To improve its dissolution, ibuprofen solid dispersions (SDs) were prepared in a relatively easy and simple manner, characterized by scanning electron microscopy (SEM), differential scanning calorimetry (DSC) and Fourier transform infrared spectroscopy (FT-IR), and evaluated for solubility, in-vitro drug release and oral bioavailability of ibuprofen in rats. Loss of individual surface properties during melting and resolidification as revealed by SEM micrographs indicated the formation of effective SDs. Absence or shifting towards the lower melting temperature of the drug peak in SDs and physical mixtures in DSC study indicated the possibilities of drug–polymer interactions. FT-IR spectra showed the presence of drug crystalline in SDs. Quicker release of ibuprofen from SDs in rat intestine resulted in a significant increase in AUC and Cmax, and a significant decrease in Tmax over pure ibuprofen. Preliminary results from this study suggested that the preparation of fast dissolving ibuprofen SDs by low temperature melting method using polyethylene glycol 4000 (PEG 4000) as a meltable hydrophilic polymer carrier could be a promising approach to improve solubility, dissolution and absorption rate of ibuprofen.
To develop a valsartan-loaded gelatin microcapsule using hydroxypropylmethylcellulose (HPMC) as a stabilizer, which could improve the physical stability and bioavailability of valsartan, the gelatin microcapsules were prepared with various ratios of gelatin and HPMC using a spray-drying technique. Their solubility, dissolution, thermal characteristics, crystallinity, and physical stability were investigated. The bioavailability of drug in valsartan-loaded microcapsule was then evaluated compared to drug powder and commercial product in rats. The microcapsule with gelatin and/or HPMC enhanced the solubility and dissolution of drug compared to valsartan powder. Among the formulations tested, the valsartan-loaded gelatin microcapsule at the weight ratio of valsartan/gelatin/HPMC of 1/2/1 gave excellent drug solubility of approximately 2 microg/ml and dissolution of 70% at 1 h. The crystal state of valsartan in this microcapsule was changed from crystalline to amorphous form during the spray-drying process and maintained as an amorphous form at 40 degrees C for at least 3 months, indicating that it was physically stable. HPMC in this microcapsule could inhibit the recrystallization, resulting in stabilizing the amorphous form of valsartan. Furthermore, it improved the oral bioavailability of valsartan compared to valsartan powder and gave the similar AUC, C(max), and T(max) values to commercial product, suggesting that it was bioequivalent to commercial product in rats. Thus, the gelatin microcapsule with HPMC would be a more effective and stable oral delivery system of poorly water-soluble valsartan.
Objectives The aim of this study was to develop a novel itraconazole-loaded gelatin microcapsule without ethanol with enhanced oral bioavailability. Methods Various gelatin microcapsules were prepared using a spray-drying technique. Their physicochemical properties, dissolution, characteristics and pharmacokinetics in rats were evaluated and compared with those of a commercial product. Key findings The gelatin microcapsule at a weight ratio for itraconazole/gelatin/citric acid of 1 : 3 : 0.3 was spherical in shape with a smooth surface and inner hole, and gave a maximum drug solubility of about 700 μg/ml. The gelatin microcapsule dramatically increased the initial dissolution rate of itraconazole compared with a commercial product in simulated gastric fluids (pH 1.2). Moreover, at the same dose as the commercial product, it gave significantly higher initial plasma concentrations, Cmax and AUC of itraconazole in rats than did the commercial product, indicating that providing the drug in the gelatin microcapsule caused enhanced absorption in rats. At half dose, it gave similar AUC, Cmax and Tmax values to the commercial product, suggesting that it was bioequivalent to the commercial product in rats. Conclusions The itraconazole-loaded gelatin microcapsule without ethanol developed using a spray-drying technique at half the dose of the commercial product can deliver itraconazole in a pattern that allows fast absorption in the initial phase, making it bioequivalent to the commercial product.
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