Molecular Interaction between CTAB with NSAIDs (IBFN) by using Tensiometry, Viscometry, FTIR, and 1H NMR Techniques
Keywords:
Nonsteroidal anti-inflammatory [IBFN], CMC, surfactant, FTIR, and 1H NMR.
Abstract
Cetyltrimethylammonium bromide (CTAB), a cationic surfactant, has been interacted with Ibuprofen drug characterized by 1HNMR and FTIR spectroscopictechniques in the solid state. The surface tension method was used to calculate the values of the critical micelle concentration (CMC). Viscosity properties of the mixed system are followed by viscosity techniques. Interaction between anionic surfactants and drugs. These artificially produced surfactants are effective in raising the solubility and bioavailability of drug molecules. Additional screening was done on surfactants to check for antibacterial and antifungal properties. Parameters of the interface, like the maximum concentration of surface excess (Γmax), A molecule's smallest area (Amin), π cmc, and the adsorption efficiency (pC20), were determined.
References
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2. Earle M. J., Esperança J. M. S. S., Gilea M. A., Canongia Lopes J. N., Rebelo L. P. N., & Magee J. W. (2006). The distillation and volatility of ionic liquids. Nature, 439(7078), 831-834.
3. Ventura S. P. M., de Oliveira L. S., da Ponte M. N., Santos L. M. N. B. F., Gonçalves F., &Coutinho J. A. P. (2013). Measuring the salting‐out effect in ionic liquid–organic solvent mixtures. AIChE Journal, 59(2), 402-410.
4. Freire M. G., Neves C. M. S. S., Carvalho P. J., Gardas R. L., Fernandes A. M., Marrucho I. M., & Santos L. M. N. B. F. (2007). Mutual solubilities of water and hydrophobic ionic liquids. The Journal of Physical Chemistry B, 111(44), 13082-13089.
5. Li Y., Tu S. T., He H., Ma Z., & Liu J. (2014). Carbon dioxide capture using a CO2-philic ionic liquid in an organic solvent. Separation and Purification Technology, 125, 73-77.
6. Chhetri A. B., Verma M., &Lankey R. L. (2012). A novel process for making biodiesel from the microalga Schizochytriumlimacinum by using ionic liquids. Energy & Fuels, 26(5), 2775-2783.
7. Kroon M. C., Kurnia K. A., & Hunt P. A. (2014). Industrial physical property data of 35 protic ionic liquids containing the trifluoroacetate anion. Fluid Phase Equilibria, 375, 215-222.
8. Chen L. J., & Dong D. J. (2012). Thermophysical properties of [C4mim] [BF4] + PEG400 solutions. Fluid Phase Equilibria, 333, 109-116.
9. Loftsson T., & Brewster M. E. (2010). Pharmaceutical applications of cyclodextrins. 1. Drug solubilization and stabilization. Journal of Pharmaceutical Sciences, 85(10), 1017-1025.
10. Banjare M.K., Kurrey R., Yadav T., Sinha S., Satnami M.L., & Ghosh K.K. (2017). A comparative study on the effect of imidazolium-based ionic liquid on self-aggregation of cationic, anionic, and nonionic surfactants studied by surface tension, conductivity, fluorescence, and FTIR spectroscopy. Journal of Molecular Liquids, 241, 622-632.
11. More U., Kumari P., Vaid Z., Behera K., &Malek N.I. (2015). Interaction between ionic liquids and gemini surfactants: A detailed investigation into the role of ionic liquids in modifying properties of aqueous gemini surfactants. Journal of Surfactants and Detergents, 18, 743-752.
12. Siddiquee M.A., Saraswat J., ParrayM.D., Singh P., Bargujar S., & Patel,R. (2023). Spectroscopic and DFT study of imidazolium-based ionic liquids with the broad-spectrum antibacterial drug levofloxacin. SpectrochimicaActa. Part A, 285, 121803.
13. Shekaari H., Golmohammadi B., Faraji S., Mokhtarpour M., Sadrmousavi A., Gharouni S., &Zafarani-Moattar M.T. (2021). Thermodynamic and computational study of paracetamol in aqueous solutions of some sustainable amino acid-based ionic liquids. The Journal of Chemical Thermodynamics, 106348.
14. Kumar A., Banjare M.K., Sinha S., Yadav T., Sahu R., Satnami M.L., & Ghosh K.K. (2018). Imidazolium-Based Ionic Liquid as a Modulator of Physicochemical Properties of Cationic, Anionic, Nonionic, and Gemini Surfactants. Journal of Surfactants and Detergents, 21, 355–366.
15. Sinha S., Tikariha D., Lakra J., Yadav T., Kumari S., Saha S.K., & Ghosh K.K. (2016). Interaction of bovine serum albumin with cationic monomeric and dimeric surfactants: A comparative study. Journal of Molecular Liquids, 218, 421-428.
16. Bhatt D., Maheria K., Parikh J. (2014). Mixed system of ionic liquid and non-ionic surfactants in aqueous media: Surface and thermodynamic properties. Journal of Chemical Thermodynamics, 74, 184-192.
17. Wang S., Yin T., &Shen W. (2014). Comparative Investigations on Mixing Behaviors of Cationic Gemini Surfactant with Surface-Active Ionic Liquid in Water and in Ethylammonium Nitrate. Industrial & Engineering Chemistry Research, 53(47), 18202–18208.
18. Qin L., & Wang X.H. (2017). Surface adsorption and thermodynamic properties of a mixed system of ionic liquid surfactants with cetyltrimethyl ammonium bromide. RSC Advances, 7, 51426-51435.
19. Shekaari H., Golmohammadi B., Faraji S., Mokhtarpour M., Sadrmousavi A., Fattah S. G., Zafarani-Moattar M. T. (2020). Thermodynamic and computational study of paracetamol in aqueous solutions of some sustainable amino acid-based ionic liquids.Journal of Chemical Thermodynamics 106348.
20. Gehlot P., Kulshrestha A., Bharmoria P., Damarla,K., Chokshi K., & Kumar A. (2017). Surface-active ionic liquid choliniumdodecylbenzenesulfonate: self-assembling behavior and interaction with cellulase. ACS Omega, 2(10), 7451–7460.
21. Alwadani, N., &Fatehi, P. (2018). Synthetic and lignin-based surfactants: Challenges and opportunities. Carbon Resources Conversion. 1(2), 126-138.
22. Shakil S. M., Muhammad H., Kamal S., &Fogang L. T. (2018). Effect of internal olefin on the properties of betaine-type zwitterionic surfactants for enhanced oil recovery. Journal of Molecular Liquids, 266, 43-50.
23. Evans E., & Needham D. (1987). Physical properties of surfactant bilayer membranes: thermal transitions, elasticity, rigidity, cohesion, and colloidal interactions. The Journal of Physical Chemistry, 91(16), 4219–4228.
24. Yalkowsky S.H., &Dannenfelser R.M. (1992). Solubilization of Drugs in Aqueous Media. College of Pharmacy, University of Arizona, Tucson, 189.
25. Banipal T.S., Kaur H., &Banipal P.K. (2016). Investigations on micellization and surface properties of sodium dodecyl sulfate in aqueous solutions of triflupromazine hydrochloride at different temperatures. Journal of Molecular Liquids, 218, 112–119.
26. Dib N., Silber J.J., Correa N.M., & Falcone R.D. (2022). Amphiphilic ionic liquids capable of formulating organized systems in an aqueous solution, designed by a combination of traditional surfactants and commercial drugs. Pharmaceutical Research, 10, 2379-2390.
27. Lawrence M.J. (1994). Surfactant systems: their use in drug delivery. Chemical Society Reviews, 23, 417-424.
28. Heckenbach M. E., Romero F. N., Green M. D., &Halden R. U. (2016). Meta-analysis of ionic liquid literature and toxicology. Chemosphere, 150, 266-274.
29. Fraser J. K., & MacFarlane R. D. (2009). Phosphonium-based ionic liquids: an overview. Australian Journal of Chemistry, 62, 309–321.
30. Mukhtar A., Kareem S. F., Al Hashim M., &AlNashef I. M. (2010). Phosphonium-based ionic liquids analogues and their physical properties. Chemical Engineering Data, 55(11), 4632–4637.
31. Mukherjee I., Mukherjee S., Naskar B., Ghosh S., &Moulik S. P. (2013). Amphiphilic behavior of two phosphonium-based ionic liquids. The Journal of Colloid and Interface Science, 395, 135-144.
32. Chiappe C., &Pieraccini D. (2005). Ionic liquids: solvent properties and organic reactivity. the Journal of Physical Organic Chemistry., 18(4), 275-297.
33. Tian Y. H., Goff G. S., Runde W. H., & Batista E. R. (2012). Exploring electrochemical windows of room-temperature ionic liquids: a computational study. Journal of Physical Chemistry B 116(39), 11943-11952.
34. Wu F., Schüra A. R., Kim G., Dong X., Kuenzel M., Diemant T.,Passerini A. S. (2021). A novel phosphonium ionic liquid electrolyte enabling high-voltage and high-energy positive electrode materials in lithium-metal batteries. Energy Storage Materials, 42, 826-835.
35. Chen M., White B. T., Kasprzak R. C., & Long E. T. (2018). Advances in phosphonium-based ionic liquids and poly (ionic liquid) as conductive materials. European Polymer Journal, 108, 28-37.
How to Cite
Rashmita Khuntia, & Prashant Mundeja. (1). Molecular Interaction between CTAB with NSAIDs (IBFN) by using Tensiometry, Viscometry, FTIR, and 1H NMR Techniques. Revista Electronica De Veterinaria, 25(2), 2631-2639. https://doi.org/10.69980/redvet.v25i2.2364
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