Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-29T07:53:28.741Z Has data issue: false hasContentIssue false

Ibuprofen sorption and release by modified natural zeolites as prospective drug carriers

Published online by Cambridge University Press:  02 January 2018

D. Krajišnik*
Affiliation:
Department of Pharmaceutical Technology and Cosmetology, University of Belgrade–Faculty of Pharmacy, Vojvode Stepe 450, 11000 Belgrade, Serbia
A. Daković
Affiliation:
Institute for the Technology of Nuclear and Other Mineral Raw Materials, Franše d’Epere 86, P.O. Box 390, 11000 Belgrade, Serbia
A. Malenović
Affiliation:
Department of Drug Analysis, University of Belgrade–Faculty of Pharmacy, Vojvode Stepe 450, 11000 Belgrade, Serbia
M. Kragović
Affiliation:
Institute for the Technology of Nuclear and Other Mineral Raw Materials, Franše d’Epere 86, P.O. Box 390, 11000 Belgrade, Serbia
J. Milić
Affiliation:
Department of Pharmaceutical Technology and Cosmetology, University of Belgrade–Faculty of Pharmacy, Vojvode Stepe 450, 11000 Belgrade, Serbia
*

Abstract

The sorption of ibuprofen by modified natural zeolite composites at three concentration levels (10, 20 and 30 mmol/100 g) of cationic surfactants – benzalkonium chloride and cetylpyridinium chloride, in a buffer solution (pH 7.4), was studied. Characterization of the composites before and after ibuprofen sorption was performed by drug sorption and isotherm studies, zeta potential and Fourier Transform infrared spectroscopic analysis. The biopharmaceutical performance of cationic surfactant-modified zeolites as drug formulation excipients was evaluated by in vitro dissolution experiments from the composites with medium surfactant contents. The drug sorption was influenced by the surfactant type and amount used for the zeolite modification. Prolonged drug release over a period of 8 h (up to ~40%) was achieved with both groups of samples. The kinetic analysis showed that the drug release profiles were best fitted with the Higuchi and the Bhaskar models, indicating a combination of drug diffusion and ion exchange as the predominant release mechanisms.

Type
Research Article
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2015

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Adamson, A.W. & Gast, P.A. (1997) Physical Chemistry of Surfaces, 6th edition, pp. 239250. John Wiley & Sons, Inc., New York.Google Scholar
Aguzzi, C., Cerezo, P., Viseras, C. & Caramella, C. (2007) Use of clays as drug delivery systems: Possibilities and limitations. Applied Clay Science, 36, 2236.Google Scholar
Ambrogi, V., Fardella, G., Grandolini, G., Perioli, L. & Tiralti, M.C. (2002) Intercalation compounds of hydrotalcite-like anionic clays with anti-inflammatory agents II: uptake of diclofenac for a controlled release formulation. AAPS Pharmaceutical Science and Technology, 3(3), E26.Google Scholar
Anachkov, S.E., Danov, K.D., Basheva, E.S., Kralchevsky, P.A. & Ananthapadmanabhan, K.P. (2012) Determination of the aggregation number and charge of ionic surfactant micelles from the stepwise thinning of foam films. Advances in Colloid and Interface Science, 183–184, 5567.Google Scholar
Andersson, J., Rosenholm, J., Areva, S. & Lindén, M. (2004) Influences of material characteristics on ibuprofen drug loading and release profiles from ordered micro- and meso-porous silica matrices. Chemistry of Materials, 16, 41604167.CrossRefGoogle Scholar
Bashardoust, N., Jenita, J.J.L. & Zakeri-Milani, P. (2013) Physicochemical characterization and dissolution study of ibuprofen compression-coated tablets using locust bean gum. Dissolution Technologies, 20, 3843.Google Scholar
Bhaskar, R., Murthy, S.R.S., Miglani, B.D. & Viswanathan, K. (1986) Novel method to evaluate diffusion-controlled release of drug from resinate. International Journal of Pharmaceutics, 28, 5966.Google Scholar
Bleam, W.F. (1990) The nature of cation-substitution sites in phyllosilicates. Clays and Clay Minerals, 38, 527536.CrossRefGoogle Scholar
Borne, R., Levi, M. & Wilson, N. (2013) Nonsteroidal anti-inflammatory drugs. Pp. 987–1044 in: Foye’s Principles of Medicinal Chemistry (T.L. Lemke & D.A. Williams, editors) 7th edition. Lippincott, Williams & Wilkins, Philadelphia, USA.Google Scholar
Carretero, M.I. & Pozo, M. (2009) Clay and non-clay minerals in the pharmaceutical industry. Part I. Excipients and medical applications. Applied Clay Science, 46, 7380.Google Scholar
Chiou, C.T., Peters, L.J. & Schmedding, D.W. (1983) Partition equilibriums of non-ionic organic compounds between soil organic matter and water. Environmental Science & Technology, 17, 227231.CrossRefGoogle Scholar
Colella, C. (2011) A critical reconsideration of biomedical and veterinary applications of natural zeolites. Clay Minerals, 46, 295309.CrossRefGoogle Scholar
Costa, P. & Sousa Lobo, J.M. (2001) Modelling and comparison of dissolution profiles. European Journal of Pharmaceutical Science, 13, 123133.Google Scholar
Daković, A., Matijašević, S., Rottinghaus, G.E., Dondur, V., Pietrass, T. & Clewett, F.M. (2007a) Adsorption of zearalenone by organomodified natural zeolitic tuff. Journal of Colloid and Interface Science, 311, 813.Google Scholar
Daković, A., Tomašević-Čanović, M., Rottinghaus, G.E., Matijašević, S. & Sekulić Ž. (2007b) Fumonisin B1 adsorption to octadecyldimethylbenzyl ammoniummodified clinoptilolite-rich zeolitic tuff. Microporous and Mesoporous Materials, 105, 285290.CrossRefGoogle Scholar
Ersoy, B. & Çelik, M.S. (2003) Effect of hydrocarbon chain length on adsorption of cationic surfactants onto clinoptilolite. Clays and Clay Minerals, 51, 172180.Google Scholar
Farías, T., de Ménorval, L.C., Zajac, J. & Rivera, A. (2011) Benzalkonium chloride and sulfamethoxazole adsorption onto natural clinoptilolite: effect of time, ionic strength, pH and temperature. Journal of Colloid and Interface Science, 363, 465475.Google Scholar
Farías, T., de Ménorval, L.C., Zajacb, J. & Rivera, A. (2010) Adsolubilization of drugs onto natural clinoptilolite modified by adsorption of cationic surfactants. Colloids and Surfaces B: Biointerfaces, 76, 421426.Google Scholar
Ghiaci, M., Kia, R., Abbaspur, A. & Seyedeyn-Azad, F. (2004) Adsorption of chromate by surfactant-modified zeolites and MCM-41 molecular sieve. Separation and Purification Technology, 40, 285295.CrossRefGoogle Scholar
Heikkilä, T., Salonen, J., Tuura, J., Hamdy, M.S., Mul, G., Kumar, N., Salmi, T., Murzin, D.Yu., Laitinen, L., Kaukonen, A.M., Hirvonen, J. & Lehto, V.-P. (2007) Mesoporous silica material TUD-1 as a drug delivery system. International Journal of Pharmaceutics, 331, 133138.Google Scholar
Iqbal, J., Kim, H.J., Yang, J.S., Baek, K. & Yang, J.W. (2007) Removal of arsenic from groundwater by micellar-enhanced ultrafiltration (MEUF). Chemosphere, 66, 970976.Google Scholar
Jaynes, W.F. & Boyd, S.A. (1991) Clay mineral type and organic compound sorption by hexadecyltrimethylammonium- exchanged clays. Soil Science Society of America Journal, 55, 4348.Google Scholar
Kragović, M., Daković, A., Marković, M., Krstić, J., Gatta, G.D. & Rotiroti, N. (2013) Characterization of lead sorption by the natural and Fe(III)-modified zeolite. Applied Surface Science, 283, 764774.Google Scholar
Krajišnik, D., Daković, A., Malenović, A., Djekić, Lj., Kragović, M., Dobričić, V. & Milić, J. (2013) An investigation of diclofenac sodium release from cetylpyridinium chloride-modified natural zeolite as a pharmaceutical excipient. Microporous and Mesoporous Materials, 167, 94101.Google Scholar
Krajišnik, D., Daković, A., Milojević, M., Malenović, A., Kragović, M., Bajuk Bogdanović, D., Dondur, V. & Milić, J. (2011) Properties of diclofenac sodium sorption onto natural zeolite modified with cetylpyridinium chloride. Colloids and Surfaces B: Biointerfaces, 83, 165172.Google Scholar
Krajišnik, D., Milojević, M., Malenović, A., Daković, A., Ibrić, S., Savić, S., Dondur, V., Matijašević, S., Radulović, A., Daniels, R. & Milić, J. (2010) Cationic surfactants-modified natural zeolites: Improvement of the excipient’s functionality. Drug Development and Industrial Pharmacy, 36, 12151224.Google Scholar
Krajišnik, D., Stepanović-Petrović, R., Tomić, M., Micov, A., Ibrić, S. & Milić, J. (2014) Application of artificial neural networks in prediction of diclofenac sodium release from drug-modified zeolites physical mixtures and antiedematous activity assessment. Journal of Pharmaceutical Sciences, 103, 10851094.Google Scholar
Li, Z. & Bowman, R. (1998) Sorption of perchloroethylene by surfactant-modified zeolite as controlled by surfactant loading. Environmental Science & Technology, 32, 22782282.Google Scholar
Mallick, S., Pattnaik, S., Swain, K., De, P.K., Saha, A., Mazumdar P . & Ghoshal, G. (2008a) Physicochemical characterization of interaction of ibuprofen by solid-state milling with aluminum hydroxide. Drug Development and Industrial Pharmacy, 34, 726734.Google Scholar
Mallick, S., Pattnaik, S., Swain, K., De, P.K., Saha, A., Ghoshal, G. & Mondal, A. (2008b) Formation of physically stable amorphous phase of ibuprofen by solid state milling with kaolin. European Journal of Pharmaceutics and Biopharmaceutics, 68, 346351.CrossRefGoogle ScholarPubMed
Milić, J., Daković, A., Krajišnik, D. & Rottinghaus, G.E. (2014) Modified natural zeolites – functional characterization and biomedical application. Pp. 353–396 in: Advanced Healthcare Materials (A. Tiwari, editor). Wiley-Scrivener Publishing, Hoboken, New Jersey and Salem, Massachusetts, USA.Google Scholar
Perioli, L., Posati, T., Nocchetti, M., Bellezza, F., Costantino, U. & Cipiciani, A. (2011) Intercalation and release of anti-inflammatory drug diclofenac into nanosized ZnAl hydrotalcite-like compound. Applied Clay Science, 53, 374378.Google Scholar
Rawajfih, Z. & Nsour, N. (2006) Characteristics of phenol and chlorinated phenols sorption onto surfactant-modified bentonite. Journal of Colloid and Interface Science, 298, 3949.Google Scholar
Rivera, A. & Farías, T. (2005) Clinoptilolite–surfactant composites as drug support: A new potential application. Microporous and Mesoporous Materials, 80, 337346.Google Scholar
Rivera, A., Farías, T., Ruiz-Salvador, A.R. & de Menorval, L.C. (2003) Preliminary characterization of drug support systems based on natural clinoptilolite. Microporous and Mesoporous Materials, 61, 249259.Google Scholar
Sheng, G., Xu, S. & Boyd, S.A. (1996) Mechanism(s) controlling sorption of neutral organic contaminants by surfactant-derived and natural organic matter (1996) Environmental Science & Technology, 30, 15531557.CrossRefGoogle Scholar
Sposito, G. (1984) The Surface Chemistry of Soils. Oxford University Press, Oxford, UK.Google Scholar
Sullivan, E.J., Hunter, D.B. & Bowman, R.S. (1997) Topological and thermal properties of surfactantmodified clinoptilolite studied by tapping-mode atomic force microscopy and high-resolution thermogravimetric analysis. Clays and Clay Minerals, 45, 4253.Google Scholar
Wang, S., Gong, W., Liu, X., Gao, B. & Yue, Q. (2006) Removal of fulvic acids using the surfactantmodified zeolite in a fixed-bed reactor. Separation and Purification Technology, 51, 367373.Google Scholar
Zhu, L., Chen, B. & Shen, X. (2000) Sorption of phenol, p-nitrophenol, and aniline to dual-cation organobentonites from water. Environmental Science & Technology, 34, 468475.Google Scholar