Development and optimization of flurbiprofen loaded microsponges; an in-vitro evaluation

Current study was designed with the aim to employ quasi emulsification, and double emulsification techniques for the development of Flurbiprofen (FLB) loaded micro sponges, followed by their physicochemical evaluation. FTIR interpretations exhibited compatibility of ingredients, while crystallograph...

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Bibliographic Details
Published in:Pakistan journal of pharmaceutical sciences 2019-07, Vol.32 (4(Supplementary)), p.1773-1779
Main Authors: Qureshi, Sundus, Zaman, Muhammad, Mahmood, Asif, Shah, Shahid, Amjad, Muhammad Wahab, Shaheryar, Zaib Ali, Sarfraz, Rai Muhammad, Khan, Sajid Mahmood, Raja, Maria Abdul Ghafoor
Format: Article
Language:English
Subjects:
Analysis
Delayed-Action Preparations - chemistry
Drug Compounding - methods
Drug Delivery Systems - methods
Electron microscopy
Flurbiprofen
Flurbiprofen - chemistry
Particle Size
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Summary:Current study was designed with the aim to employ quasi emulsification, and double emulsification techniques for the development of Flurbiprofen (FLB) loaded micro sponges, followed by their physicochemical evaluation. FTIR interpretations exhibited compatibility of ingredients, while crystallographic analysis revealed crystalline nature of pure drug, which was masked upon incorporation into microsponges. Optical microscope and SEM have exposed spherical and spongy surfaces of prepared micro sponges. Micromeritics suggested that the flow properties are excellent and microsponges have remarkable drug entrapment efficiency (98.55±0.08%). In-vitro dissolution studies demonstrated good control over release of FLB until 8th h from the prepared microsponges. However, a difference in cumulated amount of released drug was noticed i.e. EC based formulation has released about 99.3±0.10%, while XG facilitated EC based formulations offered 92.7±2.1% release of the drug. Zeta potential indicated access of negative charge while zeta sizer has described the range of the particle size between 2.6 to 3.5μm. Conclusively the results have advocated the suitability of selected ingredients for incorporation of FLB into microsponges for its sustained delivery.
ISSN:1011-601X