Objective: The purpose of this study is to evaluate the quality control of marketed tablets containing propranolol hydrochloride available on the Iraqi market and manufactured by different companies. Methods: Different batches of propranolol hydrochloride 40 mg tablets were assessed using quality control tests. Weight variation, diameter, thickness, friability, disintegration time and dissolution study were carried out in this study. Results: Based on the data obtained in this study, all brands of PPL available on the Iraqi market showed weight variation within the acceptable limit of USP. Marketed products of Becardin and Propranolol lie within the acceptable limit of hardness and Inderal was observed to be slightly higher than the normal upper range of USP. Diameter and thickness for all brands were almost the same, except the diameter of Becardin was slightly higher and friability was zero for all brands. All brands demonstrated a time of disintegration of fewer than 30 min. The tested marketed propranolol products; Inderal, Procard, Becardin and Propranolol showed cumulative drug release of 90.08%, 94.46%, 92.4% and 79.51%, respectively at the end of the first 20 min. This variation in the release profile of marketed tablets of Propranolol HCl might be attributed to the excipients present in the marketed tablets where some of these excipients may behave as a disintegrant and enhance dissolution rate while others may act as dissolution retardants. Conclusion: All marketed tablets of Propranolol HCl employed in this study were produced within the standard criteria of tablet manufacturing. Evaluation of quality control of these selected tablets showed acceptable pharmaceutical properties that lie within the limits of USP.
The aim of the work is to consolidate azilsartan-kamedoxomil (AZM) into lipid matrix controlled-release microparticles to enhance its permeability because AZM belongs to Biopharmaceutical classification (BCS) IV which characterized by poor permeability and to protect AZM from light and humidity and execute a prolonged release profile. Materials and methods. A reversed-phase HPLC method was created and validated to estimate the drug. AZM microparticles formulations were invented using melt dispersion technique and waxy materials such as carnuba wax, beeswax, stearic acid in the ratio of waxy-substance: drug ranging from 0.25: 1 to 1:1 and stabilizer namely; tween 80 and Poloxamer 407 in ratio of stabilizer: drug ranging from 0.5:1 to 1:1. Azilsartan formulations were assessed for azilsartan-medoxomil content, loading, entrapment efficiency, the zeta potential,the particle size, the morphology by scanning electronic microscopy (SEM), and in-vitro release profile. Results. Zeta potential results for microparticle formulations using beeswax and carnuba range from -21.1 mV to -26.6 mV and -20.6 mV to -26.7 mV, respectively. This difference indicates that the azilsartan microparticles containing stearic acid are better stabilized with zeta potential of 25.3 - 29.7 mV. Furthermore, the release from azilsartan microparticle formulations containing stearic acid exceeded 80 % after 8 h and remained for 24 h while release from beeswax did not exceed 65 % after the same period and less than 60 % in case of carnuba formulations Conclusions. The formulation (AZSP4) exhibited the highest zeta potential and released exceeding 80 % of AZM over the course of 8 hours and remained over a day. AZSP4 microparticles formulation containing, poloxamer 407, in a 0.8:0.8:1 drug: stearic acid: poloxamer ratio proved the ability of stearic acid microencapsulation employing poloxamer as stabilizer in a certain ratio can prolong the release of AZM
Objective: The aim of this study was to formulate, evaluate and characterise nanoemulsion formulation containing a lipophilic drug, Ketoprofen. Methods: Nanoemulsion formulations composed of oil, surfactant, co-surfactants and Ketoprofen were prepared. In all formulations, the percent of surfactants, as well as oil, was varied while the amount of Ketoprofen kept constant. Solubility studies were conducted to select the oil, surfactant and cosurfactant. Phase diagrams were constructed using the aqueous phase titration method. Formulations were selected from the phase diagrams. The prepared nanoemulsions were subjected to different thermodynamic stability tests. Results: Following optimization, the F7 formula (10% oil, 3:1 surfactant to co-surfactant) was thermodynamically stable, with a droplet size of 105 nm and a zeta potential of-26.21 mV. In vitro release study showed that the drug release pattern from formulations F5, F6, F7, F8, F9 and F10 was higher than that of F1, F2, F3 and F4. Conclusion: The present work demonstrates that the nanoemulsion is a promising drug delivery system approach for the enhancement of solubility and dissolution rate of Ketoprofen.
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