Formulation of Gastro-retentive Floating Tablets of Valsartan by 2 power 2 Factorial Designs: In vitro and In vivo Evaluations
DOI:
https://doi.org/10.37285/ijpsn.2019.12.2.7Abstract
An oral dosage form containing gastro-retentive floating tablets forms a stomach-specific drug delivery system for the treatment of hypertension. Valsartan belongs to the BCS class II (poo Classification System). It is desirable to improve the extent of bioavailability (23%). The objective of the present study was to apply design of experiment to optimize floating drug delivery of valsartan by employing 22 factorial design. Improvement of the aqueous solubility of valsartan was done by solid dispersions using hot melt extrusion technique. Plasdone S630 copovidone is a variable carrier and drug to carrier ratio of 1:2 was optimized. Valsartan floating tablets were prepared by employing factorial design (22), where HPMC K15M (X1) and pregelatinized starch (X2) were independent variables and drug dissolution was the dependent parameter (Y1) to prepare matrix tablets. The factorial analysis, steepest ascent method was utilized for obtaining optimized formulation. In vitro evaluation, In vivo radiographic study and biopharmaceutical analysis in rabbits for valsartan optimized formulation (FT-5). Floating lag time (FLT) for valsartan optimized formulation (FT-5) was 15 s and total floating time (TFT) of the tablets was about 33 h, which was satisfactory. A four-point (1 h, 4 h, 8 h and 16 h) dissolution analysis gave satisfactory dissolution profile up to 24 h. The release kinetics of valsartan optimized formulation (FT-5) followed zero order and the release mechanism was found to be Korsemeyer Peppas model, i.e. swelling type. The dissolution efficiency for valsartan floating tablets was 1190.89% against the marketed formulation of 39.77%. The accelerated stability profile of valsartan optimized formulation (FT-5) was evaluated in terms of drug content and percent cumulative dissolution of valsartan in 24 h, in a 6 months study. In vivo X-ray image study for valsartan optimized formulation (FT-5) indicated the presence of intact tablet up to 12 h in gastric region of rabbit. The biopharmaceutical analysis in rabbits was conducted for valsartan optimized formulation (FT-5). The HPLC method was established and validated for the in vivo analysis. The Cmax was 453.2 ng/mL compared to that of the marketed tablets (522.4 ng/mL). The mean residence time (MRT) for the valsartan optimized formulation (FT-5) was 14.82 h as against 4 h for marketed tablet. The relative bioavailability of valsartan optimized formulation (FT-5) was 650% higher than the marketed tablet. To overcome the poor bioavailability of valsartan, it was suitably modified using hot-melt extrusion for improving therapeutic outcome. In conclusion, gastro-retentive drug delivery system is an excellent approach for improving the bioavailability of valsartan.
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Keywords:
Bioavailability, Hot-melt extrusion, 2 Power 2 factorial design, Steepest ascent, Zero-order, Rabbits, BiopharmaceuticalDownloads
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Brookman LJ, Rolan PE, and Benjamin IS (1997). Pharmacokinetics of valsartan in patients with liver disease. Clin Pharmacol Ther 62: 272-8.
Brunella C, Cleelia DM, and Maria I (2006). Improvement of solubility and stability of valsartan by hydroxypropyl-β- cyclodextrin. J Incl Phenom Macro 54: 289-94.
Cao QR, Liu Y, and Xu WJ (2012). Enhanced oral bioavailability of novel mucoadhesive pellets containing valsartan prepared by a dry powder-coating technique. Int J Pharm 434: 325-333.
Çelebier M, Kaynak MS, and Altınözo S (2010). Validated HPLC method development: The simultaneous analysis of amlodipine and valsartan in samples for liver perfusion studies. Brazilian J Pharm Sci 46: 761-768.
Challa VR, Babu PR, and Challa SR (2013). Pharmacokinetic interaction study between quercetin and valsartan in rats and in vitro models. Drug Dev Ind Pharm 39: 865-872.
Charlie M (2008). Continuous mixing of solid dosage forms via hot melt extrusion. Pharm Tech. 32: 76-86.
Chen W, Miao YQ, and Fan DJ (2011). Bioavailability study of berberine and the enhancing effects of TPGS on intestinal absorption in rats. AAPS Pharm Sci Tech. 12: 705-711.
Criscione L, de Gasparo M, and Buhlmayer P (1993). Pharmacological profile of valsartan: A potent, orally active, nonpeptide antagonist of the angiotensin II AT1-receptor subtype. Br J Pharmacol. 110: 761-771.
Crowley MM. and Zhang F (2007). Pharmaceutical Applications of Hot-Melt Extrusion: Part I. Drug Dev Ind Pharm. 33: 909-926.
Djuris J, Nikolakakis I, and Ibric S (2013). Preparation of carbamazepine-Soluplus solid dispersions by hot-melt extrusion, and prediction of drug-polymer miscibility by thermodynamic model fitting. Eur J Pharm Biopharm. 84: 228-237.
Guo Z, Lu M, and Li Y (2014). The utilization of drug-polymer interactions for improving the chemical stability of hot-melt extruded solid dispersions. J Pharm Pharmcol. 66: 285-296.
Hoichman D, Gromova LI, and Sela J (2004). Gastroretentive Controlled-Release Drugs. Pharm Chem J. 38: 621-4.
Ige PP and Gattani SG (2013). In vivo radio imaging studies on designed swelling gastro retentive drug delivery system. Afr J Pharm Pharmacol. 4: 2846-2848.
Carstensen JT (2006). Stability of solids and solid dosage forms. J Pharm Sci. 63: 1-14.
Jain NK (2004). Progress in Controlled and Novel Drug Delivery Systems, First Ed. CBS Publishers and Distributors, New Delhi, pp 84-85.
Kumar ML, Reddy S, and Managuli RS (2015). Full factorial design for optimization, development and validation of HPLC method to determine valsartan in nanoparticles. Saudi Pharm Journal. 23: 549-555.
Lee JY, Kang WS, and Piao J (2015). Soluplus/TPGS-based solid dispersions prepared by hot-melt extrusion equipped with twin-screw systems for enhancing oral bioavailability of valsartan. Drug Des Devel Ther. 9: 2745-2756.
Leuner C and, Dressman J (2000). Improving drug solubility for oral delivery using solid dispersions. Eur J Pharm Biopharm. 50: 47-60.
Linn M, Collnot EM, and Djuric D (2012). Soluplus® as an effective absorption enhancer of poorly soluble drugs in vitro and in vivo. Eur J Pharm Sci. 45: 336-343.
Ma Q, Sun H, and Che E (2013). Uniform nano-sized valsartan for dissolution and bioavailability enhancement: influence of particle size and crystalline state. Int J Pharm. 441: 75-81.
Mahapatra AK, Murthy PN, and Sudarsan Biswal S (2011). Dissolution Enhancement and Physicochemical Characterization of Valsartan in Solid Dispersions with β-CD, HP β-CD, and PVP K-30. Dissolut Technol.
Maniruzzaman M, Boateng JS, and Bonnefille M (2012). Taste masking of paracetamol by hot melt extrusion: an in vitro and in vivo evaluation. Eur J Pharm Biopharm. 80: 433-442.
Pamu S, Subrahmanyam CVS, and Patnaik KSKR (2014). Hot melt extrusion technique and its pharmaceutical applications: A Review. Int J Pharmaceut Anal Res. 3: 524-530.
Pamu S, Subrahmanyam CVS, and Patnaik KSKR (2016). Gastroretentive dosage forms as oral controlled drug delivery: A review. World J Pharm Res. 5: 368-389.
Pamu S, Subrahmanyam CVS, and Patnaik KSKR (2017): Formulation and in vitro evaluation of gastroretentive floating drug delivery of valsartan using hot melt extrusion technique. Int J Pharm Sci Res. 8: 1813-1819.
Patil JM, Hirlekar RS, and Gide PS (2006). Trends in floating drug delivery systems. J Sci Ind Res. 65: 11-21.
Poudel BK, Marasini N, and Tran TH (2012). Formulation, characterization and optimization of valsartan self-micro-emulsifying drug delivery system using statistical design of experiment. Chem Pharm Bull. 60: 1409-1418.
Practical Manual of Experimental and Clinical Pharmacology by Bikash Medhi and Ajay Prakash 2010.
Ranjan OP, Nayak UY, and Reddy MS (2013). Development and validation of RP-HPLC method with ultraviolet detection for estimation of montelukast in rabbit plasma: Application to preclinical pharmacokinetics. J of Young Pharmacists. 5: 133-138.
Repka MA, Battu SK, and Upadhye SB (2007). Pharmaceutical applications of hot-melt extrusion: Part II. Drug Dev Ind Pharm. 33: 1043-1057.
Rouge N, Buri P, and Doelker E (1996). Drug absorption sites in the gastrointestinal tract and dosage forms for site-specific delivery. Int J Pharm. 136: 117-139.
Sakore S and Chakraborty B (2011). In Vitro - In Vivo Correlation (IVIVC): A Strategic Tool in Drug Development. J Bioequiv Availab. 1-12.
Sandhya P, Subrahmanyam CVS, and Rao Patnaik KSK (2015). Bioanalytical method development and validation of valsartan in rabbit plasma. Int J Pharm. 5: 1360-1364.
Sandhya P, Subrahmanyam CVS, and Rao Patnaik KSK (2016). Plasdone™ s-630 copovidone based hot melt extrudates for the enhancement of solubility, stability and oral bioavailability of poorly soluble valsartan. TSCST NICE–2016 at JNTUH, Hyderabad, ISBN: 978-93-82829-14-0:322-327.
Shin SC and, Kim J (2003). Physicochemical characterization of solid dispersion of furosemide with TPGS. Int J Pharm. 251: 79-84.
Siddiqui N, Husain A and Chaudhry L (2011). Pharmacological and Pharmaceutical Profile of Valsartan: A Review. J Appl Pharm Sci. 1(4): 12-19.
Singh SK, Vuddanda PR, and Singh S (2013). A comparison between use of spray and freeze drying techniques for preparation of solid self-microemulsifying formulation of valsartan and in vitro and in vivo evaluation. Biomed Res Int. 909045.
Streubel A, Siepmann J abd Bodmeier R (2006). Gastroretentive drug delivery system. Expert Opin Drug Deliv. 3: 217-233.
Van Eerdenbrugh B, Van Speybroeck M, and Mols R (2009). Itraconazole/TPGS/Aerosil 200 solid dispersions: characteri-zation, physical stability and in vivo performance. Eur J Pharm Sci. 38: 270-278.
Virkar PS, Pingale SG, and Mangaonkar KV (2012). Development and validation of a high performance liquid chromatography method for determination of telmisartan in rabbit plasma and its application to a pharmacokinetic study. J Anal Bioanal Techn. 3: 133.
Yan YD, Sung JH, and Kim KK (2012). Novel valsartan-loaded solid dispersion with enhanced bioavailability and no crystalline changes. Int J Pharm. 422: 202-210.