Michèle Leonard

Influence of polymeric surfactants on the properties of drug-loaded PLA nanospheres

Abstract Different dextran derivatives containing various grafted hydrophobic groups (phenoxy, P; hexyl, C6 or decyl, C10) were synthesized and their applicability as emulsion stabilizers in the preparation of poly(lactic acid) (PLA) nanospheres by an o/w emulsion/evaporation technique was investigated. The effect of dextran modification on particle size, surface charge and stability was evaluated. Differential scanning calorimetry (DSC) studies suggested that the mechanism of interfacial adhesion between immiscible dextran and PLA chains depend on the nature of the hydrophobic grafted groups. However, all dextran layers behaved similarly in terms of stability and in preventing protein adsorption. The encapsulation of lidocaine in PLA nanoparticles was not possible when using phenoxy–dextran as an emulsion stabilizer in the preparation of particles. Conversely, particles with drug-loading varying from about 7 to 18% (w/w) were obtained in the presence of alkyl–dextrans. The polysaccharide layer at the surface of PLA particles did not significantly change the in vitro release of lidocaine, compared with that obtained with drug-loaded uncoated PLA nanoparticles. The partition coefficient of lidocaine between PLA and water and the drug diffusion in the matrix were found to control the release pattern of lidocaine from nanoparticles.

Synthesis and rheological properties of hydrogels based on amphiphilic alginate-amide derivatives

New amphiphilic derivatives of sodium alginate were prepared by covalent attachment of dodecylamine onto the polysaccharide via amide linkages at different substitution ratios, using 2-chloro-1-methylpyridinium iodide (CMPI) as coupling reagent. The aim was to limit the progressive loss of associative behaviour which occurs in the case of previously described dodecyl ester alginate derivatives due to hydrolysis of ester bonds. A series of hydrogels was obtained which differed by the amount of attached dodecyl tails. The stability and viscoelastic properties were evaluated and compared to those of hydrogels obtained with alginate esters. The observed differences were discussed in relation to the synthesis procedures. The advantages of amide links are underlined, especially with regard to long-term stability of hydrogels.

Physicochemical evaluation of PLA nanoparticles stabilized by water-soluble MPEO-PLA block copolymers.

Different water-soluble MPEO-PLA diblock copolymers with various alpha-methoxy-omega-hydroxyl polyethylene (MPEO) and poly(lactic acid) (PLA) block lengths have been synthesized. Their surface-active properties were evidenced by surface tension (water/air) measurements. In each case the surface tension leveled down above a critical polymer concentration, which was attributed to the formation of a dense polymer layer at the liquid-air interface. The applicability of copolymers as emulsion stabilizers in the preparation of PLA nanospheres by an o/w emulsion/evaporation technique was then investigated. Four copolymers presenting sufficient water solubility and good surfactive properties were used to prepare PLA nanospheres with MPEO chains firmly anchored at the particle surface. The effect of polymer concentration in emulsion on particle size and surface coverage was examined. Whatever the copolymer characteristics, it was found that the optimal concentration to obtain a large amount of MPEO at the particle surface was similar (around 2 g/l). The effect of the copolymer composition on MPEO layer characteristics and on colloidal stability was also evaluated. The conformation of MPEO blocks at the PLA particle surface is discussed in relation to the layer thickness and the surface area occupied per molecule.

Acylation of human hemoglobin with polyoxyethylene derivatives

Monomethoxypolyoxyethylene (Mw = 5000) was covalently linked to human hemoglobin via an amide bond formed between amino groups of the protein and a carboxylic group introduced onto the polymer. The conjugates thus obtained have a molecular size corresponding to that of a globular protein with a molecular weight of about 190 000. Their oxygen-binding properties depend upon the initial conformation of the hemoglobin and reaction pH: hemoglobin modified in the deoxy state exhibited a lower oxygen affinity than that modified in the oxy state, and the lower the reaction pH, the lower the oxygen affinity of polymer-linked hemoglobin. However, the affinity of modified hemoglobin is always higher than that of native hemoglobin. On the other hand, when deoxyHb was complexed with organic phosphates during the condensation reaction, the resulting conjugates exhibited oxygen-binding characteristics quite similar to those of native hemoglobin, i.e., the same oxygen affinity, modified cooperativity and the same alkaline Bohr effect. Finally, in order to decrease the oxygen affinity of hemoglobin conjugates, the polymer was coupled to deoxy hemoglobin previously covalently modified with pyridoxal phosphate. The oxygen affinity of such conjugates was in fact as low as that of the initial pyridoxylated hemoglobin.

Evaluation of intra-articular delivery of hyaluronic acid functionalized biopolymeric nanoparticles in healthy rat knees.

The aim of this study is to evaluate the toxicity of nanoparticles of poly(D,L-lactic acid) (PLA) or poly(D,L-lactic-co-glycolic acid) (PLGA) covered by chemically esterified amphiphilic hyaluronate (HA) which will be used for intra-articular injection as a drug carrier for the treatment of arthritis (RA) and/or osteoarthritis (OA). PLA and PLGA are FDA approved polymers that are already used for the preparation of nano or microparticles. HA is a natural polysaccharide already present in the articulations known to interact with the CD44 receptors of the cells (especially chondrocytes). Therefore, we can envisage that the HA covering can improve the interactions between the cells and the nanoparticles, leading to better targeting or biodistribution. The knee of healthy male rats was injected one to two times weekly, with various concentrations of nanoparticles encapsulating Dextran-FITC. The synovial membranes and the patellae were collected aseptically and histologically analyzed to assess the effects and localization of the nanocapsules in the knee joint. We did not observe significant modifications in the synovial membranes (weak hyperplasia) or patellae integrity after local administration of nanodevices into the rats. While we found some nanoparticles in the synovial membrane, none were detected in the patellae. Moreover, the histological observations for patellae were confirmed by radiosulfate intake, which depicted no decrease in proteoglycans biosynthesis in nanoparticles treated animals. Concerning the safety towards synovial membranes, we also had a look at the inflammatory response after injections of nanoparticles covered by amphiphilic HA or polyvinyl alcohol (PVA) by monitoring the mRNA expression levels of some specific early cytokines (IL-1β and TNF-α). Once again, no differences were observed between the control rats and the rats treated with nanoparticles. Considering these preliminary results obtained in healthy rats, we can establish that neither the amphiphilic HA-covered PLGA nanoparticles nor their degradation products induce major modifications of articular tissues functions, while injected into the knee of healthy rats. These results should be confirmed in OA or RA rat models, in order to confirm that nanoparticles do not worsen already altered (degenerative or inflamed) articular tissues. Once confirmed, such tuneable nanoparticles could be proposed as a safe drug delivery system for the treatment of articular disease, allowing a wide range of encapsulating molecules.

Injectable PLA-based in situ forming implants for controlled release of Ivermectin a BCS Class II drug: solvent selection based on physico-chemical characterization

In situ forming implants (ISI) prepared from biodegradable polymers such as poly(d,l-lactide) (PLA) and biocompatible solvents can be used to obtain sustained drug release after parenteral administration. The aim of this work was to study the effect of several biocompatible solvents with different physico-chemical properties on the release of ivermectin (IVM), an antiparasitic BCS II drug, from in situ forming PLA-based implants. The solvents evaluated were N-methyl-2-pyrrolidone (NMP), 2-pyrrolidone (2P), triacetine (TA) and benzyl benzoate (BB). Hansen’s solubility parameters of solvents were used to explain polymer/solvent interactions leading to different rheological behaviours. The stability of the polymer and drug in the solvents were also evaluated by size exclusion and high performance liquid chromatography, respectively. The two major factors determining the rate of IVM release from ISI were miscibility of the solvent with water and the viscosity of the polymer solutions. In general, the release rate increased with increasing water miscibility of the solvent and decreasing viscosity in the following order NMP>2P>TA>BB. Scanning electron microscopy revealed a relationship between the rate of IVM release and the surface porosity of the implants, release being higher as implant porosity increased. Finally, drug and polymer stability in the solvents followed the same trends, increasing when polymer-solvent affinities and water content in solvents decreased. IVM degradation was accelerated by the acid environment generated by the degradation of the polymer but the drug did not affect PLA stability.

Synthesis of monomethoxypolyoxyethylene-bound haemoglobins

Abstract Monomethoxypolyoxyethylene (M w ≅5000) was chemically modified and activated in order to react with the amino-groups of human haemoglobin. The best active polymeric derivatives were obtained by substituting a carboxymethoxyl group for the hydroxyl function of the polymer and by converting the carboxyl function into a N-hydroxysuccinimide active ester. When such modified polyoxyethylene derivatives were allowed to react with haemoglobin, soluble conjugates were formed with relatively low molecular weights. Some of the polymer-bound haemoglobins exhibit good oxygen-binding properties relative to unbound haemoglobin and could be suitable for use as erythrocyte substitutes.

Polysaccharide-covered nanoparticles with improved shell stability using click-chemistry strategies

Dextran-covered PLA nanoparticles have been formulated by two strategies. On one hand, dextran-g-PLA copolymers have been synthesized by click-chemistry between azide-multifunctionalized dextran (DexN3) and alkyne end-functionalized PLA chains (α-alkyne PLA); then nanoprecipitated without any additional surfactants. On the other hand, DexN3 exhibiting surfactant properties have been emulsified with unfunctionalized or α-alkyne PLA, which are dissolved in organic phase with or without CuBr. Depending on the o/w emulsion/evaporation process experimental conditions, dextran-g-PLA copolymers have been produced in situ, by click chemistry at the liquid/liquid interface during the emulsification step. Whatever the process, biodegradable core/shell polymeric nanoparticles have been obtained, then characterized. Colloidal stability of these nanoparticles in the presence of NaCl or SDS has been studied. While the physically adsorbed polysaccharide based shell has been displaced by SDS, the covalently-linked polysaccharide based shell ensures a permanent stability, even in the presence of SDS.

Emulsifying properties of neutral and ionic polymer surfactants based on dextran

The emulsifying properties of neutral and anionic polymer surfactants derived from dextran (a neutral polysaccharide) are described. The kinetics of interfacial tension lowering by the amphiphilic polymers is first characterized by the use of semi-empirical equations. These equations allow the determination of the equilibrium value of surface tension by extrapolation to infinite time. Oil-in-water emulsions are prepared by sonication in the presence of the polymers previously dissolved in the aqueous phase. The average droplet size of the emulsions is determined immediately after preparation and followed during several weeks. Ageing of the emulsions is shown to result from molecular diffusion in accordance with previous work. The increase of droplet size with time is correctly depicted by the theoretical equation derived by Lifshitz, Slyozov and Wagner (LSW). It seems that creaming has no real effect on emulsion ageing up to 1 μm. The influence of oil nature is clearly related to the physical properties of the oil (solubility in water, diffusion coefficient, interfacial tension), a typical consequence of molecular diffusion. An increase in the amount of hydrophobic groups fixed on the polymer leads to slower ageing. An increase in the anionic group content of the polymer has the reverse effect. Ionic strength has a significant effect on ageing of emulsions stabilized by dextran derivatives bearing ionic groups. Increasing ionic strength in the continuous phase gives rise to slower emulsion ageing. An attempt is made to rationalise all these facts by relating emulsion ageing to the data of interfacial tension measurements. The results follow approximately the tendency predicted by the LSW equation.

Effect of polyanionic polymers on haemoglobin oxygen-binding properties: application to the synthesis of covalent conjugates with low oxygen affinity

Abstract Polyanionic water-soluble polymers containing sulphate, phosphate and polycarboxylate groups were synthesized. These compounds, when simply added to haemoglobin solutions, were shown to lower the affinity of the protein for oxygen. Their influence on oxygen affinity was regarded as the result of a specific interaction of the polymer anionic groups inside the 2,3-diphosphoglycerate-binding site of deoxyhaemoglobin. On the other hand, these polymers were linked to deoxyhaemoglobin to give covalent conjugates also exhibiting an oxygen affinity lower than that of free haemoglobin in the presence of 2,3-diphosphoglycerate, its natural effector, which means that after fixation, the polyanionic polymers are still acting as effectors.