Design, Devlopment and Evaluation of Gastroretentive Floating Microspheres of Glibenclamide: In-vitro In-vivo Studies

Radheshyam Samanta^1*, Gaurav Tiwari¹, Naveen Gupta¹, Dharmendra Singh Rajput¹ Prasenjit Maity²

¹Department of Pharmacy, Patel College of Pharmacy, Madhyanchal Professional University, Bhopal, Madhya Pradesh, India.

²Department of Pharmaceutical Science and Technology, BIT MESRA, Ranchi, Jharkhand, India. 

Received: 15^th March, 2024; Revised: 23^rd May, 2024; Accepted: 13^th August, 2024; Available Online: 25^th September, 2024 

ABSTRACT

The current research study was designed to characterize the ethyl cellulose act as a carrier mediator used to prepare a floating microsphere of glibenclamide for developed gastroretentive sustain release floating drug delivery. Different microspheres of glibenclamide were formulated by the emulsion solvent evaporation technique of glibenclamide with EC in different ratios by using two solvent systems (ethanol and chloroform). After evaluating the micropolitics properties, %of yield value, drug loading efficiency, entrapment efficiency, diameter and surface morphology of the microsphere by using DLS and SEM, in-vitro drug release in gastric content, in-vitro buoyancy, and in-vivo floatation using animal model, compatibility study by FTIR, DSC and any other analytical study to demonstrate all formulation (especially GM2) was showing excellent results. So this work shows great gastro etentive floating drug delivery system for prolonged periods of time which is very useful in future for further study.

Keywords: Gastroretentive, Solvent evaporation, Floatation, Microspheres. International Journal of Drug Delivery Technology (2024); DOI: 10.25258/ijddt.14.3.48

How to cite this article: Samanta R, Tiwari G, Gupta N, Rajput DS, Maity P. Design, Devlopment and Evaluation of Gastroretentive Floating Microspheres of Glibenclamide: In-vitro In-vivo Studies. International Journal of Drug Delivery Technology. 2024;14(3):1591-1598.

REFERENCES

1. Alqahtani MS, Kazi M, Alsenaidy MA, Ahmad MZ. Advances in oral drug delivery. Front. Pharmacol. 2021; 12: 618411. doi. org/10.3389/ fphar.2021.618411.
2. He S, Liu Z, Xu D. Advance in oral delivery systems for therapeutic protein. J. Drug Target. 2019; 27: 283–291, doi: 1080/1061186X.2018.1486406.
3. Singh BN, Kim Floating drug delivery systems: an approach to oral controlled drug delivery via gastric retention. J Control Release. 2000; 63: 235. doi.org/10.1016/S0168-3659 (99)00204-7.
4. Brahma NS, Kwon HK. Floating drug delivery systems: an approach to oral controlled drug delivery via gastric retention. J Controlled Release 2000; 63:35–259.
5. Renukuntla J, Vadlapudi AD, Patel A, Boddu SH, Mitra AK. Approaches for enhancing oral bioavailability of peptides and proteins. Int. J. Pharm. 2013; 447(1-2):75-93. doi: 10.1016/j. 2013.02.030.
6. Prasad D, Parashar T, Khaudiyal S, Semwal A, Jakhmola V. Gastro retentive drug delivery system: Latest approaches towards novel drug delivery, IJPQA, 2023; 14 (4): 1256-1263.
7. Brijesh SD, Avani FA, Madhabhai MP. Gastro retentive drug delivery system of ranitidine hydrochloride: formulation and in-vitro evaluation. AAPS Pharm. Sci. Tech.; 2004; 5(2), 1-6.
8. Pallam NC, Maruvajala V, Mounika SS T, Design and Charecterization of Hallow Porous Floating Microspheres ofFavipiravir. IJDDT. 2024; 14(1): 236-245.
9. Mujbaile S, Khobragade D, Mundhada D. Formulation and optimisation of microspheres of leaves extract of lantana camara 3² design approaches, IJPQA, 2023; 14: 268-273
10. Iyan S, Sriwidodo, Retno W, Norisca A Review, Floating drug delivery system as a tool to improve dissolution rate in gastric, International jornal of applied pharmaceutic. 2020; 12(4): 51-54.
11. Bhange A M, Gunde C M, Ukey B S, Suruse B P. Formulation and Evaluation of Gastro Retentive Floating Tablet of Cetrizine Hydrochloride using Linseed Musilage Polymer. IJDDT. 2023; 13(4): 1544-1547.
12. Bajpai SK, Bajpai M, Sharma L. Investigation of water uptake behavior and mechanical properties of superporous hydrogels. J Macromol Sci. 2006; 43: 507-24.
13. Juthi AZ, Li F, Wang B, Alam MM, Talukder ME, Qiu pH-responsive super-porous hybrid hydrogels for gastroretentive controlled-release drug delivery. Pharmaceutics. 2023; 15: 816. doi.org/10.3390/pharmaceutics15030816.
14. Groning R, Berntgen M, Georgarakis M. Acyclovir serum concentrations following peroral administration of magnetic depot tablets and the influence of extracorporal magnets to control gastrointestinal transit. Eur J Pharm Biopharm. 1998; 46: 285-91.
15. Arza RAK, Gonugunta CSR, Veerareddy PR. Formulation and evaluation of swellable and floating gastroretentive ciprofloxacin hydrochloride AAPS PharmSciTech 2009; 10(1):220-6. doi: 10.1208/s12249-009-9200.
16. Siepmann, J, Kranz H, Bodmeier R, Peppas HPMC matrices for controlled drug delivery: A new model combining diffusion, swelling and dissolution mechanisms and predicting the release kinetics. Pharm. Res. 1999; 16: 1748-1756.
17. Pund S, Joshi A, Vasu K, Gastroretentive delivery of rifampicin: In vitro mucoadhesion and in vivo gamma scintigraphy. Int J Pharm. 2011; 4(11):106-12.
18. Varshosaz J, Tavakoli N, Roozbahani F. Formulation and in vitro characterization of ciprofloxacin floating and bioadhesive extended-release Drug Delivery. 2006; 13(4):277-85. doi: 10.1080/10717540500395106.
19. Janugada BU, Singla N. Formulation, In-vitro and In-vivo Evaluation of Chronology-based Mucoadhesive Drug Delivery System of an Antihypertensive IJDDT. 2024; 14( 1):4-101.
20. Kavimandan NJ, Lakshman JP, Matharu AS. Extended Release Gastro retentive Oral Drug Delivery System for Valsartan, JSTOR. 2009; 2061438.
21. Klausner EA, Lavy E, Friedman M, Hoffman A. Expandable gastroretentive dosage forms. J Control Release. 2003; 90: 143-62.
22. Riefflin A, Ayyagari U, Rury R, Jonathan The effect of glibenclamide on insulin secretion at normal glucose concentrations. 2015; 58: 43–49.
23. Parida P, Mishra SC, Sahoo S, Behera A, Nayak BP. Development and characterization of ethylcellulose based microsphere for sustained release of nifedipine. Journal of Pharmaceutical Analysis. 2016; 6(5): 341-344
24. Bipul N, Lilakanth N, Bhaskar M, Pradeep K, Niraj S, Bhanupratap S. Preparation and characterization of Salbutamol sulphate loaded Ethyl cellulose microspheres using water-inoil- in-oil emulsion technique. Iranian J. Pharm. Res. 2010; 9(2): 97-105.
25. Geng y, Williams GR. Developing and scaling up captopril- loaded electrospun ethyl cellulose fibers for sustained-release floating drug delivery. International Journal of Pharmaceutics. 2023; 648: 123557.
26. Dash SK, Khan AS, Das SR, Padhan A, Rout D. Formulation and In-Vitro Evaluation of Sustained Released Glibenclamide Microspheres. International Journal of Pharmaceutical Sciences and Research. 2012; 3: 1433-1443.
27. Rao AA, Rao N, Raju B. Mohammed J. Formulation and Evaluation of Floating Microspheres of 2023; 16(5): 343.
28. Rajpali D, Gupta V. Floating Microspheres Based Nizatidine Gastro Retentive Formulation to Control the Release of Drug. Letter in applied nanobioscience. 2020; 9(3): 1409 – 1419.
29. Sato Y, Kawashima Y, Takeuchi H, Yamamoto H. In vitro evaluation of floating and drug releasing behaviour of hollow microsphers (microballoons) prepared by emulsion solvent diffusion method. European journal of pharmaceutics and biopharmaceutics 2004; 57: 564.
30. Kokardekar RR, Chaudhari YS, Kumavat SD, Pawar HA. Development and Evaluation of Sustained Release Microspheres of Glibenclamide by Emulsion Solvent Evaporation Method. Clin Pharmacol Biopharm. 2014; 4(1): 234. doi: 10.4172/2167- 1000127.