Prolonged intragastric drug delivery mediated by Eudragit® E-carrageenan polyelectrolyte matrix tablets.

Interpolyelectrolyte (IPE) complexation between carrageenan (CG) and Eudragit E (EE) was studied in 0.1 M HCl and was used to develop floating matrix tablets aimed to prolong gastric-residence time and sustain delivery of the loaded drug. The optimum EE/CG IPE complexation weight ratio (0.6) was determined in 0.1 M HCl using apparent viscosity measurements. The IPE complex was characterized by Fourier transform infrared spectroscopy and differential scanning calorimetry. Metronidazole matrix tablets were prepared by direct compression using EE, CG, or hybrid EE/CG with ratio optimal for IPE complexation. Corresponding effervescent tablets were prepared by including Na bicarbonate as an effervescent agent. Tablets were evaluated for in vitro buoyancy and drug release in 0.1 M HCl. Both CG and EE-CG effervescent matrices (1:2 drug to polymer weight ratio, 60 mg Na bicarbonate) achieved fast and prolonged floating with floating lag times less than 30 s and floating duration of more than 10 h. The corresponding EE effervescent matrices showed delayed floating and rapid drug release, and completely dissolved after 3 h of dissolution. CG matrices showed an initial burst drug release (48.3±5.0% at 1 h) followed by slow drug release over 8 h. EE-CG matrices exhibited sustained drug release in almost zero-order manner for 10 h (68.2±6.6%). The dissolution data of these matrices were fitted to different dissolution models. It was found that drug release followed zero-order kinetics and was controlled by the superposition of the diffusion and erosion.

A Validated RP HPLC-PAD Method for the Determination of Hederacoside C in Ivy-Thyme Cough Syrup.

A simple reversed phase high-performance liquid chromatographic (RP-HPLC) method coupled with a photodiode array detector (PAD) has been developed and validated for the analysis of hederacoside C, the marker of ivy plant, in Ivy-Thyme cough syrup. Separation of hederacoside C was achieved using a Phenomenex-Gemini C18 column isothermally at 40°C. A mobile phase system constituted of solvent A (water: acetonitrile: orthophosphoric acid (85%), 860 : 140 : 2 v/v) and solvent B (acetonitrile: orthophosphoric acid (85%), 998 : 2 v/v) was used, at gradient conditions, at a flow rate of 1.5 mL/min. Analysis was performed using UV-detection (205 nm). The method was linear over the range (0.03-0.15) mg/mL of hederacoside C (r = 0.9992). Repeatability and intermediate precision were acceptable (RSD <2%). Limits of detection (LOD) and quantitation (LOQ) were 0.011 and 0.032 mg/mL, respectively. Percentage recovery was found to lie between 99.69% and 100.90% (RSD <2%). The method was also proved to be specific (peak-purity coefficient = 0.996).

Sodium mefenamate as a solution for the formulation and dissolution problems of mefenamic acid.

Sodium salt formation of mefenamic acid (MA) was studied as a way to solve the formulation and dissolution problems of MA. For this purpose, sodium salt of mefenamic acid (Na-MA) was prepared by reacting MA powder with equimolar sodium hydroxide in an aqueous phase, and consequently, Na-MA solution was obtained. The resultant solution was lyophilized and Na-MA powder was collected. The salt formation was confirmed by the results of fourier transformation-infrared (FTIR) spectroscopy and differential scanning calorimetry (DSC) studies on Na-MA powder in comparison to MA powder. Na-MA powder was assessed for direct compressibility, in comparison to MA powder, when formulated as a mixture with minimum amount of Avicel((R)) pH 101 and then compressed into tablets using a hydraulic tablet press. Na-MA tablets exhibited satisfactory hardness and friability, and did not show capping or lamination. On the other hand, some MA tablets showed capping or lamination upon compression and all the tested MA tablets for friability capped. Na-MA tablets were also studied for drug dissolution, in comparison to MA tablets, in water, a pH 7.4 phosphate buffer, and a pH 7.4 phosphate buffer after soaking in 0.1 m HCl. Under these different dissolution conditions, Na-MA tablets showed much higher dissolution rate and extent than MA tablets. The results of the study suggested that Na-MA can be considered as a solution form for the formulation and dissolution problems of MA.