Self-organization in the development of sensors, biosensors and membrane models for application in nanomedicine

In this thesis we employed the concept of self-organization, including the layer-by-layer (LbL) technique, alkanethiols self-assembled monolayers (SAMmix) and Langmuir monolayers, to develop new methods for materials and devices manipulation for application in nanomedicine. Two different types of biosensors were developed. The first one was based on the LbL technique to detect nitric oxide (NO•), which is of great importance in the medicine. The second biosensor was based on SAM monolayers supporting acetylcholinesterase for pesticide monitoring. The NO• was constructed by modified carbon fiber (CF) assembled with nickel phtalocyanine tetrasulfonade (NiTsPc) and polyamidoamine dendrimer (PAMAM) in the form of ultramicroelectrodes (UMEs) by the LbL technique. The sensor was characterized using differential pulse voltammetry and electrochemical impedance spectroscopy. The results showed that NO• diffusion is dependent on the number of bilayers employed and the arrangement of molecules in the film. The sensor architecture with CF-(PAMAM/NiTsPc) presented the best analytical signal. In addition, we analyzed the detection of interfering with NO• as nitrite, nitrate, hydrogen peroxide, ascorbic acid, dopamine, epinephrine and norepinephrine. The results showed high selectivity due to the use of PAMAM dendrimer as selective layer. The second biosensor used the enzyme acetylcholinesterase immobilized on SAMmix. The electrochemical detection of carbaryl was highly sensitive, since there is no use of glutaraldehyde as crosslinking agent. Using acetylcholine as a probe, Kmapp value was determined at 0.46x10-3 mol L-1, with detection limit of 3.32x10-10 mol L-1 and quantification limit of 1.11x10-9 mol L-1, values lower than those found in the literature, highlighting the efficiency of the new platform. Langmuir films made of lipids were employed as cell membrane models, in order to investigate the interactions between single-wall carbon nanotubes (SWCNT), PAMAM and their nanocomplex (SWCNT-PAMAM) at the molecular level. The interation of SWCNT and nanocomplexes in lipid monolayers was studies using Brewster angle microscopy (BAM) in conjunction with absorption kinetics and surface pressure. The results confirmed the interaction between nanomaterials and the membrane, indicating that the presence of nanomaterials affects the packing of the lipids. Cytotoxicity studies were also employed to investigate the interaction of nanomaterials in in vitro cell systems. The results of flow cytometry, cell proliferation, morphology and inhibition of adhesion revealed the toxicological aspects of the materials, demonstrating a higher toxicity to the nanocomplex, compared to SWCNT, differently of the individual components. The toxicity of SWCNT nanocomplex and its individual components can be related to the type of material and how these materials are available in the culture medium. The studies in this thesis show the versatility of self-assembly thin films on biomimetic systems and may be relevant to the advance of research on the interaction of nanomaterials and biosystems. (AU)