2 resultados para OXIDATIVE STRESS MARKERS
em Universita di Parma
Resumo:
Riassunto I biomarcatori o “marcatori biologici” svolgono un ruolo fondamentale nel monitoraggio biologico. In questo lavoro ci siamo soffermati sullo studio di biomarcatori di effetto e di esposizione a xenobiotici ambientali. Nel primo caso abbiamo valutato i micro RNA (miRNA) da utilizzare per la diagnosi precoce del tumore al polmone in matrici di facile accesso, quale il CAE e il plasma, utilizzando il miRNA-21, oncogeno, e il miRNA-486, oncosoppressore. I risultati evidenziano una loro capacità di distinguere correttamente i soggetti con tumore polmonare dai soggetti sani, ipotizzando un loro utilizzo a scopo diagnostico. Nella seconda parte del lavoro di tesi sono stati studiati i biomarcatori di esposizione a benzene per valutare gli effetti dell’esposizione a concentrazioni ambientali su bambini residenti in città e a diverso livello di urbanizzazione. Lo studio ha evidenziato una correlazione dose-effetto fra le concentrazioni di benzene e dei suoi metaboliti urinari e un danno ossidativo a livello degli acidi nucleici. Tuttavia, le concentrazioni di benzene urinario non sono influenzate dal grado di industrializzazione, a differenza dell’S-PMA e degli indicatori di stress ossidativo (8-oxodGuo e 8-oxoGuo) che sembrano risentire sia della residenza che del momento del campionamento. Infine abbiamo ricercato possibili biomarcatori di esposizione a vinilcicloesene (VCH), sottoprodotto industriale nella polimerizzazione del 1,3-butadiene, poiché non sono ancora stati proposti BEI di riferimento nonostante i bassi valori di TLV-TWA (0.1 ppm) proposti dall’ACGIH. Nella prima fase del lavoro abbiamo studiato i meccanismi di tossicità del VCH tramite modelli in vitro, testando varie linee cellulari. I risultati evidenziano come la dose reale di VCH sia di molto inferiore a quella nominale per effetto dell’evaporazione. Inoltre, nelle linee cellulari più sensibili si sono evidenziati effetti citostatici, con alterazioni del ciclo cellulare, a differenza dell’esposizione agli epossidi del VCH, il VCD e l’1,2-VCHME, che determinano lisi cellulare con IC50 di 3 ordini di grandezza inferiori a quelli del VCH. La quantificazione dei metaboliti di I fase e di II fase del VCH nelle linee cellulari epatiche ha evidenziato concentrazioni di circa 1000 volte inferiori a quelle del VCH confermando come la sua tossicità sia principalmente dovuta alla produzione degli intermedi epossidici. La trasformazione nei metaboliti di II fase conferma inoltre l’effetto detossificante del metabolismo. La trasferibilità dei risultati ottenuti in vitro su sistemi in vivo fornirà le basi per poter identificare possibili metaboliti da proporre per il monitoraggio biologico di lavoratori esposti a VCH. PAROLE CHIAVE: biomarcatori di effetto e di esposizione, tumore al polmone, miRNA, benzene, vinilcicloesene.
Resumo:
As defined by the European Union, “ ’Nanomaterial’ (NM) means a natural, incidental or manufactured material containing particles, in an unbound state or as an aggregate or agglomerate, where, for 50 % or more of the particles in the number size distribution, one or more external dimensions is in the size range 1 nm-100 nm ” (2011/696/UE). Given their peculiar physico-chemical features, nanostructured materials are largely used in many industrial fields (e.g. cosmetics, electronics, agriculture, biomedical) and their applications have astonishingly increased in the last fifteen years. Nanostructured materials are endowed with very large specific surface area that, besides making them very useful in many industrial processes, renders them very reactive towards the biological systems and, hence, potentially endowed with significant hazard for human health. For these reasons, in recent years, many studies have been focused on the identification of toxic properties of nanostructured materials, investigating, in particular, the mechanisms behind their toxic effects as well as their determinants of toxicity. This thesis investigates two types of nanostructured TiO2 materials, TiO2 nanoparticles (NP), which are yearly produced in tonnage quantities, and TiO2 nanofibres (NF), a relatively novel nanomaterial. Moreover, several preparations of MultiWalled Carbon Nanotubes (MWCNT), another nanomaterial widely present in many products, are also investigated.- Although many in vitro and in vivo studies have characterized the toxic properties of these materials, the identification of their determinants of toxicity is still incomplete. The aim of this thesis is to identify the structural determinants of toxicity, using several in vitro models. Specific fields of investigation have been a) the role of shape and the aspect ratio in the determination of biological effects of TiO2 nanofibres of different length; b) the synergistic effect of LPS and TiO2 NP on the expression of inflammatory markers and the role played therein by TLR-4; c) the role of functionalization and agglomeration in the biological effects of MWCNT. As far as biological effects elicited by TiO2 NF are concerned, the first part of the thesis demonstrates that long TiO2 nanofibres caused frustrated phagocytosis, cytotoxicity, hemolysis, oxidative stress and epithelial barrier perturbation. All these effects were mitigated by fibre shortening through ball-milling. However, short TiO2 NF exhibited enhanced ability to activate acute pro-inflammatory effects in macrophages, an effect dependent on phagocytosis. Therefore, aspect ratio reduction mitigated toxic effects, while enhanced macrophage activation, likely rendering the NF more prone to phagocytosis. These results suggest that, under in vivo conditions, short NF will be associated with acute inflammatory reaction, but will undergo a relatively rapid clearance, while long NF, although associated with a relatively smaller acute activation of innate immunity cells, are not expected to be removed efficiently and, therefore, may be associated to chronic inflammatory responses. As far as the relationship between the effects of TiO2 NP and LPS, investigated in the second part of the thesis, are concerned, TiO2 NP markedly enhanced macrophage activation by LPS through a TLR-4-dependent intracellular pathway. The adsorption of LPS onto the surface of TiO2 NP led to the formation of a specific bio-corona, suggesting that, when bound to TiO2 NP, LPS exerts a much more powerful pro-inflammatory effect. These data suggest that the inflammatory changes observed upon exposure to TiO2 NP may be due, at least in part, to their capability to bind LPS and, possibly, other TLR agonists, thus enhancing their biological activities. Finally, the last part of the thesis demonstrates that surface functionalization of MWCNT with amino or carboxylic groups mitigates the toxic effects of MWCNT in terms of macrophage activation and capability to perturb epithelial barriers. Interestingly, surface chemistry (in particular surface charge) influenced the protein adsorption onto the MWCNT surface, allowing to the formation of different protein coronae and the tendency to form agglomerates of different size. In particular functionalization a) changed the amount and the type of proteins adsorbed to MWCNT and b) enhanced the tendency of MWCNT to form large agglomerates. These data suggest that the different biological behavior of functionalized and pristine MWCNT may be due, at least in part, to the different tendency to form large agglomerates, which is significantly influenced by their different capability to interact with proteins contained in biological fluids. All together, these data demonstrate that the interaction between physico-chemical properties of nanostructured materials and the environment (cells + biological fluids) in which these materials are present is of pivotal importance for the understanding of the biological effects of NM. In particular, bio-persistence and the capability to elicit an effective inflammatory response are attributable to the interaction between NM and macrophages. However, the interaction NM-cells is heavily influenced by the formation at the nano-bio interface of specific bio-coronae that confer a novel biological identity to the nanostructured materials, setting the basis for their specific biological activities.