F. Quaglia

Influence of the co-encapsulation of different non-ionic surfactants on the properties of PLGA insulin-loaded microspheres

The aim of this work was to produce insulin-loaded microspheres allowing the preservation of peptide stability during both particle processing and insulin release. Our strategy was to combine the concepts of using surfactants to improve insulin stability while optimising overall microsphere characteristics such as size, morphology, peptide loading and release. Bovine insulin was encapsulated within poly(lactide-co-glycolide) (PLGA 50:50, Resomer RG504H) microspheres by the multiple emulsion-solvent evaporation technique. Microspheres were prepared by adding to the primary emulsion three non-ionic surfactants, poloxamer 188, polysorbate 20 and sorbitan monooleate 80, at different concentrations (1.5 and 3. 0% w/v). The presence of surfactants was found to decrease the mean diameter and to affect the morphology of the microspheres. Insulin encapsulation efficiency was reduced in the presence of surfactants and especially for sorbitan monooleate 80, in a concentration-dependent mode. The influence of the surfactants on the interactions between insulin and PLGA together with the primary emulsion stability were found to be the major determinants of insulin encapsulation. The release of insulin from microspheres was biphasic, showing an initial burst effect followed by a near zero-order release for all the batches prepared. The initial burst was related to the presence of insulin molecules located onto or near to the microsphere surface. In the presence of surfactants, a faster insulin release with respect to microspheres encapsulating insulin alone was observed. Insulin stability within microspheres after processing, storage and release was evaluated by reversed phase- and size-exclusion-HPLC. The analysis of microsphere content after processing and 6 months of storage showed that insulin did not undergo any chemical modification within microspheres. On the contrary, during the period of sustained release insulin was transformed in a high-molecular weight product, the amount of which was related to the surfactant used. In conclusion, polysorbate 20 at 3% w/v concentration was the most effective in giving regular shaped particles with both good insulin loading and slow release, and limiting insulin modification within microspheres.

Biodegradable core-shell nanoassemblies for the delivery of docetaxel and Zn(II)-phthalocyanine inspired by combination therapy for cancer.

Combination therapies for cancer aim to exploit either additive or synergistic effects arising from the action of two species with the final goal to maximize the therapeutic efficacy. In this work, we develop multifunctional nanoparticles (NPs) for co-delivery of the conventional anticancer drug docetaxel (DTX) and the second generation photosensitizer zinc-phthalocyanine (ZnPc) as potential dual carrier system for the combination of chemotherapy and photodynamic therapy (PDT). Biodegradable and amphiphilic block copolymers based on poly(ε-caprolactone) (PCL=B) and poly(ethylene oxide) (PEO=A), with AB and ABA architectures, were assembled in core-shell NPs and loaded with both DTX and ZnPc employing the melting/sonication method. Hydrodynamic diameters within the range 60-100nm and low polydispersity indexes were obtained. Zeta potential was negative for all the formulations and unaffected by drug encapsulation. Concerning drug loading ability of NPs, the entrapment efficiency was related to initial ZnPc/DTX ratio. Steady-stationary and time-resolved emission fluorescence measurements pointed out the embedding of monomeric ZnPc in the NPs, excluding the presence of ZnPc self-supramolecular oligomers. The release of DTX was biphasic whereas ZnPc remained mainly associated with NPs. Singlet oxygen generation was observed when ZnPc-loaded NPs were irradiated at 610nm within a 45min time range, despite that ZnPc was not released in the medium. Stability of NPs in the presence of serum proteins and plasma was excellent and no toxicity toward red blood cells was found. NPs cytotoxicity was evaluated in HeLa cells irradiated for 30min with a halogen lamp. After 72h, viability of cells treated with ZnPc/DTX-loaded NPs strongly decreased as compared to NPs loaded only with DTX, thus showing a combined effect of both DTX and ZnPc. Superior antitumor activity of ZnPc/DTX-loaded NPs as compared to DTX-loaded NPs was confirmed in an animal model of orthotopic amelanotic melanoma, thus pointing to the application of PEO-PCL NPs in the combined chemo-photodynamic therapy of cancer.

Bioactivation of collagen matrices through sustained VEGF release from PLGA microspheres.

The success of any tissue engineering implant relies upon prompt vascularization of the cellular construct and, hence, on the ability of the scaffold to broadcast specific activation of host endothelium and guide vessel ingrowth. Vascular endothelial growth factor (VEGF) is a potent angiogenic stimulator, and if released in a controlled manner it may enhance and guide scaffold vascularization. Therefore, the aim of this work was to realize a scaffold with integrated depots able to release VEGF in a controlled rate and assess the ability of this scaffold to promote angiogenesis. VEGF-loaded poly(lactide-co-glycolide) (PLGA) microspheres were produced and included in a collagen scaffold. The release of VEGF from microspheres was tailored to be sustained over several weeks and occurred at a rate of approximately 0.6 ng/day per mg of microspheres. It was found that collagen scaffolds bioactivated with VEGF-loaded microspheres strongly enhanced endothelial cell activation and vascular sprouting both in vitro and in vivo as compared with a collagen scaffold bioactivated with free VEGF. This report demonstrates that by finely tuning VEGF release rate within a polymeric scaffold, sprouting of angiogenic vessels can be guided within the scaffolds interstices as well as broadcasted from the host tissues.

Chromatographic indices determined on an immobilized artificial membrane (IAM) column as descriptors of lipophilic and polar interactions of 4-phenyldihydropyridine calcium-channel blockers with biomembranes†

Summary A set of nine 4-phenyldihydropyridine (DHP) calcium-channel blockers including both ionizable and unionizable molecules has been examined. The chromatographic parameters log k ′ have been determined by HPLC on an immobilized artificial membrane (IAM) column which is a solid-phase model of fluid membranes. The influence of different percentages of organic modifier and ionic strength of the eluent on the chromatographic behaviour has been studied in order to identify the best experimental conditions modelling the in vivo interaction with phospholipids. As different ranking orders can occur under different experimental conditions, log k ′ values extrapolated to 100% aqueous phase (log k IAM w ) have been determined. Moreover, n -octanol/buffer partition data at pH 7.4 and 12.5 (log D 7.4 and log P ) and chromatographic data on a hydrocarbon HPLC stationary phase (log k w ODS ) have been measured. Comparative studies between the experimental data, obtained for the different systems, have shown that the IAM-derived scale is distinct from the one obtained by ‘conventional’ lipophilic indices, because of the particular behaviour of the basic DHPs. Moreover, only IAM parameters are good descriptors of the strong interactions of the basic DHPs with biomembranes. In fact, the chromatography of neutral compounds is mainly lipophilicity dependent while a ‘dual’ mechanism, partition and ion-exchange, operates for basic analogues. In this case the lipophilic component is insensitive to the protonation of the basic function. Finally, receptor binding values from rat cortical brain preparations successfully correlate with log k w IAM . Hence, the biomembrane affinity of DHPs appears to be a critical factor for access to their receptor site.

Biodegradable microparticles for the controlled delivery of oligonucleotides

Microspheres allowing the controlled release of the model oligonucleotide pdT16 were designed. The oligonucleotide, alone or associated with polyethylenimine (PEI) at different nitrogen/phosphate ratios, was encapsulated within poly(lactide-co-glycolide) microspheres prepared by the multiple emulsion-solvent evaporation technique. The introduction of PEI in the internal aqueous phase resulted in a strong increase of the oligonucleotide encapsulation efficiency. PEI affected also microsphere morphology inducing the formation of very porous particles and yielding to an accelerated release of pdT16. However, when incubated with HeLa cells, microspheres encapsulating pdT16/PEI complexes allowed an improvement of the intracellular penetration of the released oligonucleotide. The developed strategy appears to be a very interesting tool to obtain a sustained release system for oligonucleotides with an efficient cellular delivery.

Spray-by-spray in situ cross-linking alginate hydrogels delivering a tea tree oil microemulsion

In this paper we propose an in situ forming ionically cross-linked alginate (Alg) hydrogel delivering a Tea Tree Oil microemulsion (MeTTO) and potentially useful as an advanced dressing for infected wounds. Alg hydrogels were prepared by a spray-by-spray deposition method with the aim to minimize the discomforts during application. From pseudoternary phase diagrams, it was found that proper combination of TTO, water, polysorbate 80 and ethanol gave stable spherical MeTTO with good antimicrobial activity. On this basis, MeTTO at 20% TTO was selected for further inclusion in an Alg hydrogel prepared by alternating sprays of Alg/MeTTO and calcium chloride solutions. Homogeneous dispersion of MeTTO inside cross-linked Alg was assessed by different macroscopic and microscopic methods demonstrating the superior propensity of MeTTO to be integrated in the water-based hydrogel as compared to TTO. Antimicrobial effect of Alg/MeTTO hydrogels on Escherichia Coli strains was remarkable, highlighting the potential of the system as bioactive wound dressing.

In vitro and in vivo evaluation of terpenoid esters of indomethacin as dermal prodrugs

Abstract Indomethacin terpenoids esters (1–4) were synthesized and assessed both in vitro and in vivo as indomethacin dermal prodrugs. Esters 1–4 showed high lipophilicity, poor water solubility, good stability in hydro-alcoholic medium (ethanol/water 1:1) and rapid enzymatic cleavage. Results from in vitro percutaneous absorption studies showed that esters 1 and 2 slightly increased the cumulative uptake of indomethacin through excised human skin compared with the parent drug. In vivo results, using methyl nicotinate (MN) induced erythema as an inflammatory model in human volunteers, showed an interesting delayed and sustained activity of ester 1 compared with the parent drugs.

Functional characterization of biodegradable nanoparticles as antigen delivery system

BackgroundPeptide based vaccines may suffer from limited stability and inefficient delivery to professional antigen-presenting cells (APCs), such as dendritic cells (DCs). In order to overcome such limitations, several types of biodegradable nanoparticles (NPs) have been developed as carrier system for antigens. The present study describes for the first time the extensive biological characterization of cationic NPs made of poly (D,L-lactide-co-glycolide) (PLGA) and polyethylenimine (PLGA/PEI) as delivery system for protein/peptide antigens, with potential in therapeutic cancer vaccine development.ResultsFlow cytometry as well as confocal laser scanning microscopy (CLSM) showed that PLGA/PEI NPs are more readily taken up than PLGA NPs by both human CD14+ monocytes and mouse Hepa 1–6 hepatoma cell line. No signs of toxicity were observed in either cellular setting. Sequential image acquisition by TEM showed an intracellular apical localization for PLGA NPs and a perinuclear localization for PLGA/PEI NPs. Both NPs showed a clathrin-dependent as well as a caveolin-dependent internalization pathway and, once in the cells, they formed multivesicular endosomes (MVE). Finally, an ex vivo priming experiment showed that PLGA/PEI NPs are comparable to PLGA NPs in delivering a non-self antigen (i.e., ovalbumin - OVA) to immature dendritic cells (imDCs), which matured and induced autologous naïve CD4+ T cells to differentiate to memory (i.e., central memory and effector memory) cells. Such a differentiation was associated with a Th1 phenotype suggesting a downstream activation and amplification of a CD8+ T cell cytotoxic response. The same OVA antigen in a soluble form was unable to induce maturation of DCs, indicating that both NP formulations provided an intrinsic adjuvanting effect combined to efficient antigen delivery.ConclusionsOur study represents the first report on side-by-side comparison of PLGA and PLGA/PEI NPs as strategy for protein antigen delivery. PLGA/PEI NPs are superior for cellular uptake and antigen delivery as compared to PLGA NPs. Such an evidence suggests their great potential value for vaccine development, including therapeutic cancer vaccines.

Development of inhalable hyaluronan/mannitol composite dry powders for flucytosine repositioning in local therapy of lung infections.

Flucytosine (5-fluorocytosine, 5-FC) is a fluorinated analogue of cytosine currently approved for the systemic treatment of fungal infections, which has recently demonstrated a very promising antivirulence activity against the bacterial pathogen Pseudomonas aeruginosa. In this work, we propose novel inhalable hyaluronic acid (HA)/mannitol composite dry powders for repositioning 5-FC in the local treatment of lung infections, including those affecting cystic fibrosis (CF) patients. Different dry powders were produced in one-step by spray-drying. Powder composition and process conditions were selected after in depth formulation studies aimed at selecting the 5-FC/HA/mannitol formulation with convenient aerosolization properties and drug release profile in simulated lung fluids. The optimized 5-FC/HA/mannitol powder for inhalation (HyaMan_FC#3) was effectively delivered from different breath-activated dry powder inhalers (DPI) already available to CF patients. Nevertheless, the aerodynamic assessment of fine particles suggested that the developed formulation well fit with a low-resistance DPI. HyaMan_FC#3 inhibited the growth of the fungus Candida albicans and the production of the virulence factor pyoverdine by P. aeruginosa at 5-FC concentrations that did not affect the viability of both wild type (16HBE14o-) and CF (CFBE41o-) human bronchial epithelial cells. Finally, pharmacokinetics of HyaMan_FC#3 inhalation powder and 5-FC solution after intratracheal administration in rats were compared. In vivo results clearly demonstrated that, when formulated as dry powder, 5-FC levels in both bronchoalveolar lavage fluid and lung tissue were significantly higher and sustained over time as compared to those obtained with the 5-FC solution. Of note, when the same 5-FC amount was administered intravenously, no significant drug amount was found in the lung at each time point from the injection. To realize a 5-FC lung concentration similar to that obtained by using HyaMan_FC#3, a 6-fold higher dose of 5-FC should be administered intravenously. Taken together, our data demonstrate the feasibility to deliver 5-FC by the pulmonary route likely avoiding/reducing the well-known side effects associated to the high systemic 5-FC doses currently used in humans. Furthermore, our results highlight that an appropriate formulation design can improve the persistence of the drug at lungs, where microorganisms causing severe infections are located.

Controlled release of oligonucleotide/polyethyleneimine complexes from PLGA-based microspheres: potential of spray-drying technique

In this work, the potential of spray-drying technique in the production of poly(lactide-co-glycolide) (PLGA) microspheres for the delivery of oligonucleotide/polyethylenimine (ODN/PEI) complexes was assessed. PLGA microspheres, entrapping the oligodeoxythymidilate pdT16 in association with PEI at nitrogen to phosphate ratios (N/P) 15 and 40, were prepared by spray-drying different emulsions. Microparticles obtained from a w/o emulsion at 1:5 volume ratio were collapsed and displayed a mean diameter in the range of 8.3 to 10.6xa0μm. A decrease in the aqueous phase volume (1:100 w/o ratio) yielded to regular microspheres with a smaller mean diameter. The co-encapsulation of PEI affected microsphere surface charge, which was strongly positive and depended on the amount of PEI entrapped. The release profiles of pdT16/PEI were affected by PLGA employed and PEI amount co-encapsulated. Microspheres releasing pdT16/PEI complexes at constant and optimal N/P ratios were selected for in vitro studies on HeLa cells. After 24xa0h of incubation, small-size positively-charged microspheres were effectively internalized into cells and, depending on the formulation, pdT16 could be located into the nucleus.