Formulation and Evaluation of Oral Controlled Release Clarithromycin Matrix Tablets using Hydrophilic Polymer
DOI:
https://doi.org/10.37285/ijpsn.2013.6.4.8Abstract
The objective of the present study was to develop clarithromycin tablets from polymeric hydrophilic matrices using methocel and characterization for its physic-chemical properties and in vitro release studies to optimize its release profile with the standard marketed product. Matrix tablets were prepared by wet granulation method using PVP and ethyl cellulose as binding agents. The matrix tablets were evaluated for its thickness, hardness, friability, weight variation, drug content and in vitro release studies. The drug delivery was analyzed using the paddle method in phosphate buffer pH 6.0 (dissolution medium I) and phosphate buffer pH 6.8 containing 0.5% sodium lauryl sulfate (dissolution medium II) and compared with USP dissolution limits. The dissolution release profile of formulation F9 was comparable with the market formulation and the difference factor and similarity factor f1 and f2 was found to be 2.44 and 83.18 in dissolution medium I; 1.44 and 89.71 in dissolution medium II. Stability studies were carried out as per ICH guidelines and tested for its physicochemical properties and in vitro studies. The study shows that the matrix method can be employed for preparing clarithromycin sustained release formulation using combination of hydrophilic polymers like Methocels and sodium carboxy methyl cellulose.
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Keywords:
Clarithromycin, HPMC, Eudragit NE 30D, Sustained release matrix, Tablet disintegrant
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References
Bankar GS, Anderson GS (1987). Tablets. In The theory and practice of industrial pharmacy (Lachman L, Liberman HA, Kanig JL eds), 3rd ed. Varghese publishing house, Mumbai, 1987; 383.
Ford JL, Mitchell K, Rowe P, Armstron DJ, Elliot PNC, Rostron C (1991). Mathematical modeling of drug release from hydroxyl propylmethyl cellulose matrices: Effect of the temperature. Int J Pharm 71: 95-104.
Lakshmana Prabu S, Shirwaikar A, Sirwaikar AA, Ravikumar, Aravind Kumar G, Abraham J (2009). Formulation and evaluation of oral sustained release of Diltiazem Hydrochloride using rosin as matrix forming material. ARS Pharma 50: 32-42.
Loganathan V, Senthil Kuamr K, Siva Prasada Reddy MV, Sreekanth N, Senthil Kumar B (2003). Studies on preformulation compatibility between lomefloxacin and tablet excipients through DSC and X-ray diffraction analysis. Int Journal of Pharmaceutical Excipients. April-June: 38-49.
Ranga Rao KV, Padmaltha Devi K (1988). Swelling controlled release systems: Recent development and applications. Int J Pharm 48: 1-13.
Roseman TJ, Cardinelli NF (1980). In Controlled release technologies (Kydonieus AF eds), Vol 1, CRC Press, Boca Raton, FL, 1980.
Salsa T, VEiga F, Pina ME (1997). Oral controlled release dosage forms: I. Cellulose ether polymers in hydrophilic matrices. Drug Dev Ind Pharm 239: 929-938.
Siepmann J, Kranz H, Bodmeier R (1999). HPMC matrices for controlled drug delivery: A new model combining diffusion, swelling and dissolution mechanism and predicting the release kinetics. Pharm Res 16: 1748-1756.
Sung KC, Nixon PR, Skoug JW, Ju TR, Gao P, Patel MV (1996). Effect of formulation variables on drug and polymer release from HPMC based matrix tablets. Int J Pharm 142: 53-60.
