Kinetic and mechanistic study of ciprofloxacin in aqueous alkaline medium

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Kinetic and mechanistic study of ciprofloxacin in aqueous alkaline medium

Author Affiliations

¹Department of Chemistry, Janki Devi Bajaj Government Girls College, Kota-324001, Rajasthan, India
²Department of Chemistry, Janki Devi Bajaj Government Girls College, Kota-324001, Rajasthan, India
³Department of Chemistry, Janki Devi Bajaj Government Girls College, Kota-324001, Rajasthan, India

Res. J. Recent Sci., Volume 7, Issue (4), Pages 6-12, April,2 (2018)

Abstract

The existence of fluoroquinolone drugs in environment, may harmful to the human health. Hence the present study aimed to oxidative degradation of antibacterial drug ciprofloxacin by hexacyanoferrate(III) (HCF) in aqueous alkali medium at 40&

References

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Google Scholar
Dasgupta G. and Mahanti K. (1986)., Kinetics of oxidation of anilines by alkaline hexacyanoferrate (III)., Oxidation of N- alkyl side chains, Fr. Bull. Soc. Chim., 4, 492-496.
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Google Scholar
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Google Scholar
Speakman P.T. and Waters W.A. (1955)., Kinetic features of the oxidation of aldehydes, ketones and nitroparaffins with alkaline ferricyanide., Journal of the Chemical Society (Resumed), 40-45.
Google Scholar
Singh V.N., Gangwar M.C., Saxena B.B.L. and Singh M.P. (1969)., Kinetics and mechanism of the oxidation of formaldehyde by hexacyanoferrate (III) ion., Canadian Journal of Chemistry, 47(6), 1051-1056.
Google Scholar
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Google Scholar
Nath N. and Singh L.P. (1985)., Kinetics and mechanism of ruthenium(III)-catalyzed oxidation of benzylamine by hexacyanoferrate (III) in alkaline medium., J. Indian Chem. Soc., 62(2), 108-111.
Google Scholar
Wang P., He Y.L. and Huang C.H. (2010)., Oxidation of fluoroquinolone antibiotics and structurally related amines by chlorine dioxide: reaction kinetics, product and pathway evaluation., water research, 44(20), 5989-5998.
Google Scholar
Guinea E., Brillas E., Centellas F., Ca�izares P., Rodrigo M.A. and S�ez C. (2009)., Oxidation of enrofloxacin with conductive-diamond electrochemical oxidation, ozonation and Fenton oxidation. A comparison., Water research, 43(8), 2131-2138.
Google Scholar
Dodd M.C., Shah A.D., von Gunten U. and Huang C.H. (2005)., Interactions of fluoroquinolone antibacterial agents with aqueous chlorine: reaction kinetics, mechanisms and transformation pathways., Environmental Science & Technology, 39(18), 7065-7076.
Google Scholar
Jain A., Jain S. and Devra V. (2015)., Kinetics and mechanism of permanganate oxidation of Ciprofloxacin in aqueous sulphuric acid medium., Int J Pharm Sci Drug Res, 7(2), 205-10.
Google Scholar
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Google Scholar
Nowduri A., Duggada A.B. and Kurimella V.R. (2014)., Kinetics and mechanism of oxidation of labetalol by hexacyanoferrate (III) in alkaline medium., Int.J. of Scientific Research., 3(2), 131-133.
Google Scholar
Patgar M.B., Nandibewoor S.T. and Chimatadar S.A. (2015)., Spectroscopic investigation of the oxidation of levofloxacin by hexacyanoferrate (III) in aqueous alkaline medium- A Kinetic and Mechanistic approach., Cogent Chemistry, 1(1), 1-14.
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Jagdeesh R.V. and Puttuswammy (2008)., Ru(III), Os(VIII), Pd(II) and Pt(IV) catalyzed oxidation of glycyl-glycine by sodium-N-chloro-p-toulenesulfonamide: Comparative mechanistic aspects and kinetic modelling., J. Phys. Org. Chem., 21(10), 844-858.
Google Scholar

[ref1] Zhang H. and Haung C.H. (2005)., Oxidative Transformation of Fluoroquinolone Antibacterial Agents and Structurally Related Amines by Manganese Oxide., Environ. Sci. Technol, 39(12), 4474-4483.
Google Scholar

[ref2] Dasgupta G. and Mahanti K. (1986)., Kinetics of oxidation of anilines by alkaline hexacyanoferrate (III)., Oxidation of N- alkyl side chains, Fr. Bull. Soc. Chim., 4, 492-496.
Google Scholar

[ref3] Farokhi S.A., Nandibewoor S.T. (2003)., Kinetic, mechanistic and spectral studies for the oxidation of sulfanilic acid by alkaline hexacyanoferrate (III)., Tetrahedrone, 59(38), 7595-7602.
Google Scholar

[ref4] Nowduri A., Adari K.K., Gollapalli N.R. and Parvataneni V. (2009)., Kinetics and mechanism of oxidation of l-cystine by hexacyanoferrate (III) in alkaline medium., Journal of Chemistry, 6(1), 93-98.
Google Scholar

[ref5] Kelson E.P. and Phengsy P.P. (2000)., Kinetic study of 2‐propanol and benzyl alcohol oxidation by alkaline hexacyanoferrate (III) catalyzed by a terpyridyl ruthenium complex., International Journal of Chemical Kinetics, 32(12), 760-770.
Google Scholar

[ref6] Vovk A.I., Murav, Kinetics of oxidation of vitamin B-1 and its O-acyl analogs with ferricyanide. A mechanistic model of thiamin-binding protein., Russian Journal of General Chemistry, 70(7), 1108-1112.
Google Scholar

[ref7] Speakman P.T. and Waters W.A. (1955)., Kinetic features of the oxidation of aldehydes, ketones and nitroparaffins with alkaline ferricyanide., Journal of the Chemical Society (Resumed), 40-45.
Google Scholar

[ref8] Singh V.N., Gangwar M.C., Saxena B.B.L. and Singh M.P. (1969)., Kinetics and mechanism of the oxidation of formaldehyde by hexacyanoferrate (III) ion., Canadian Journal of Chemistry, 47(6), 1051-1056.
Google Scholar

[ref9] Al-Subu M.M. (1992)., Kinetics and mechanism of oxidation of diallylamine by alkaline hexacyanoferrate (III)., An-Najah University Journal for Research, 7, 37-44.
Google Scholar

[ref10] Nath N. and Singh L.P. (1985)., Kinetics and mechanism of ruthenium(III)-catalyzed oxidation of benzylamine by hexacyanoferrate (III) in alkaline medium., J. Indian Chem. Soc., 62(2), 108-111.
Google Scholar

[ref11] Wang P., He Y.L. and Huang C.H. (2010)., Oxidation of fluoroquinolone antibiotics and structurally related amines by chlorine dioxide: reaction kinetics, product and pathway evaluation., water research, 44(20), 5989-5998.
Google Scholar

[ref12] Guinea E., Brillas E., Centellas F., Ca�izares P., Rodrigo M.A. and S�ez C. (2009)., Oxidation of enrofloxacin with conductive-diamond electrochemical oxidation, ozonation and Fenton oxidation. A comparison., Water research, 43(8), 2131-2138.
Google Scholar

[ref13] Dodd M.C., Shah A.D., von Gunten U. and Huang C.H. (2005)., Interactions of fluoroquinolone antibacterial agents with aqueous chlorine: reaction kinetics, mechanisms and transformation pathways., Environmental Science & Technology, 39(18), 7065-7076.
Google Scholar

[ref14] Jain A., Jain S. and Devra V. (2015)., Kinetics and mechanism of permanganate oxidation of Ciprofloxacin in aqueous sulphuric acid medium., Int J Pharm Sci Drug Res, 7(2), 205-10.
Google Scholar

[ref15] Jeffrey G.H., Bassett J., Denny R.C. and Mendham J. (1996)., Vogel's text book of quantitative chemical analysis., 5th edn. ELBS, Longman, Essex, 339.
Google Scholar

[ref16] Nowduri A., Duggada A.B. and Kurimella V.R. (2014)., Kinetics and mechanism of oxidation of labetalol by hexacyanoferrate (III) in alkaline medium., Int.J. of Scientific Research., 3(2), 131-133.
Google Scholar

[ref17] Patgar M.B., Nandibewoor S.T. and Chimatadar S.A. (2015)., Spectroscopic investigation of the oxidation of levofloxacin by hexacyanoferrate (III) in aqueous alkaline medium- A Kinetic and Mechanistic approach., Cogent Chemistry, 1(1), 1-14.
Google Scholar

[ref18] Jagdeesh R.V. and Puttuswammy (2008)., Ru(III), Os(VIII), Pd(II) and Pt(IV) catalyzed oxidation of glycyl-glycine by sodium-N-chloro-p-toulenesulfonamide: Comparative mechanistic aspects and kinetic modelling., J. Phys. Org. Chem., 21(10), 844-858.
Google Scholar