Drug loading of polymeric micelles.

PURPOSE: To gain mechanistic insights into drug loading and lyophilization of polymeric micelles. METHODS: PEGylated poly-4-(vinylpyridine) micelles were loaded with dexamethasone. Three different methods were applied and compared: O/W emulsion, direct dialysis, cosolvent evaporation. Micellar dispersions with the highest drug load were lyophilized with varying lyoprotectors: sucrose, trehalose, maltose, a polyvinylpyrrolidine derivative, and ß-cyclodextrin derivatives. For comparison, other PEGylated block copolymer micelles (PEGylated polylactic acid, polylactic acid-co-glycolic acid, polycaprolactone) were freeze-dried. RESULTS: Drug loading via direct dialysis from acetone was a less effective loading method which led to dexamethasone loads <2% w/w. O/W emulsion technique from dichlormethane increased drug load up to ~13% w/w; optimized cosolvent evaporation increased load up to ~19% w/w. An important step for cosolvent evaporation was solubility screen of the drug prior to preparation. Loading was maintained upon lyophilization with ß-cyclodextrins which proved to be versatile stabilizers for other block copolymer micelles. CONCLUSION: Careful solvent selection prior to cosolvent evaporation was a beneficial approach to load hydrophobic drugs into polymeric micelles. Moreover, ß-cyclodextrins could be used as versatile lyoprotectors for these micelles.

Analysis of immediate stress mechanisms upon injection of polymeric micelles and related colloidal drug carriers: implications on drug targeting.

Polymeric micelles are ideal carriers for solubilization and targeting applications using hydrophobic drugs. Stability of colloidal aggregates upon injection into the bloodstream is mandatory to maintain the drugs' targeting potential and to influence pharmacokinetics. In this review we analyzed and discussed the most relevant stress mechanisms that polymeric micelles and related colloidal carriers encounter upon injection, including (1) dilution, (2) interactions with blood components, and (3) immunological responses of the body. In detail we analyzed the opsonin-dysopsonin hypothesis that points at a connection between a particles' protein-corona and its tissue accumulation by the enhanced permeability and retention (EPR) effect. In the established theory, size is seen as a necessary condition to reach nanoparticle accumulation in disease modified tissue. There is, however, mounting evidence of other sufficient conditions (e.g., particle charge, receptor recognition of proteins adsorbed onto particle surfaces) triggering nanoparticle extravasation by active mechanisms. In conclusion, the analyzed stress mechanisms are directly responsible for in vivo success or failure of the site-specific delivery with colloidal carrier systems.

Comparative investigations on in vitro serum stability of polymeric micelle formulations.

PURPOSE: Stability of polymeric micelles upon injection is essential for a drug delivery system but is not fully understood. We optimized an analytical test allowing quantification of micellar stability in biofluids and applied it to a variety of block copolymer micelles with different hydrophobic block architechtures. METHODS: Polymeric micelles were prepared from four different polymers and investigated via encapsulation of two fluorescent dyes. Samples were incubated in human serum; changes in Foerster Resonance Energy Transfer (FRET) were recorded as a function of time. This fluorescence-based approach was supported semi-quantitatively by results from Asymmetrical Flow Field-Flow-Fractionation (AF4). RESULTS: After incubation experiments, micellar stability was determined by calculation of two stability-indicating parameters: residual micellar fractions (RMFs) and in vitro serum half-lives. Both parameters showed that PEG-PVPy micelles rapidly destabilized after 3 h (RMF < 45%), whereas PEG-PLA, PEG-PLGA and PEG-PCL micelles were far more stable (RMFs 65 to 98%). CONCLUSION: This FRET-based assay is a valuable tool in evaluating and screening serum stability of polymeric micelles and revealed low serum stability of PEG-PVPy micelles compared to polyester-based micelles.

Self-assembly of ternary insulin-polyethylenimine (PEI)-DNA nanoparticles for enhanced gene delivery and expression in alveolar epithelial cells.

Enhancing gene delivery and expression in alveolar epithelial cells could offer the opportunity for the treatment of acquired and inherited lung diseases. Here, we show that particle adsorption of human insulin (INS) is capable of increasing plasmid DNA (pDNA) delivery from polyethylenimine (PEI) nanoparticles specifically in alveolar epithelial cells. INS receptors were predominantly detected on alveolar but not on bronchial epithelial cells. INS was adsorbed on the surface of PEI gene vectors by spontaneous self-assembly resulting in ternary PEI-pDNA-INS nanoparticles. Surface adsorption was confirmed by particle size, surface charge, and fluorescence resonance energy transfer (FRET) measurements. INS adsorption significantly increased gene expression of PEI-pDNA nanoparticles up to 16-fold on alveolar epithelial cells but not on bronchial epithelial cells. This increased gene expression was INS receptor specific. Our results demonstrate that targeting INS receptor for gene delivery in alveolar epithelial cells represents a promising approach for enhanced gene delivery and expression.

Dry powder aerosols of polyethylenimine (PEI)-based gene vectors mediate efficient gene delivery to the lung.

Aerosol gene delivery holds great therapeutical potential for many inherited and acquired pulmonary diseases. The physical instability of aqueous suspensions of non-viral vector complexes is a major limitation for their successful application. In this study, we investigated dry powder aerosols as novel gene vector formulations for gene transfer in vitro and murine lungs in vivo. Lyophilization was used to produce dry powder cakes followed by powderization to produce dry powder aerosols. Different sugars, namely lactose, sucrose and trehalose, were tested as lyoprotectants for gene delivery complexes consisting of branched polyethylenimine 25 kDa and plasmid DNA. Biophysical particle characterization demonstrated that lyophilization and powderization in the presence of lyoprotectants were well tolerated. In vitro transfection efficiency remained unaffected by the choice of lyoprotectant and subsequent lyophilization and/or powderization. In vivo screening of powderized samples, by applying the powder with an insufflator, resulted in highest gene expression with lactose as lyoprotectant. Delivering a plasmid coding for murine erythropoietin together with lactose as lyoprotectant resulted in increased blood hematocrit values post application thereby demonstrating the potential of dry powder aerosol as a promising method for pulmonary gene delivery.