Nanocomposite systems based on polysaccharides and organic/inorganic nanostructures for biomedical applications

This PhD thesis deals with the development of bioactive polysaccharide-based biomaterials for bone tissue and neural tissue engineering. Alginate was chosen for its gel forming properties; hyaluronic acid and chitlac (a lactose-modified chitosan) were chosen for their bioactive properties. The properties of these polysaccharides have been implemented by introducing gelatin, functionalized Carbon Nanotubes (f-CNTs) and silver nanoparticles (nAg). In the first part of the work, the dispersibility and aggregation tendency of f-CNTs have been characterized by means of Low Field Nuclear Magnetic Resonance (LF-NMR). It was also possible to correlate the f-CNTs concentration to the proton transversal relaxation rate of water. Alginate/f-CNTs solutions and hydrogels have been analyzed by LF-NMR, rheology and uniaxial compression tests; these investigations showed that the f-CNTs are able to affect nanocomposite properties depending on their concentration and functionalization. In the second part of the work, the preparation of a bioactive (bridging) implant for the treatment of Spinal Cord Injury is described. Neuronal cells and mesoangioblasts (MABs) engineered for the production of neurotrophines have been cultured and co-cultured on polysaccharide-coated glass substrates in order to evaluate the biological effects of chitlac. Chitlac-coated surfaces where shown to possess higher surface energies if compared to chitosan-coated ones and enable the formation of wider neural networks with improved electrical activity. The co-cultures confirmed the higher bioactivity of chitlac/alginate substrates and the biological role of neurotrophines. Porous scaffolds of alginate/chitlac have been prepared; these scaffolds where shown to be stable in simulated body fluid for over a month. The mechanical properties of rehydrated scaffolds where proved to be similar to those of neural tissue. Biological properties of chitlac substrates enriched with f-CNTs are currently under investigation. In the third part of the work, tridimensional scaffolds and injectable fillers were developed for the treatment of non-critical bone defects. Porous scaffolds with different pore morphologies have been prepared by freeze casting of alginate/HAp hydrogels. Isotropic porosity was obtained by freezing the constructs in a cryostat, while anisotropic porosity was obtained by the Ice Segregation Induced Self Assembly process. Physical, mechanical and biological analyses revealed that the differences in pore morphology determine differences in the mechanical properties of the scaffolds. Biocompatible f-CNTs have been used to implement the isotropic scaffolds; the biological analyses showed that the presence of f-CNTs does not affect scaffold properties. Osteoconductive/antimicrobial injectable bone fillers, based on alginate/HAp microbeads dispersed in polysaccharide mixtures, have been developed. Microbeads were enriched with nAg synthesized in chitlac. Antimicrobial assays proved the antibacterial properties of the microbeads towards bacteria in suspension and on pre-formed biofilms. Biological assays showed the biocompatibility of the microbeads and their ability to sustain osteoblast proliferation. The fillers prepared by dispersing microbeads in polysaccharide mixtures were shown to be easily injectable through surgical syringes. In vivo studies on a rabbit model of non-critical bone defect pointed out the biocompatibility and the osteoconductivity of the composite materials. Further studies are ongoing in order to evaluate the possibility to further implement the bioactive properties of the microbeads by addiction of gelatin.