Chitosan-g-oligo(L,L-lactide) copolymer hydrogel for nervous tissue regeneration in glutamate excitotoxicity: in vitro feasibility evaluation.

Over the last decade, a number of hydrogels attracted great attention in the area of brain tissue engineering. The hydrogels are composed of hydrophilic polymers forming 3D network in water. Their function is promoting structural and functional restoration of damaged brain tissues by providing mechanical support and navigating cell fate. This paper reports on the neurocompatibility of chitosan-g-oligo(L,L-lactide) copolymer hydrogel with primary rat cortical neuron culture. The hydrogel was produced by a molding technique on the base of photocurable composition consisting of chitosan-g-oligo(L,L-lactide) copolymer, poly(ethylene glycol) diacrylate and photosensitizer Irgacure 2959. The influence of the hydrogel on cell viability, phenotype and calcium homeostasis, mitochondrial potential and oxygen consumption rate in glutamate excitotoxicity was analyzed using primary neuron cultures obtained from a neonatal rat cortex. This study revealed that the hydrogel is non-cytotoxic. Dissociated neonatal rat cortical cells were actively attaching to the hydrogel surface and exhibited the phenotype, calcium homeostasis and mitochondrial function in both standard conditions and glutamate excitotoxicity (100 µM) similar to the control cells cultured without the hydrogel. To conclude, in this study we assessed the feasibility of the application of chitosan-g-oligo(L,L-lactide) copolymer hydrogel for tissue engineering therapy of brain injury in an in vitro model. The results support that the hydrogel is able to sustain realization of the functional metabolic activity of neonatal rat cortical cells in response to glutamate excitotoxicity.

[Compatibility of cells of the nervous system with structured biodegradable chitosan-based hydrogel matrices].

Hydrogel matrices for cell cultivation have been generated by two-photon laser polymerization of unsaturated chitosan derivatives and methacrylated hyaluronic acid. The adhesive and toxic properties of the matrices have been assessed, and the matrices have been shown to have a good compatibility with primary hippocampal cell cultures. The formation of morphologically normal neural networks by cells of the nervous system cultured on the surface of hydrogel matrices has been observed. The metabolic status of dissociated hippocampal cells cultured on the matrices was similar to that of the control cultures, as shown by the results of MTT reductase activity assay. Thus, matrices based on unsaturated polysaccharide derivatives crosslinked by laser irradiation showed good compatibility with differentiated cells of the nervous system and considerable potential for use in neurotransplantation.

Polylactide-based microspheres prepared using solid-state copolymerized chitosan and d,l-lactide.

Amphiphilic chitosan-g-poly(d,l-lactide) copolymers have been manufactured via solid-state mechanochemical copolymerization and tailored to design polyester-based microspheres for tissue engineering. A single-step solid-state reactive blending (SSRB) using low-temperature co-extrusion has been used to prepare these copolymers. These materials have been valorized to stabilize microspheres processed by an oil/water emulsion evaporation technique. Introduction of the copolymers either in water or in the oil phase of the emulsion allowed to replace a non-degradable emulsifier typically used for microparticle preparation. To enhance cell adhesion, these copolymers were also tailored to bring amino-saccharide positively charged segments to the microbead surface. Size distribution, surface morphology, and total microparticle yield have been studied and optimized as a function of the copolymer composition.