Objective: The aim of the present work was to enhance the solubility of rosuvastatin calcium by self-nano emulsifying drug delivery system (SNEDDS) using mixtures of oil, cosolvent, surfactant and cosurfactant. Methods: Based on solubility study and emulsification efficiency, Preliminary investigations of various oils, surfactants and cosurfactants were carried out for the selection of the proper SNEDDS ingredients. Pseudo-ternary phase diagrams were constructed to identify the efficient self-emulsification region. A series of SNEDDS formulations were prepared using labrasol: cremophor EL with a combination of peceol: ethyl oleate by using the simplex lattice design. Prepared formulation evaluated for refractive index, turbidimetric, droplet size, zeta potential and polydispersity index, self-emulsification, stability tests, viscosity and in vitro diffusion studies. Results: The best formula for SNEDDS in the current study were: 15% oil (peceol: ethyloleatein 1:1 ratio), 50% Labrasol and 35% Cremophor EL. All the SNEDDS batches globule size was found to be varied from 22.90±1.50 nm to 43.90±1.40 nm. and no significant variations in globule size were observed after 3 mo stability studies. All the batches % transparency was found to be varied from 95.40±1.40% to 99.50±1.10% and drug diffused in 10 min varied from 63.65±1.51% to 93.72±1.46 %. Conclusion: The data suggest the use of rosuvastatin calcium SNEDDS to offer the potential for delivery and it increases the aqueous solubility and bioavailability of the drug.
Objective: The aim of the present study was to optimize long-acting injectable (LAI) microspheres of Paliperidone palmitate (PP) for treatment of schizophrenia using face-centered central composite design (FC-CCD). Methods: In this study, poly lactic-co-glycolic acid (PLGA) based LAI microspheres of paliperidone palmitate (PP) were formulated by using FC-CCD. LAI microspheres were developed by using oil in water (O/W) emulsion solvent evaporation technique. On the basis of preliminary trials, FC-CCD was employed to check effect of independent variables such as drug polymer ratio (X1), homogenization speed (X2) and rate of addition (X3). While mean particle size (Y1), drug loading (Y2), entrapment efficiency (Y3), burst release (Y4), and drug release on day 60 (Y5) were considered as dependent variables and statistically evaluation performed by using design expert 12 software. Morphology of prepared microspheres was studied by using the scanning electron microscopy (SEM) technique, while particle size was analyzed by laser diffraction technique. In vitro drug release studies were performed using a controlled temperature shaking water bath apparatus. Fourier transforms infrared spectroscopy (FTIR) and differential scanning calorimetric (DSC) study were performed to analyze any changes in crystal behavior or to detect any chemical bonding between ingredients. 13C NMR and 1H NMR techniques were used to analyze end-capping and monomer ratio in developed microspheres. Results: The factorial batches mean particle size was found to be 38 µm to 104 µm and drug loading were found between 27.2 % to 47.2%. Mathematical modelling of drug release kinetics revealed that near zero-order drug release of checkpoint formulations. Endcap analysis and molar ratio of formulated microspheres were found to be ester end cap and ~75:25, respectively. Morphologically all the prepared samples were found to be spherical in shape and smooth surface. FTIR data showed no significant interactions occurred between drug and excipients. The actual responses of checkpoint formulations were observed within 5% variation of predicted values. Conclusion: The prepared microspheres showed promising results of morphology, particle size, drug loading, entrapment efficiency, burst release and drug release on day 60. The successful predictive designs models were achieved from employed FC-CCD.
Objective: The aim of present work was to develop of pediatric cefuroxime axetil 125 mg dispersible tablets by using ion exchange resin as a taste masking agent and quality target product profile was defined based on the properties of the cefuroxime axetil. Methods: Initially, cefuroxime axetil and various resin complexes (DRC) were prepared with different conditions and evaluated for taste masking and drug loading. Optimized DRC was used to formulate the dispersible tablet. A 32 full factorial design was employed to study the effect of mannitol (X1) and microcrystalline cellulose PH-101 (X2) on drug release at 10 min and time taken to 80% drug release. In the present study, the following constraints were arbitrarily used for the selection of an optimized batch: Q10>65% and T80%<30 min. Multiple linear regression analysis, ANOVA and graphical representation of the influence factor by 3D plots were performed by using Sigmaplot 11.0. Checkpoint batch was prepared to validate the evolved model. Results: Among the various drug resins complex DRC-9 was found with less bitter taste which was containing kyron T-114 and among the all factorial batch F7 showed highest drug release at 10 min (Q10) and lowest time taken to 80% drug release (T80) hence batch F7 was selected as an optimized batch and it’s found to be stable in the stability evaluation. Conclusion: The results of full factorial design indicate mannitol and MCC PH-101 have a significant effect on drug release.
Objective: The aim of the present work was to prepare film coated tablet of glucosamine sulfate potassium chloride and study the effect of coating process parameters which implicate more significant effects on an aqueous-based film coating process of tablets. Methods: The different batches of uncoated tablets were prepared by wet granulation method. Aqueous film coating was carried out by using opadry®II white 85F18422. A 32 full factorial design was employed to study the effect of spray rate (X1) and inlet air temperature (X2) on coating uniformity, coating process efficiency and % loss on drying. The surface characteristics of the aqueous based film coated tablet were studied using a SEM. Check point batch was prepared to validate the evolved model. Results: Preliminary trials indicated that individually process parameters affected the quality of coated tablets. Hence, studied the combined effect of these factors on the coating process required and 32 full factorial design was applied. In this study, it was seen that spray rate and inlet air temperature had a major effect on tablet coating process. It was observed from factorial batch that maximum drug release was found in batch F5. Conclusion: The results of full factorial design indicate both parameters spray rate (X1) and inlet air temperature (X2) have significant effect on coating process and batch F5 is stable for 3 mo at accelerated condition.
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