M. Callewaert

Hydrogels incorporating GdDOTA: towards highly efficient dual T1/T2 MRI contrast agents.

Do not tumble dry: Gadolinium-DOTA encapsulated into polysaccharide nanoparticles (GdDOTA NPs) exhibited high relaxivity (r(1) =101.7 s(-1) mM(-1) per Gd(3+) ion at 37 °C and 20 MHz). This high relaxation rate is due to efficient Gd loading, reduced tumbling of the Gd complex, and the hydrogel nature of the nanoparticles. The efficacy of the nanoparticles as a T(1)/T(2) dual-mode contrast agent was studied in C6 cells.

Etoposide encapsulation in surface-modified poly(lactide-co-glycolide) nanoparticles strongly enhances glioma antitumor efficiency†

Etoposide (VP-16) is a hydrophobic anticancer agent inhibiting Topoisomerase II, commonly used in pediatric brain chemotherapeutic schemes as mildly toxic. Unfortunately, despite its appropriate solubilization in vehicle solvents, its poor bioavailability and limited passage of the blood-brain barrier concur to disappointing results requiring the development of new delivery system forms. In this study, etoposide formulated as a parenteral injectable solution (Teva®) was loaded into all-biocompatible poly(lactide-co-glycolide) (PLGA) or PLGA/P188-blended nanoparticles (size 110-130 nm) using a fully biocompatible nanoprecipitation technique. The presence of coprecipitated P188 on encapsulation efficacies and in vitro drug release was investigated. Drug encapsulation was determined using HPLC. Inflammatory response was checked by FACS analysis on human monocytes. Cytotoxic activity of the various simple (Teva®) or double (Teva®-loaded NPs) formulations was studied on the murine C6 and F98 cell lines. Obtained results suggest that, although noninflammatory neither nontoxic by themselves, the use of PLGA and PLGA/P188 nanoencapsulations over pre-existing etoposide formulation could induce a greatly improved cytotoxic activity. This approach demonstrated a promising perspective for parenteral delivery of VP16 and potential development of a therapeutic entity.

Tuning the composition of biocompatible Gd nanohydrogels to achieve hypersensitive dual T1/T2 MRI contrast agents

A series of hydrogel nanoparticles incorporating MRI contrast agents (GdDOTP and MS325) as potential cross-linkers were elaborated by an easy and robust ionotropic gelation process. By this process, high Gd loadings were obtained (between 1.8 and 14.5 × 104 Gd centres per NP). By tuning the cross-linker ionization degree and the nature of the polymer matrix it was possible to boost the r1 relaxivity per Gd centre up to 22-fold. The greatest gains in relaxivity were observed for nanogels for which the polymer matrix was constituted of chitosan and hyaluronan. Relaxivities per Gd centre as high as 100 s-1 mM-1 at 30 MHz can be reached, which highlighted the fact that molecular motion of the Gd chelate was effectively restricted and water access to the inner core of these nanogels was not limited.

Serum albumin-alginate coated microspheres: role of the inner gel in binding and release of the KRFK peptide.

In continuation with our previous study using fluorescein-isothiocyanate (FITC)-Lys-Arg-Phe-Lys (KRFK) peptide, the aim of this work was to study the interaction of the unlabelled KRFK with calcium alginate gel microspheres coated with a serum albumin (HSA)-alginate membrane prepared using a transacylation method. Coated microspheres were prepared with two main sizes and two gel strengths. Control microspheres made of cross-linked alginate-HSA without calcium alginate gel were also prepared. A series of loading and release assays conducted with methylene blue showed the requirement of inner gel for binding the cationic molecule. Release experiments were performed in different media using unlabelled KRFK and coated microspheres. A plateau was reached within 1h, in contrast with the slow release of the FITC-peptide observed in our previous work. This discrepancy was attributed to modified properties of the labelled peptide. Adsorption assays of KRFK on coated microspheres were performed in the presence of growing concentrations of NaCl or imidazole. The ions were able to displace the peptide from the particles, which demonstrated ionic interactions, probably involving carboxylate groups of alginate. Adsorption isotherms showed that gel strength influenced affinity (4x10(5) L/mol or 8x10(5) L/mol for gelation with 5% or 20% CaCl(2), respectively). Binding site number doubled (from 2.6x10(-7) mol/mg to more than 5x10(-7) mol/mg) when microsphere size decreased from 450 microm to 100 microm. Binding sites were assumed to be located in the gel underneath the membrane.

Optimised NSAIDs-loaded Biocompatible Nanoparticles

In this formulation study, biocompatible non steroidal anti-inflammatory (NSAIDs)-loaded nanoparticles were designed as models to be further integrated in a prosthesis surface functionalization. A modified spontaneous emulsion-solvent diffusion methodology was used to produce drug-loaded PLGA nanoparticles without any purification or solvent evaporation requirements. Formulation parameters, such as lactide/glycolide ratio, polymer concentration, solvent/non solvent ratio and non solvent phase, as well as the non ionic tensioactive P188 co-precipitation composition were systematically explored. The optimized formulation (mean size: 145 nm, surface charge: −13 mV) was employed to encapsulate various amounts of NSAIDs in a simple and scalable manner. The drug release was characterized in vitro by a complete release for 48 h. These results encourage upcoming preliminary steps for in vivo experiments of prosthesis surface functionalization.

Synthesis and Characterization of PEGylated and Fluorinated Chitosans: Application to the Synthesis of Targeted Nanoparticles for Drug Delivery

To synthesize chitosan nanoparticles (CS NPs), ionic gelation is a very attractive method. It relies on the spontaneous supramolecular assembly of cationic CS with anionic compounds, which leads to nanohydrogels. To extend ionic gelation to functionalized CS, the assessment of CS degree of substitution (DSCS) is a key step. In this paper, we have developed a hyphenated strategy for functionalized CS characterization, based upon 1H, DOSY and, when relevant, 1D diffusion-filtered 19F NMR spectroscopies. For that, we have synthesized two series of water-soluble CS via amidation of CS amino groups with mPEG2000-COOH or fluorinated synthons (TFB-COOH). The aforementioned NMR techniques helped to discriminate between ungrafted and grafted synthons and finally to determine DSCS. According to DSCS values, the selection of CS-mPEG2000 or CS-TFB copolymers can be made to obtain, in the presence of hyaluronic acid (HA) and tripolyphosphate (TPP), CS-mPEG2000-TPP/HA or CS-TFB-TPP/HA nanohydrogels suitable for drug delivery.

Biocompatibility of Gd-Loaded Chitosan-Hyaluronic Acid Nanogels as Contrast Agents for Magnetic Resonance Cancer Imaging

Although the research on nanogels incorporating Gd chelates for theranostic applications has grown exponentially in recent years, knowledge about their biocompatibility is limited. We compared the biocompatibility of Gd-loaded hyaluronic acid-chitosan-based nanogels (GdCA⊂CS-TPP/HA) with two chitosan concentrations (2.5 and 1.5 mg·mL−1 respectively) using SVEC4-10 murine lymph node endothelial cells. The sulforhodamine B method and released lactate dehydrogenase (LDH) activity were used as cell viability tests. Reactive oxygen species (ROS), reduced glutathione (GSH) and malondialdehyde (MDA) were measured by spectrophotometric and fluorimetric methods. Nrf-2 protein expression was evaluated by Western blot analysis and genotoxicity by alkaline comet assay. After 24 h, the cells viability was not affected by all types and doses of nanogels. The increase of ROS induced a low decrease of GSH concentration and a time-dependent raise of MDA one was produced by citric GdDOTA⊂CS-TPP/HA with a chitosan concentration of 1.5 mg·mL−1, at the highest dose applied. None of the tested nanogels induced changes in Nrf-2 protein expression. A slight but significant genotoxic effect was caused only by citric GdDOTA⊂CS-TPP/HA where CS concentration was 1.5 mg·mL−1. Our results showed a better biocompatibility with lymph node endothelial cells for Gd-loaded hyaluronic acid-chitosan based nanogels with a concentration in chitosan of 2.5 mg·mL−1.