Síntese e caracterização de nanopartículas FeOx/Au/Ag em multicamada núcleo-concha

Nesta dissertação, apresenta-se o trabalho realizado no decorrer do segundo ano do Mestrado em Bioquímica Aplicada. Prepararam-se nanopartículas metálicas através da redução química de sais metálicos em solução. Obtiveram-se soluções coloidais monometálicas de Au, Ag e FeOx e bimetálicas de Au/Ag, Ag/Au, FeOx/Au e FeOx/Ag seguindo ou adaptando métodos publicados na literatura. Numa primeira fase foram sintetizadas nanopartículas monometálicas de prata e ouro utilizando-se β-D-glucose, borohidreto de sódio e β-ciclodextrina como agente redutor dos iões metálicos. Seguidamente, por co-redução de uma mistura de iões prepararam-se ligas de nanopartículas de prata e ouro e por redução sucessiva de Ag e Au sintetizaram-se nanopartículas com uma estrutura núcleo-concha. As nanopartículas de FeOx foram preparadas por co-precipitação de Fe (III) e Fe (II). O revestimento com ouro foi conseguido através da redução com citrato de sódio e para a deposição de prata utilizou-se o ácido ascórbico. As soluções coloidais preparadas foram caracterizadas através de estudos de espetroscopia do UV-vis, tendo sido registados os máximos de absorvância característicos do ouro e da prata e os desvios esperados para o caso das nanopartículas núcleo-concha. As análises por dispersão dinâmica de luz permitiram auferir o tamanho das nanopartículas, eventual aglomeração e, portanto, permitiram a apreciação da estabilidade dos coloides. Com o intuito de confirmar a formação de estruturas em camada núcleo-concha foi feita a caracterização das amostras por microscopia eletrónica de transmissão e espetroscopia de raios-X de energia dispersiva. Alguns dos espetros obtidos confirmam o sucesso na preparação de uma estrutura em multicamada. Finalmente, demonstrou-se a biocompatibilidade de algumas amostras preparadas através da realização de estudos de citotoxicidade na linha celular fibroblástica NIH 3T3.

Gene delivery using dendrimer/pDNA complexes immobilized in electrospun fibers using the layer-by-layer technique

Tissue engineering is an important branch of regenerative medicine that uses cells, materials (scaffolds), and suitable biochemical and physicochemical factors to improve or replace specific biological functions. In particular, the control of cell behavior (namely, of cell adhesion, proliferation and differentiation) is a key aspect for the design of successful therapeutical approaches. In this study, poly(lactic-co-glycolic acid) (PLGA) fiber mats were prepared using the electrospinning technology (the fiber diameters were in the micrometer range). Furthermore, the electrospun fiber mats thus formed were functionalized using the layer-by- layer (LbL) technique with chitosan and alginate (natural and biodegradable polyelectrolytes having opposite charges) as a mean for the immobilization of pDNA/dendrimer complexes. The polyelectrolyte multilayer deposition was confirmed by fluorescence spectroscopy using fluorescent-labeled polyelectrolytes. The electrospun fiber mats coated with chitosan and alginate were successfully loaded with complexes of pDNA and poly(amidoamine) (PAMAM) dendrimers (generation 5) and were able of releasing them in a controlled manner along time. In addition, these mats supported the adhesion and proliferation of NIH 3T3 cells and of human mesenchymal stem cells (hMSCs) in their surface. Transfection experiments using a pDNA encoding for luciferase showed the ability of the electrospun fiber mats to efficiently serve as gene delivery systems. When a pDNA encoding for bone morphogenetic protein-2 (BMP-2) was used, the osteoblastic differentiation of hMSCs cultured on the surface of the mats was promoted. Taken together, the results revealed that merging the electrospinning technique with the LbL technique, can be a suitable methodology for the creation of biological active matrices for bone tissue engineering.

Low generation triazine-based dendrimers-synthesis, characterzation and in vitro biological activity

In the present study, two low generation triazine-based dendrimers, G1.0(Cl)4 dendrimer and G1.5(OH)8 dendrimer, were synthesized and their cytotoxicity were tested by using the NIH 3T3 and the A2780 cell lines. In the synthesis process of the G1.0(Cl)4 dendrimer, cyanuric chloride (CAC) which has high reactivity chlorine atom was connected to the terminal of triethylene glycol (TEG) via nucleophilic substitution by controlling temperature. The prepared G1.0(Cl)4 dendrimer was purified by silica gel column chromatography. Then the four chlorine atoms in the G1.0(Cl)4 dendrimer were substituted by diethanolamine (DEA) to give dendrimer with the hydroxyl terminal group G1.5(OH)8. The starting materials, CAC, G1.0(Cl)4 dendrimer and G1.5(OH)8 dendrimer were analyzed by one-dimensional NMR, FTIR and MS techniques. The two dendrimers, G1.0(Cl)4 and G1.5(OH)8, showed perfect stability in the air environment at room temperature. However, G1.0(Cl)4 is not soluble in water while the G1.5(OH)8 dendrimer is a water soluble compound. Furthermore, cell biological evaluation at the studied concentrations showed that the CAC, as well as the prepared G1.0(Cl)4 and G1.5(OH)8 dendrimers, have no cytotoxicity towards the NIH 3T3 and A2780 cell lines.