Effect of gadolinium incorporation on the structure and luminescence properties of niobium-based materials.

In this work, we have investigated how the concentration of Gd3+ ions affects the structural and luminescent properties of niobium oxide-based matrices doped with Eu3+ ions obtained by the adapted non-hydrolytic sol-gel route. X-ray diffractograms revealed that increasing the concentration of Gd3+ ions favored the onset of the Gd2O3 structure decreasing the GdNbO4 phase. The excitation spectra (λ em = 613 nm) presented bands corresponding to the 7F0 â†’ 5LJ transitions (L = D, G, and L, where J = 0-7), attributed to the Eu3+ ions, and a broad band at 270 nm, assigned to the charge transfer of the [Formula: see text] group. The emission spectra contained bands refer to the 5D0 â†’ 7FJ internal configuration transitions (J = 0, 1, 2, 3, and 4). Finally, the CIE chromaticity coordinates met the standard for the color red established by the National Television Standard Committee (NTSC).

Structural properties induced by the composition of biocompatible phospholipid-based microemulsion and amphotericin B association.

Anionic microemulsions (MEs) containing soya phosphatidylcholine, Tween-20, sodium oleate as surfactant, and cholesterol as oil phase were investigated as drug carriers for amphotericin B. Depending on the composition of the microemulsion, various structures, which differently interact with amphotericin B, can be formed. The nanostructured systems were characterized by photon correlation spectroscopy, rheological behavior, and polarized light microscopy. The results reveal that the droplet diameters increased with amphotericin B incorporation for all ranges of surfactant and oil phase. For both amphotericin B-unloaded and amphotericin B-loaded microemulsions, the profile of the oil droplet diameter decreased with increasing the surfactant concentration, demonstrating the stabilizing effect of the surfactant. The increase in the oil phase proportions led to the growth of the droplet diameter, clearly demonstrating the limit of the surfactant organization in the oil-water interface. The amphotericim B incorporation into microemulsion increased with the fraction volume of the oil phase and the surfactant concentration reaching a plateau at high contents. This profile could be quantitatively analyzed by the framework of the pseudo-phase model that considers the amphotericim B distribution between the oil and the aqueous phases. The rheological analysis showed a pseudoplastic behavior with little thixotropic characteristic. Under polarized light, the system of interest showed a dark background characteristic of dispersed droplets. However, for both amphotericim B-loaded and amphotericim B unloaded microemulsions, the increase in the O/S ratio led to the formation of ordered structures with lamellar arrangements.