PREPARATION AND EVALUATION OF ORALLY DISINTEGRATING TABLETS OF DROTAVERINE HYDROCHLORIDE USING SUBLIMATION TECHNIQUE

Objective: To formulate orally disintegrating taste masked tablets of drotaverine hydrochloride (HCl) by sublimation technique.Methods: Initially superdisintegrant was selected and its concentration was optimized by pre-compression and post-compression parametric evaluation. Camphor and menthol were used as sublimating agents alone and in combination to mask the taste of drotaverine hydrochloride. Prepared tablets were evaluated for physicochemical evaluation, in vitro dissolution studies and fourier transformation-infrared spectroscopy, differential scanning calorimetry and X-ray diffractometry studies.Results: The optimised formulation DCM2 prepared with a mixture of camphor and menthol was characterised by fourier transformation-infrared spectroscopy, differential scanning calorimetry and X-ray diffractometry studies and found no incompatibility and no major shifts were noticed.Conclusion: The results demonstrated that the prepared drotaverine HCl orally disintegrating tablets showed better taste masking. The present sublimation technique can be effectively used for taste masking and also for orally disintegrating tablets

ELECTROSPUN NANOFIBROUS WOUND DRESSINGS: A REVIEW ON CHITOSAN COMPOSITE NANOFIBERS AS POTENTIAL WOUND DRESSINGS

Advancements in topical wound dressings led to the development of products to protect the wound and facilitate addressing special issues in healing and non-healing wounds. Rapidly growing interest in nanofiber research is leading to the development of potential candidates for wound dressing applications. Electrospinning nanofibers have been considered one of the effective materials in development of scaffolds for tissue engineering applications. Nanofibers mimic the extracellular matrix with their structural similarities, high surface area, and porosity, thereby enabling the effective delivery of antimicrobial agents in the wound milieu. Chitosan, an excellent biopolymer, is offering versatile applications as electrospun nanofibers due to the presence of its inherent properties like nontoxicity, biodegradability, biocompatibility, and antimicrobial nature, as well as its efficiency towards re‐epithelialization and regeneration of the granular layer of the wounds. The current review discusses the design and strategies used in the development of electrospun chitosan nanofibers, as well as the limitations of these strategies. This article provides the most recent information on the fabrication of chitosan composite nanofibrous materials and their applications for wound healing