Sintese de derivados 3 - substituídos de coumarinas

Este trabalho descreve a síntese de novos derivados de coumarinas 3-substituídas por grupos arilo, etenilarilo e etenil-organometálicos, através de novas metodologias via reacções de Heck e de metátese (Grubbs), com controlo da regioquímica e com significativos rendimentos reaccionais. A aplicação destas metodologias permitiu a síntese dos derivados, 3-fenilcoumarina (131), 3-(4-bromofenil)coumarina, (132), 3-(4-iodofenil)­coumarina (134), 3-(4-nitrofenil)coumarina (136), 3-(4-etilfenil)coumarina (133), 4-(coumarin-3-il)benzaldeído (135), 3-(4-metoxifenil)coumarina (137), (E)-3-acrilato-[4-(coumarin-3-il)fenil] de metilo (138), 6,7-metileno­dioxi-[3-(E)-2'-feniletenil]coumarina (145), 6,7-dimetoxi-[-(E)-2'-fenil­etenil]coumarina (146), 6,7-dimetoxi-[3-(E)-2'-(6'-nitrofenil)etenil]coumarina (147), 4-[2-(E)-(6,7-dimetoxicoumarin-3-il)etenil]benzaldeído (148) e 6,7-dimetoxi-[3-(E)-2'-ferroceniletenil]coumarina (149), dos quais os últimos nove, são compostos novos, identificados e caracterizados pela primeira vez. A deslocalização do sistema de electrões  conjugados, induzida pelos diversos substituintes das coumarinas, foi igualmente avaliada através da espectroscopia de UV/Vis. De referir que parte deste trabalho foi publicado como: "New Methodology for the Synthesis of 3-Substituted Coumarins via Pd-Catalyzed Site-Se/ective Cross-Coupling Reactions”, Sérgio Martins, Paula S. Branco, María C. de la Torre, Miguel A. Sierra e António Pereira, Synlett, 2010 (https://www.thieme-connect.com/ejournals/abstract/ synlett/doi/1 O.1 OS5/s-0030-1259014). ABSTRACT: This work describes the synthesis of new 3-aryl, ethenylaryl and ethenyl-organometallics coumarin derivatives, using a new methodology via Heck and metathesis (Grubbs) reactions, with regiochemistry control and significant reaction yields. The application of these methodologies allowed the synthesis of derivatives, 3-phenylcoumarin (131), 3-(4-bromophenyl)coumarin (132), 3-(4-iodophenyl)coumarin (134), 3-(4-nitrophenyl)coumarin (136), 3-(4-ethylphenyl)coumarin {133), 4-(coumarin-3-yl)benzaldehyde {135), 3-(4-methoxiphenyl)coumarin (137), (E)-ethyl 3-[4(coumarin-3-yl)phenyl]­acrylate (138), 6,7-methylenedioxy-[3-(E)-2'-phenylethenyl]coumarin (145), 6,7-dimethoxy-[-(E)-2'-phenylethenyl]coumarin (146), 6,7-dimethoxy-[3-(E)­-2'-(6'-nitrophenyl)ethenyl]coumarin (147), 4-[2-(E)-(6,7-dimethoxy­coumarin-3-yl)ethenyl]benzaldehyde {148) e 6,7-dimethoxy-[3-(E)-2'-(ferro­ cene)ethenyl]coumarin (149), the last nine of these are new compounds, identified and characterized for the first time. The delocalization of conjugated -electron system, induced by different substituents of coumarins, was also assessed by spectroscopy UV/Vis. Part of this work was published at: "New Methodology for the Synthesis of 3-Substituted Coumarins via Pd-Catalyzed Site-Selective Cross-Coupling Reactions", Sérgio Martins, Paula S. Branco, María C. de la Torre, Miguel A. Sierra e António Pereira, Synlett, 2010 (https://www.thieme­connect.com/ejournaIs/abstract/synlett/doi/1O.1 055/s-0030-1259014).

Selective Sonogashira Couplings in 1,2,4,5-tetrazine derivatives

1,2,4,5-Tetrazines are six-membered heterocyclic compounds in which the four nitrogen atoms are displayed in a symmetric fashion. Their reactivity is quite different from other heterocyclic aromatic systems due to its unique electron-withdrawing character, comparable to tetra-nitrobenzene. 1 In particular, 1,2,4,5- tetrazines are known to take part in [4+2] inverse-Diels–Alder cycloaddition processes which efficiently lead to the construction of substituted pyridazine systems that are important in drug development and biomarker applications. 2 However, the electronic character of 1,2,4,5-tetrazines hampered the development of 3- ethynyl- and 3,6-diethynyl-1,2,4,5-tetrazine derivatives for molecular electronic applications, proved by the scarcity of examples found in the literature. 3 Herein, we describe the synthesis and characterization of two novel ethynyl-based 1,2,4,5-tetrazine derivatives. Synthesis of 3,6-(4-bromophenyl)-1,2,4,5-tetrazine precursor (1) was achieved in good yield by Pinner’s method, starting from 4-bromobenzonitrile. Despite its low solubility in common organic solvents, this precursor was found to react smoothly under typical Sonogashira coupling conditions to selectively afford the 3-ethynyl (2) and 3,6-diethynyl (3) protected derivatives (Figure 1). Reaction conditions were evaluated in order to provide the best yields and to promote selectivity of the mono- or disubstituted ethynyl derivatives. Finally, deprotection was achieved affording, in the case of compound 3, an unprecedented 3,6- diethynyl-1,2,4,5-tetrazine compound. Time-Dependent Density Functional Theory (TDDFT) calculations for both deprotected ethynyl derivatives were used to simulate electronic spectra. A deep knowledge of the relevant electronic transitions involved and quantitatively satisfactory results of the calculated electronic excitations in comparison with experimental data were obtained.

Design, Synthesis and Bioassays of 3-substituted-3-hydroxyoxindoles for cholinesterase inhibition

Based on the positive bioassay results of the known oxindole hit compound rac-1-benzyl-3-hydroxy-3-phenylindolin-2-one which showed significant inhibition of butyrylcholinesterase (BuChE) (IC50=7.41 μM), a library of 31 analogues of 3-substituted-3-hydroxyoxindoles was synthesized and screened for both acetylcholinesterase (AChE) and BuChE activity. Our bioassays revealed that some of the new compounds exhibited moderate inhibition of eel AChE (EeAChE) and very good inhibition of equine serum BuChE (EqBuChE) with a best IC50 of 1.02 μM. On the basis of these results, the lead compound 1-((1-benzylpiperidin-4-yl)methyl)-3-hydroxy-3-phenylindolin-2-one was designed, which was shown to interact well with the enzymes active sites by molecular docking, was synthesized and upon bioassay gave an IC50 of 6.61 μM for BuChE. Interestingly, when we separated rac-benzyl-3-hydroxy-3-phenylindolin-2-one into the individual enantiomers (R)- and (S)-benzyl-3-hydroxy-3-phenylindolin-2-one it was the latter enantiomer that gave the best IC50 of 6.19 μM for BuChE.