DANTAS, M. L.; http://lattes.cnpq.br/6317533886497651; DANTAS, Maria Jucélia Lima.
Resumo:
Three-dimensional structures are very attractive tools for tissue engineering,
physically mimicked the natural extracellular matrix, these structures act as supports for cell development. The goal was to produce biodegradable threedimensional structures of chitosan-hydroxyapatite-gelatin (CS / HA / L) with different HA contents and evaluate their properties and behavior in vitro. The three-dimensional structures were produced in two steps. In a first step CS were obtained spheres containing different amounts of HA low crystallinity (20, 50 and 70% w / w). The poorly crystalline HA was generated in situ within the CS spheres. To this precipitate was dissolved in CS CaHPO4 and the resulting suspension was shaped in the form of spheres by dripping in dissolution Na5P3O10 (TPP) at pH 8-9. The precipitated spheres were kept in this solution under stirring to obtain the halftone processing and the CS HA CaHPO4
, and finally lyophilized. To obtain the three-dimensional structures, CS-HA spheres
were bonded by impregnation with warm solution (40 ° C) 5% C, cooling to -18 °C and lyophilization. The spheres were characterized by optical microscopy (OM), scanning electron microscopy (SEM), X-ray diffraction (XRD), thermogravimetric analysis (TG) and infrared spectroscopy (IR). And the three dimensional structures by porosity, Degree of Swelling (GI), mechanical property of resistance comrpressão via dry and wet. The average diameter of the spheres according to the results of MO was 2.6 ± 0.22 mm and 2.8 ± 0,28mm CS-20% CSHA50% respectively. Already the particles of CS-HA70% had a mean diameter of 3.9 ± 0,37mm having their morphology and surface porosity varied with the HA content. The presence of low crystallinity with in the
HA spheres was confirmed by the XRD results and IV. In the SEM images was
observed that HA crystals are homogeneously dispersed within the sphere. The
TG data showed good agreement between the HA and the amounts actually
projected on the spheres obtained. The results indicate influences of threedimensional structures for various concentrations of hydroxyapatite. With the
increase in the ceramic fraction is observed densification of the surface, a slight
reduction of the porosity and the degree of swelling, as well as an increase in the modulus of elasticity via a small decrease in the mechanical properties wet route, caused by swelling of the structure. The composite that presented better results was CS-HA20%, showing a better profile to the porosity, degree of swelling and mechanical prorpriedades. The study suggests that threedimensional structures require adjustments to be applied in bone regeneration, but can be suitable for applications in tissue engineering, in situations preferably ex vivo, as temporary supports cells.