Reazioni di vari reagenti elettrofili con derivati amminotiazolici ad elevato potere nucleofilo

The nucleophile/electrophile combination in the aromatic substitution reaction using aminothiazole derivatives as nucleophiles has been the subject of this study. The reaction between 2,4-dipyrrolidinylthiazole and the neutral carbon electrophile 1,3,5-trinitrobenzene gave a stable Wheland-Meisenheimer (WM) complex. This represents another example, among those already found by the research group in which this work has been carried out, of stable zwitterionic σ-intermediates. When the reaction was carried out with halonitrobenzene derivatives, it produced the substitution product in position 5 of the thiazole ring. 2,4-dipyrrolidinylthiazole and arenediazonium salts gave the coupling product at the C5 of the thiazole ring together with many byproducts and the stable Wheland intermediate formed by attack of the proton on the C5 of the starting thiazole reagent. Arenediazonium salts were coupled also with 2-pyrrolidinylthiazole. In this case quantitative formation of the substitution product deriving from the attack of the electrophile on the carbon nucleophilic position of the thiazole ring was obtained. In conclusion, the results had allowed to expand the knowledge on electrophilic/nucleophilic interactions in the aromatic substitution involving thiazole heteroaromatics and provided a further example of stable Wheland-Meisenheimer intermediates.

Influence of alternative electron acceptors on the anaerobic biodegradation of polycyclic aromatic hydrocarbons

Polycyclic aromatic hydrocarbons are chemicals produced by both human activities and natural sources and they have been present in the biosphere since millions of years. For this reason microorganisms should have developed, during the world history, the capacity of metabolized them under different electron acceptors and redox conditions. The deep understanding of these natural attenuation processes and of microbial degradation pathways has a main importance in the cleanup of contaminated areas. Anaerobic degradation of aromatic hydrocarbons is often presumed to be slow and of a minor ecological significance compared with the aerobic processes; however anaerobic bioremediation may play a key role in the transformation of organic pollutants when oxygen demand exceeds supply in natural environments. Under such conditions, anoxic and anaerobic degradation mediated by denitrifying or sulphate-reducing bacteria can become a key pathway for the contaminated lands clean up. Actually not much is known about anaerobic bioremediation processes. Anaerobic biodegrading techniques may be really interesting for the future, because they give the possibility of treating contaminated soil directly in their natural status, decreasing the costs concerning the oxygen supply, which usually are the highest ones, and about soil excavations and transports in appropriate sites for a further disposal. The aim of this dissertation work is to characterize the conditions favouring the anaerobic degradation of polycyclic aromatic hydrocarbons. Special focus will be given to the assessment of the various AEA efficiency, the characterization of degradation performance and rates under different redox conditions as well as toxicity monitoring. A comparison with aerobic and anaerobic degradation concerning the same contaminated material is also made to estimate the different biodegradation times.