Studio sull'applicazione di derivati dell'ammina di betti chirali in sistemi catalitici organici

In this thesis, the development of asymmetric α-alkylation of aldehydes using two new organocatalysts is described. Nowadays organocatalized asymmetric synthesis uses preferentially primary or secondary amines. In our case two new Betti bases derivatives have been used as organocatalysts. We tried to find a method based on resolution to obtain both enantiomers with ee major than 90%. At the end we tried them in an organocatalytic processes which involve indole derivatives and aldehydes as substrates. In questa tesi è descritto lo sviluppo del processo di alfa-alchilazione di aldeidi utilizzando due nuovi catalizzatori organici chirali. Al giorno d’oggi la sintesi asimmetrica organo catalitica sfrutta principalmente ammine primarie e secondarie chirali. Come organo catalizzatori, sono stati utilizzati due nuovi derivati della base di Betti. E’ stato ricercato un metodo che permettesse di risolvere entrambi gli enantiomeri e che permettesse di ottenere un eccesso enantiomerico maggiore del 90%. Infine questi catalizzatori sono stati utilizzati e ottimizzati in micro-processi che utilizzano un substrato indolico e di un’aldeide.

Nuovi coniugati fra acido azelaico ed azaeterocicli: sintesi e valutazione dell'attività biologica

The well-known antiproliferative properties of the 9-hydroxystearic acid (9-HSA) on human colon cancer cells (HT-29 cell line) have inspired this thesis work in order to obtain new derivatives maintaining the C1-C8 chain of the HSA linked to an heterocyclic moiety at the C-9 carbon atom and to investigate their biological activity. First, thiazoles, thiadiazoles and benzothiazoles, that are compounds of interest in many fields for their biological activities, have been introduced through an amide bond starting from their 2-amino precursors. The products have been obtained by treatment with methyl 9-chloro-9-oxononanoate according to a Schotten-Baumann type reaction. The acylation reaction occurred at the endocyclic nitrogen atom of the heterocycle, as ascertained through NOESY-1D experiment. After, methyl 9-chloro-9-oxononanoate was reacted with indole, N-methylindole, and triptamine giving a serie of new indole derivatives. Finally, the biological activity of some compounds has been tested through assays on HT-29 cancer cells and bacterial and fungal microorganisms; docking calculations have also been performed to evaluate the possible interactions with the active site of histone deacetylase, which are molecular targets of the 9-HSA.

Dearomatizzazione organocatalitica regio- ed enantioselettiva di sali di piridinio attivati

In this work, we present the first regio- and enantioselective organocatalytic nucleophilic dearomatization of activated N-alkyl pyridinium salts. In particular, N-benzyl pyridinium bromides bearing electron-withdrawing substituents at the C3 position of the pyridine ring were chosen as substrates. These compounds were easily obtained through an alkylation reaction between benzyl bromides and the corresponding 3-substituted pyridines. Then, a wide range of nucleophiles and organocatalysts was tested, providing the best results when indole, a thiourea derived from quinidine and 1-benzyl-3-nitropyridinum bromide were employed as the nucleophile, the catalyst and the pyridinium salt, respectively. Subsequently, the reaction conditions were optimised evaluating different bases, solvents, N-benzylic protecting groups, molar concentrations and temperatures. With the optimized condition in hand, the scope of the reaction with different substituted indoles was explored, affording the corresponding 1,4-dihydropyridines in good yields, regio- and enantio-selectivities. In addition, several experiments were carried out in order to understand the mechanism of the reaction, showing an unusual pathway involving a covalently bound intermediate formed by addition of the catalyst to the pyridine unit.