drug in commercial samples. The validity of the new method was checked by comparing the results with those obtained by a standard spectrophotometric method of Piroxicam estimation.
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Year 2024,
Volume: 11 Issue: 3, 1245 - 1254, 30.08.2024
Jamıl Anwar
,
Amara Dar
,
Ramna Mumtaz
,
Jesús Anzano
,
Ayesha Mohyuddin
References
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- 2. Shojaee SA, Rajaei H, Hezave AZ, Lashkarbolooki M, Esmaeilzadeh F. Experimental measurement and correlation for solubility of piroxicam (a non-steroidal anti-inflammatory drugs (NSAIDs)) in supercritical carbon dioxide. J Supercrit Fluids [Internet]. 2013 Aug 1;80:38–43. Available from: <URL>.
- 3. Wiseman EH, Cchang YH, Lombardino JG. Piroxicam, a novel anti-inflammatory agent. Chem Informationsd [Internet]. 1976 Oct 12;7(41):1300–3. Available from: <URL>.
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- 5. Laake K, Kjeldaas L, Borchgrevink CF. Side‐effects of piroxicam (Feldene®). Acta Med Scand [Internet]. 1984 Jan 12;215(1):81–3. Available from: <URL>.
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- 11. Abed RI, Hadi H. Direct determination of piroxicam in pharmaceutical forms using flow injection- spectrophotometry. Bull Chem Soc Ethiop [Internet]. 2020 Apr 24;34(1):13–23. Available from: <URL>.
- 12. Ghobadpour G, Farjami F, Fasihi F. Sensitive electrochemical monitoring of Piroxicam in pharmaceuticals using carbon ionic liquid electrode. Curr Pharm Anal [Internet]. 2018 Nov 28;15(1):45–50. Available from: <URL>.
- 13. Rajendraprasad N, Basavaiah K. Potentiometric determination of piroxicam and oxfendazole in pharmaceuticals. Curr Chem Lett [Internet]. 2016;5(1):33–46. Available from: <URL>.
- 14. Singh S, Patel JR, Kare S. Estimation of Piroxicam in tablet dosage form by using UV-Vis. spectrophotometer. Asian J Res Chem [Internet]. 2016;9(2):82–4. Available from: <URL>.
- 15. Kormosh ZA, Hunka IP, Bazel YR. Spectrophotometric determination of piroxicam. J Anal Chem [Internet]. 2011 Apr 9;66(4):378–83. Available from: <URL>.
- 16. El‐Didamony AM, Amin AS. Adaptation of a color reaction for spectrophotometric determination of Diclofenac Sodium and Piroxicam in pure form and in pharmaceutical formulations. Anal Lett [Internet]. 2004 Dec 28;37(6):1151–62. Available from: <URL>.
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- 18. Amin AS. Spectrophotometric determination of piroxicam and tenoxicam in pharmaceutical formulations using alizarin. J Pharm Biomed Anal [Internet]. 2002 Jul 20;29(4):729–36. Available from: <URL>.
- 19. Gowda BG, Seetharamappa J, Melwanki MB. Indirect spectrophotometric determination of Propranolol Hydrochloride and Piroxicam in pure and pharmaceutical formulations. Anal Sci [Internet]. 2002 Jun 19;18(6):671–4. Available from: <URL>.
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- 21. Paciornik S, Yallouz A V., Campos RC, Gannerman D. Scanner image analysis in the quantification of mercury using spot-tests. J Braz Chem Soc [Internet]. 2006 Feb;17(1):156–61. Available from: <URL>.
- 22. da Silva RS, Borges EM. Quantitative analysis using a flatbed scanner: Aspirin quantification in pharmaceutical tablets. J Chem Educ [Internet]. 2019 Jul 9;96(7):1519–26. Available from: <URL>.
- 23. Islam MN, Ahmed I, Anik MI, Ferdous MS, Khan MS. Developing paper based diagnostic technique to detect uric acid in urine. Front Chem [Internet]. 2018 Oct 17;6:496. Available from: <URL>.
- 24. Inderdeep Verma AS, Khushi Upadhyay M. Turbidity detection using image processing. Int J Eng Sci Emerg Technol [Internet]. 2021;10(6):154–60. Available from: <URL>.
- 25. da Silva Lyra W, Castriani Sanches FA, Antônio da Silva Cunha F, Gonçalves Dias Diniz PH, Lemos SG, Cirino da Silva E, et al. Indirect determination of sodium diclofenac, sodium dipyrone and calcium gluconate in injection drugs using digital image-based (webcam) flame emission spectrometric method. Anal Methods [Internet]. 2011;3(9):1975–80. Available from: <URL>.
- 26. Uz-Zaman W, Rehman R, Zafar J. A novel approach to analyze total amino acids contents of food samples by computational image scanning densitometry. Bulg Chem Commun [Internet]. 2019;51(3):332–6. Available from: <URL>.
- 27. Anwar J, Waheed-uz-Zaman, Shafique MU, Salman M. Computational Quantification of Spot Tests by Image Scanning-A New Analytical Technique for Micro Samples. Anal Lett [Internet]. 2010 Jan 12;43(2):367–71. Available from: <URL>.
- 28. Uz-Zaman W, Anwar J, Rehman R, Iqbal T. Determination of iodide, iodate, dichromate, bismuth(III) and hydrogen peroxide through spot tests quantification by computational image scanning densitometry. Asian J Chem [Internet]. 2015;27(1):195–8. Available from: <URL>.
- 29. Shafique U, Anwar J, Salman M, Waheed-uz-Zaman, Dar A, Rehman R, et al. Novel methods to determine sulfide in aqueous samples by quantification of lead sulfide spots. J Sulfur Chem [Internet]. 2011 Apr;32(2):151–7. Available from: <URL>.
- 30. Dar A, Shafique U, Anwar J, Waheed-uz-Zaman, Naseer A. A simple spot test quantification method to determine formaldehyde in aqueous samples. J Saudi Chem Soc [Internet]. 2016 Sep;20:S352–6. Available from: <URL>.
- 31. Salman M, Rehman R, Uz-Zaman W, Anwar J, Airam S, Rehman K. Microanalysis of mercury in fish and root vegetable samples by image scanning densitometry using computationally quantified spot tests. Electron J Environ Agric Food Chem [Internet]. 2012;11(4):279–85. Available from: <URL>.
- 32. Salman M, Athar M, Waheed-uz-Zaman, Shafique U, Anwar J, Rehman R, et al. Micro-determination of arsenic in aqueous samples by image scanning and computational quantification. Anal Methods [Internet]. 2012;4(1):242–6. Available from: <URL>.
- 33. Salman M, Shafique U, Zaman W uz, Rehman R, Yousaf A, Azhar F, et al. A rapid method for measurement of nickel and chromium at trace level in aqueous samples. J Mex Chem Soc [Internet]. 2011;55(4):214–7. Available from: <URL>.