IN VITRO EQUIVALENCE STUDY OF GENERIC NAPROXEN SODIUM TABLETS USING THE USP PADDLE APPARATUS AND THE FLOW-THROUGH CELL METHOD

Authors

  • JOSE RAUL MEDINA Departamento Sistemas Biologicos Universidad Autonoma Metropolitana-Xochimilco
  • Araceli Uribe Departamento Sistemas Biologicos Universidad Autonoma Metropolitana-Xochimilco
  • Marcela Hurtado Departamento Sistemas Biologicos Universidad Autonoma Metropolitana-Xochimilco
  • ADRIANA MIRIAM DOMINGUEZ-RAMIREZ Departamento Sistemas Biologicos Universidad Autonoma Metropolitana-Xochimilco

Keywords:

Naproxen sodium, Flow-through cell method, Immediate-release generic products

Abstract

Objective: To perform an in vitro equivalence study of naproxen sodium from six immediate release oral dosage forms under the hydrodynamic environments generated by the flow-through cell method and the USP paddle apparatus.

Methods: Dissolution method was properly validated according to standard criteria. Dissolution profiles of all formulations were carried out with an automated flow-through cell (laminar flow at 16 ml/min with 22.6 mm cells) and the USP Apparatus 2 (50 rpm). 0.1 M phosphate buffer pH 7.4 at 37.0±0.5 °C was used as the dissolution medium. Spectrophotometric determination of drug at 332 nm was carried out during 45 min. Dissolution profiles were compared with model-dependent and independent approaches.

Results: Significant difference with model-independent parameters, mean dissolution time and dissolution efficiency, using both USP apparatuses, were found (*P<0.05). Best fitting of dissolution data was obtained using the sigmoidal model (R2>0.99). Only with the flow-through cell method linear regression between mean dissolution time and t63.2% values was significant (*P<0.05).

Conclusion: The study reveals significant differences in dissolution rate and a great variability for all naproxen sodium tablets when the USP paddle apparatus is used. The alternative dissolution test with the flow-through cell method allows obtaining reliable data which facilitates in vitro equivalence respect the reference product dissolution behavior.


 

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References

Al Almeri MN, Nayuni N, Anuil Akumar KG, Perrett D, Tucker A, Johnston A. The differences between the branded and generic medicines using solid dosage forms: in-vitro dissolution testing. Results Pharma Sci 2012;2:1−8.

Food and Drug Administration. Guidance for industry: Waiver on in vivo bioavailability and bioequivalence studies for immediate-release solid oral dosage forms based on a biopharmaceutics classification system; 2000.

Lennernäs H, Abrahamsson B. The use of biopharmaceutical classification of drugs in drug discovery and development: current status and future extension. J Pharm Pharmacol 2005;57:273–85.

Guo Z, Liu X, Ma L, Li J, Zhang H, Gao Y, et al. Effects of particle morphology, pore size and surface coating of mesoporous silica on naproxen dissolution rate enhancement. Colloid Surf B 2013;101:228−35.

Kasim NA, Whitehouse M, Ramachandran C, Bermejo M, Lennernäs H, Hussain AS, et al. Molecular properties of the WHO essential drugs and provisional biopharmaceutical classification. Mol Pharm 2004;1:85–96.

ACUERDO por el que se adiciona y modifica la relación de especialidades farmacéuticas susceptibles de incorporarse al catálogo de medicamentos genéricos intercambiables. Diario Oficial de la Federación; 2005. Available from: URL: http://www.salud.gob.mx/unidades/cdi/nom/compi/a110205.html [Last accessed 02 Apr 2015].

United States Pharmacopeia and national formulary USP 37-NF 32; The United States Pharmacopeial Convention, Inc: Rockville MD; 2014.

Singh I, Aboul-Enein HY. Advantages of USP Apparatus IV (flow-through cell apparatus) in dissolution studies. J Iran Chem Soc 2006;3:220–2.

Qui S, Wang K, Li M. In vitro dissolution studies of immediate-release and extended-release formulations using flow-through cell apparatus 4. Dissolution Technol 2014;21:6-15.

Sunesen VH, Pedersen BL, Kristensen HG, Müllertz A. In vivo in vitro correlations for a poorly soluble drug, danazol, using the flow-through dissolution method with biorelevant dissolution media. Eur J Pharm Sci 2005;24:305–13.

Szymanska E, Winnicka K. Comparison of flow-through cell and paddle methods for testing vaginal tablets containing a poorly water-soluble drug. Trop J Pharm Res 2013;12:39–44.

Emara LH, Emam MF, Taha NF, El-Ashmawy AA, Mursi NM. In-vitro dissolution study of meloxicam immediate release products using flow through cell (USP apparatus 4) under different operational conditions. Int J Pharm Pharm Sci 2014;6:254−60.

Fotaki N, Reppas C. The flow through cell methodology in the evaluation of intralumenal drug release characteristics. Dissolution Technol 2005;12:17−21.

Jinno J, Kamada N, Miyake M, Yamada K, Mukai T, Odomi M et al. In vitro-in vivo correlation for wet-milled tablet of poorly water-soluble cilostazol. J Controlled Release 2008;130:29−37.

Jantratid E, De Maio V, Ronda E, Mattavelli V, Vertzoni M, Dressman JB. Application of biorelevant dissolution tests to the prediction of in vivo performance of diclofenac sodium from an oral modified-release pellet dosage form. Eur J Pharm Sci 2009;37:434−41.

Hurtado M, Vargas Y, Domínguez-Ramírez AM, Cortés AR. Comparison of dissolution profiles for albendazole tablets using USP Apparatus 2 and 4. Drug Dev Ind Pharm 2003;29:777−84.

Medina JR, Salazar DK, Hurtado M, Cortés AR, Domínguez-Ramírez AM. Comparative in vitro dissolution study of carbamazepine immediate-release products using the USP paddles method and the flow-through cell system. Saudi Pharm J 2014;22:141−7.

Razdan BK, Nagaraja NV. Evaluation of dosage forms: studies on commercial tablet dosage forms of naproxen. Pharm Pharmacol Commun 1998;4:253−6.

Hernández-Abad VJ, Castañeda-Hernández G, García-Jiménez S, Marroquín-Segura R, Sánchez-González E. Evaluation of the quality of four Mexican drug products containing sodium naproxen. J Clin Pharm Ther 2008;33:237−42.

NOM-177-SSA1-2013, Norma Oficial Mexicana. Available from: URL: http://www.dof.gob.mx/nota_detalle. php?codigo=5314833&fecha=20/09/2013 [Last accessed 02 Apr 2015].

Yuksel N, Kanik AE, Baykara T. Comparison of in vitro dissolution profiles by ANOVA-based, model-dependent and independent-methods. Int J Pharm 2000;209:57−67.

Zhang Y, Huo M, Zhou J, Zou A, Li W, Yao C, et al. DD Solver: an add-in program for modeling and comparison of drug dissolution profiles. AAPS J 2010;12:263−71.

Mishra B, Sahoo J, Kumar Dixit P. Formulation and process optimization of naproxen nanosuspensions stabilized by hydroxy propyl methyl cellulose. Carbohydr Polym 2015;127:300−8.

Langenbucher F, Benz D, Kurth W, Moller H, Otz M. Standardized flow-cell method as an alternative to existing pharmacopoeial dissolution testing. Pharm Ind 1989;51:1276−81.

Steffansen B, Brodin B, Und Nielsen C. editors. Molecular Biopharmaceutics. ULLA Pharmacy Series. Pharmaceutical Press; 2010.

Fotaki N, Symillides M, Reppas C. In vitro versus canine data for predicting input profiles of isosorbide-5-mononitrate from oral extended release products on a confidence interval basis. Eur J Pharm Sci 2005;24:115−22.

Cardot JM, Beyssac E, Alrici M. In vitro-in vivo correlation: importance of dissolution in IVIVC. Dissolution Technol 2007;14:15−9.

Azevedo de Mello V, Ricci-Júnior E. Encapsulation of naproxen in nanostructured systems: structural characterization and in vitro release studies. Quim Nova 2011;34:933−9.

Adams E, Coomans D, Smeyers-Verbeke J, Massart DL. Non-linear mixed effects models for the evaluation of dissolution profiles. Int J Pharm 2002;240:37−53.

Wei X, Sun N, Wu B, Yin C, Wu W. Sigmoidal release of indomethacin from pectin matrix tablets: effect of in situ crosslinking by calcium cations. Int J Pharm 2006;318:132−8.

Ito R, Golman B, Shinohara K. Design of multi-layer coated particles with sigmoidal release pattern. Chem Eng Sci 2005;60:5415−24.

Kállai-Szabó N, Luhn O, Bernard J, Kállai-Szabó B, Zelkó R, Antal I. Comparative dissolution study of drug and inert isomalt based core material from layered pellets. J Pharm Biomed Anal 2014;98:339−44.

Costa P, Sousa Lobo JM. Modeling and comparison of dissolution profiles. Eur J Pharm Sci 2001;13:123−33.

D’Arcy DM, Corrigan OI, Healy AM. Hydrodynamic simulation (computational fluid dynamics) of asymmetrically positioned tablets in the paddle dissolution apparatus: impact on dissolution rate and variability. J Pharm Pharmacol 2005;57:1243−50.

Ameur H, Bouzit M. 3D hydrodynamics and shear rates’ variability in the united states pharmacopeia paddle dissolution apparatus. Int J Pharm 2013;452:42−51.

D’Arcy DM, Liu B, Bradley G, Healy AM, Corrigan OI. Hydrodynamic and species transfer simulations in the USP 4 dissolution apparatus: considerations for dissolution in a low velocity pulsing flow. Pharm Res 2009;27:246−58.

Kakhi M. Classification of the flow regimes in the flow-through cell. Eur J Pharm Sci 2009;37:531−44.

Published

01-07-2015

How to Cite

MEDINA, J. R., A. Uribe, M. Hurtado, and A. M. DOMINGUEZ-RAMIREZ. “IN VITRO EQUIVALENCE STUDY OF GENERIC NAPROXEN SODIUM TABLETS USING THE USP PADDLE APPARATUS AND THE FLOW-THROUGH CELL METHOD”. International Journal of Pharmacy and Pharmaceutical Sciences, vol. 7, no. 7, July 2015, pp. 348-54, https://journals.innovareacademics.in/index.php/ijpps/article/view/6503.

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