High loading of gentamicin in bioadhesive PVM/MA nanostructured microparticles using compressed carbon-dioxide.

PURPOSE: To investigate, for the first time, the viability of compressed antisolvent methodologies for the preparation of drug-loaded particles of the biodegradable and bioadhesive polymer poly (methyl vinyl ether-co-maleic anhydride) (PVM/MA), utilizing gentamicin (Gm) as a model drug. METHODS: Precipitation with a Compressed Antisolvent (PCA) method was used for the preparation of PVM/MA particles loaded with gentamicin. Before encapsulation, gentamicin was modified into a hydrophobic complex, GmAOT, by exchanging its sulphate ions with an anionic surfactant. GmAOT:PVM/MA composites were fully characterized in terms of size, morphology, composition, drug distribution, phase composition, in vitro activity and drug release. RESULTS: Homogeneous nanostructured microparticles of PVM/MA loaded with high and uniformly distributed quantities of GmAOT were obtained by PCA. The drug loading factors could be tuned at will, improving up to ten times the loadings obtained by other precipitation techniques. Gentamicin retained its bioactivity after being processed, and, according to its release profiles, after an initial burst it experienced a sustained release over 30 days. CONCLUSIONS: Compressed antisolvent methods are suitable technologies for the one-step preparation of highly loaded nanostructured PVM/MA matrices with promising application in the delivery of low bioavailable drugs.

Liposomes and other vesicular systems: structural characteristics, methods of preparation, and use in nanomedicine.

Vesicular systems, especially liposomes, have generated a great deal of interest as intelligent materials for the delivery of bioactive molecules since they can be used as sensitive containers that respond to external stimuli, such as pressure, pH, temperature, or concentration changes in the medium, triggering modifications in their supramolecular structure. The control of the nanostructure-particle size and size distribution, membrane morphology, and supramolecular organization-of these self-assembled systems is of profound importance for their application in drug delivery and the discovery of new nanomedicines. This chapter will describe the chemical structure of vesicles and their pharmacological properties, conventional and new vesicle preparation methods and structural characterization, as well as their use in the rational design and fabrication of nanomedicines.

Preparation of uniform rich cholesterol unilamellar nanovesicles using CO2-expanded solvents.

Nanoscopic and uniform unilamellar vesicles, rich in cholesterol, have been prepared by a new procedure, named "DELOS-SUSP", which is based on the depressurization of a cholesterol solution in CO2-expanded acetone into an aqueous solution containing a surfactant. The CO2 is used here as a cosolvent medium, allowing the straightforward preparation of vesicular systems with controlled size distribution, uniform shape, and stability unachievable by conventional mixing technologies. The resulting nanoscopic vesicular systems dispersed in water were characterized using dynamic light scattering, zeta potential, turbidity, and cryogenic transmission electron microscopy. The influence of operational parameters of this new methodology on the physicochemical characteristics of the vesicular systems is also reported.