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.

PEGylated polyethyleneimine-entrapped gold nanoparticles for enhanced and targeted gene delivery applications

Gene therapy, which involves the transfer of nucleic acid into target cells in patients, has become one of the most important and widely explored strategies to treat a variety of diseases, such as cancer, infectious diseases and genetic disorders. Relative to viral vectors that have high immunogenicity, toxicity and oncogenicity, non-viral vectors have gained a lot of interest in recent years. This is largely due to their ability to mimic viral vector features including the capacity to overcome extra- and intra-cellular barriers and to enhance transfection efficiency. Polyethyleneimine (PEI) has been extensively investigated as a non-viral vector. This cationic polymer, which is able to compact nucleic acid through electrostatic interactions and to transport it across the negatively charged cell membranes, has been shown to effectively transfect nucleic acid into different cell lines. Moreover, entrapment of gold nanoparticles (Au NPs) into such an amine-terminated polymer template has been shown to significantly enhance gene transfection efficiency. In this work, a novel non-viral nucleic acid vector system for enhanced and targeted nucleic acid delivery applications was developed. The system was based on the functionalization of PEI with folic acid (FA; for targeted delivery to cancer cells overexpressing FA receptors on their surface) using polyethylene glycol (PEG) as a linker molecule. This was followed by the preparation of PEI-entrapped Au NPs (Au PENPs; for enhancement of transfection efficiency). In the synthesis process, the primary amines of PEI were first partially modified with fluorescein isothiocyanate (FI) using a molar ratio of 1:7. The formed PEI-FI conjugate was then further modified with either PEG or PEGylated FA using a molar ratio of 1:1. This process was finally followed by entrapment of Au NPs into the modified polymers. The resulting conjugates and Au PENPs were characterized by several techniques, namely Nuclear Magnetic Resonance, Dynamic Light Scattering and Ultraviolet-Visible Spectroscopy, to assess their physicochemical properties. In the cell biology studies, the synthesized conjugates and their respective Au PENPs were shown to be non-toxic towards A2780 human ovarian carcinoma cells. The role of these materials as gene delivery agents was lastly evaluated. In the gene delivery studies, the A2780 cells were successfully transfected with plasmid DNA using the different vector systems. However, FA-modification and Au NPs entrapment were not determinant factors for improved transfection efficiency. In the gene silencing studies, on the other hand, the Au PENPs were shown to effectively deliver small interfering RNA, thereby reducing the expression of the B-cell lymphoma 2 protein. Based on these results, we can say that the systems synthesized in this work show potential for enhanced and targeted gene therapy applications.