CONTEXT: Boswellic acids (BAs) are isolated from oleo gum of Boswellia serrata and are mainly used as potential anti-inflammatory, hypolipidemic, immunomodulatory, and antitumor agents. Pharmacokinetic investigations of BAs uncover its poor bioavailability through digestive system thus creates a need for improved therapeutic responses which can possibly be achieved by developing formulations through novel delivery system. OBJECTIVE: Present study was conducted to design topical BA-loaded proniosomal gel for the management of inflammatory disorders with enhanced bioavailability. MATERIALS AND METHODS: Nonionic surfactant vesicles were prepared using the coacervation phase separation method. A central composite design was employed to statistically optimize formulation variables using Design-Expert software. Three independent variables were evaluated: amount of surfactant (X1), amount of soya lecithin (X2), and amount of cholesterol (X3). The encapsulation efficiency percentage (Y1) and particle size (Y2) were selected as dependent variables. RESULTS AND DISCUSSION: The optimum formulation (F10) displayed spherical bi-layered vesicles under transmission electron microscopy with optimum particle size of 707.9 nm and high entrapment efficiency as 98.52%. In vitro skin permeation study demonstrated the most sustained release of 84.83 ± 0.153 mg/cm2 in 24 h. Anti-inflammatory activity of the gel showed a significant (p < 0.001) higher percentage inhibition as compared to the marketed gel at the same dose. CONCLUSION: The present study exhibited that BA-loaded proniosomal gel was better in terms of absorption, bioavailability, and release kinetics.
CONTEXT: Boswellic acids (BAs) are isolated from oleo gum of Boswellia serrata and are mainly used as potential anti-inflammatory, hypolipidemic, immunomodulatory, and antitumor agents. Pharmacokinetic investigations of BAs uncover its poor bioavailability through digestive system thus creates a need for improved therapeutic responses which can possibly be achieved by developing formulations through novel delivery system. OBJECTIVE: Present study was conducted to design topical BA-loaded proniosomal gel for the management of inflammatory disorders with enhanced bioavailability. MATERIALS AND METHODS: Nonionic surfactant vesicles were prepared using the coacervation phase separation method. A central composite design was employed to statistically optimize formulation variables using Design-Expert software. Three independent variables were evaluated: amount of surfactant (X1), amount of soya lecithin (X2), and amount of cholesterol (X3). The encapsulation efficiency percentage (Y1) and particle size (Y2) were selected as dependent variables. RESULTS AND DISCUSSION: The optimum formulation (F10) displayed spherical bi-layered vesicles under transmission electron microscopy with optimum particle size of 707.9 nm and high entrapment efficiency as 98.52%. In vitro skin permeation study demonstrated the most sustained release of 84.83 ± 0.153 mg/cm2 in 24 h. Anti-inflammatory activity of the gel showed a significant (p < 0.001) higher percentage inhibition as compared to the marketed gel at the same dose. CONCLUSION: The present study exhibited that BA-loaded proniosomal gel was better in terms of absorption, bioavailability, and release kinetics.
Authors: Mohamed Fekry; Salwa M Elmesallamy; Nasser R Abd El-Rahman; Mahmoud Bekhit; Hend Alaidy Elsaied Journal: Environ Sci Pollut Res Int Date: 2022-04-26 Impact factor: 5.190