Novel self-associative and multiphasic nanostructured soft carriers based on amphiphilic hyaluronic acid derivatives.

The purpose of the present study was to investigate the physicochemical properties in aqueous media of amphiphilic hyaluronic acid (HA) derivatives obtained by reaction of HA's hydroxyl groups with octenyl succinic anhydride (OSA). The self-associative properties of the resulting octenyl succinic anhydride-modified hyaluronic acid (OSA-HA) derivatives were studied by fluorescence spectroscopy using Nile Red as fluorophore. The morphology, size and surface charge of the OSA-HA assemblies were determined by transmission electron microscopy, dynamic light scattering and by measuring their electrophoretic mobility, respectively. OSA-HA was shown to spontaneously self-associate in aqueous media into negatively charged spherical and multiphasic nanostructures with a hydrodynamic diameter between 170 and 230nm and to solubilize hydrophobic compounds such as Nile Red. This was a good indication that OSA-HA could be used as building block for the formulation of soft nanocarriers towards the encapsulation and controlled delivery of hydrophobic active ingredients or drugs.

Comparative studies of various hyaluronic acids produced by microbial fermentation for potential topical ophthalmic applications.

This work presents a comparative study of various hyaluronic acids (HA) produced by fermentation of either Bacillus subtilis or Streptococcus towards the selection of an optimal molecular weight (MW) HA for the preparation of topical ophthalmic formulations. The influence of HA MW on water binding capacity, sterile filtration, rheological properties, precorneal residence time and ocular tolerance of ophthalmic solutions was investigated. Molecular weight did not affect hydration of hyaluronic acid according to differential scanning calorimetry (DSC). In general, medium MW HA (0.6-1 MDa) resulted in solutions that were superior in terms of sterile filtration and kinematic viscosity requirements compared to high MW HA (>1 MDa). Moreover, all HA-based solutions exhibited well-defined viscoelastic properties that depend on MW. Gamma scintigraphic data indicated that HA MW at 0.1% concentration (w/v) and HA origin did not significantly affect the corneal residence time on rabbit eyes. A 0.3% solution of high MW HA had a prolonged residence time in the precorneal area compared to a medium MW HA at the same concentration. Finally, an in vivo ocular irritation test based on confocal laser scanning ophthalmoscopy (CLSO) conclusively showed the excellent tolerance of both Bacillus-derived HA and Streptococcus-derived HA after topical instillation onto the corneal surface. Overall, this comprehensive work highlights the superiority of medium MW hyaluronic acid for topical ophthalmic formulations based on their physico-chemical and biological properties, tolerance and handling. Such solutions are expected to enhance tear film stability, to allow for maximum comfort, and to exhibit high residence times, while being biocompatible and easy to sterile filter.

New amphiphilic lactic acid oligomer-hyaluronan conjugates: synthesis and physicochemical characterization.

The "grafting onto" strategy was used to conjugate DL-lactic acid oligomers (OLA) to hyaluronan (HA) for the sake of developing novel degradable HA-based self-assembling polymeric systems. Grafting was achieved by reacting COCl-terminated OLA with cetyltrimethylammonium hyaluronate (CTA-HA) in dimethyl sulfoxide (DMSO). The resulting CTA-HAOLA conjugates were purified and turned to sodium form (Na-HAOLA) by dissolution in a phosphate buffer-DMSO mixture and successive dialyses against DMSO, ethanol, and water. In contrast, when the same protocol was applied to CTA-HAOLA, phase separation with gel formation was observed. The solution phase was composed of Na-HAOLA whereas the gel phase was made of mixed CTA-Na-HAOLA salt with ca. 25% of the carboxyl groups neutralized by CTA. Gelation was assigned to intramolecular hydrophobic associations between OLA and cetyl alkyl chains that complemented electrostatic interactions between CTA and HA COO- groups synergistically. Therefore, the corresponding stabilized CTA ions required more drastic conditions to be released. Under the selected dialysis conditions, the CTA-Na-HAOLA gels formed tiny tubes. Na-HAOLA and CTA-Na-HAOLA were characterized by FTIR, one-dimensional 1H and two-dimensional 1H NMR. The extent of grafting was ca. 5% per disaccharidic repeating unit, regardless of the molecular weight, as determined by NMR and capillary zone electrophoresis. Amphiphilic Na-HAOLA molecules were aggregated and formed spherical species in water according to size exclusion chromatography combined with multiangle laser light scattering detection. The critical aggregation concentration ranged between 0.2 and 0.35% (w/v), depending of the molecular weight of the parent hyaluronan.

Solid-phase chemical tools for glycobiology.

Techniques involving solid supports have played crucial roles in the development of genomics, proteomics, and in molecular biology in general. Similarly, methods for immobilization or attachment to surfaces and resins have become ubiquitous in sequencing, synthesis, analysis, and screening of oligonucleotides, peptides, and proteins. However, solid-phase tools have been employed to a much lesser extent in glycobiology and glycomics. This review provides a comprehensive overview of solid-phase chemical tools for glycobiology including methodologies and applications. We provide a broad perspective of different approaches, including some well-established ones, such as immobilization in microtiter plates and to cross-linked polymers. Emerging areas such as glycan microarrays and glycan sequencing, quantum dots, and gold nanoparticles for nanobioscience applications are also discussed. The applications reviewed here include enzymology, immunology, elucidation of biosynthesis, and systems biology, as well as first steps toward solid-supported sequencing. From these methods and applications emerge a general vision for the use of solid-phase chemical tools in glycobiology.

Fractionation, solid-phase immobilization and chemical degradation of long pectin oligogalacturonides. Initial steps towards sequencing of oligosaccharides.

This work presents the optimized separation of pectin oligomers, their analysis by matrix-assisted laser desorption/ionization-time of flight mass spectrometry (MALDI-TOF MS), their subsequent immobilization to supports, and our initial steps towards solid-support assisted sequencing. The ambient pressure strong anion-exchange resin Source 15Q combined with ammonium formate buffer (AF) was used for the separation of unsaturated and saturated pectic oligogalacturonides (OGAs) derived from enzymatic digestion of pectin. Routinely, multi-milligram quantities of defined sizes OGAs with DPs from 5 to 19 were produced in excellent purity (>95%). Elution of OGAs followed by direct analysis of the peak fractions by MALDI-TOF MS. Purified OGAs (DP 5-7) were chemoselectively immobilized onto aminooxy-terminated polyethylene glycol polyacrylamide (PEGA) supports. Solid-phase anchoring took place at the reducing end of the oligosaccharide and resulted in the formation of an oxime linkage. The very high coupling yields confirmed the general suitability of aminooxy-PEGA resins for the immobilization of OGAs of different lengths. The OGA-functionalized PEGA supports were subsequently treated with aq TFA at 40 or 60 degrees C, and the chemical degradation products released from the support were analyzed by ESIMS. In all cases, the original OGA was degraded into smaller oligomers of various sizes down to the monomer. This work illustrates some of the basic principles underlying a strategy ultimately aimed at solid-support assisted sequencing of oligosaccharides.

Solid-supported enzymatic synthesis of pectic oligogalacturonides and their analysis by MALDI-TOF mass spectrometry.

Solid-phase biosynthetic reactions, followed by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry analysis (MALDI-TOF), was used to gain insight into the biosynthesis of pectin oligomers. Sepharose supports bearing long pectic oligogalacturonides (OGAs) anchored through a disulfide-containing cleavable linker, were prepared. The OGAs (degrees of polymerization of 13 and 14) were efficiently immobilized through the reducing end via formation of an oxime linkage. These OGA-derivatized matrices were subsequently employed in novel solid-phase enzymatic reactions, with the pectin biosynthetic enzyme, alpha-1,4-galacturonosyltransferase, GalAT (solubilized from Arabidopsis thaliana) and the glycosyl donor, uridine diphosphate-galacturonic acid (UDP-GalA). Solid-supported biosynthesis was followed by cleavage of the immobilized OGAs and direct analysis of the products released into the liquid phases by MALDI-TOF mass spectrometry. In time course studies conducted with an immobilized (alpha-D-GalA)14 and limiting amounts of the glycosyl donor, the predominant product was an OGA extended by one GalA residue at the non-reducing end (i.e., (GalA)15). When UDP-GalA was added in approximately excess compared to immobilized (GalA)13, OGAs up to the 16-mer were synthesized, confirming the non-processivity of the GalAT in vitro.

Immobilization of pectin fragments on solid supports: novel coupling by thiazolidine formation.

As a prerequisite to solid-phase and sequence analyses and for the study of the fine structure of pectin, we have developed oriented and chemoselective methodologies to couple model pectin fragments onto a solid support. Polyethylene glycol polyacrylamide (PEGA) resins were selected due to their excellent swelling properties in a wide range of solvents, including water, and their easy accessibility to enzymes. Following appropriate derivatization of amino-terminated PEGA resins, oligomers of alpha-D-galacturonic acid (GalA), up to the trimer, were anchored to the support through their reducing end. In addition to reductive amination, the strategies included the formation of an oxime bond, a glycosyl hydrazide, and a pyroglutamyl ring. Further, we developed a new immobilization approach based on the formation of a thiazolidine ring. All methods proved efficient and did not require modification of the GalA oligomers prior to coupling. In addition, very mild conditions and few steps for derivatization of the support were required. Immobilization by thiazolidine ring and oxime bond formation were the preferred methods, given the stability of the linkages formed, their compatibility with aqueous solvents, the few number of steps required, and their potential for application to larger pectin fragments. Thiazolidine and pyroglutamyl anchoring were developed further by the insertion of a disulfide bond which allowed release of the saccharides under mild, selective conditions.