Analysis of strychnos alkaloids using electrospray ionization Fourier transform ion cyclotron resonance multi-stage tandem mass spectrometry

The fragmentations of four strychnos alkaloids have been investigated by electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry (ESI-FTICR-MS) in the positive ion mode. Experiments using multi-stage tandem mass spectrometry (ESI-FT-ICR-MSn) allowed us to obtain precise elemental compositions of product ions at high mass resolution. The experimental data demonstrated that the nitrogen bridge and the coordinated oxygen atom on the nitrogen bridge in the alkaloid compounds were the active sites in the MS2 fragmentations. The loss of CH3 or the OCH3 group in those alkaloids, which have an OCH3 substituent, was the dominant fragmentation mode in the MS3 fragmentations. Logical fragmentation schemes for strychnos alkaloids have been proposed and these should be useful for the identification of these compounds.

ON THE IODINE-DOPING OF POLYANILINE AND POLY-ORTHO-METHYLANILINE

The reactions of polyaniline and poly-omicron-methylaniline of different oxidation degrees with I2 were followed by FTIR and electrical conductivity measurements. The results showed that the reaction of common polyanilines with I2 was oxidation in nature whereas that of the fully reduced ones was doping. The latter took place in two steps: oxidation of benzene-diamine units into quinone-diimine units (redox between I2 and the polymer chain) and formation of a conjugated system consisting of four aromatic rings (intramolecular chain redox).

Copper-catalysed asymmetric sulfide oxidation

The focus of this thesis is the preparation of enantiopure sulfoxides by means of copper-catalysed asymmetric sulfoxidation, with particular emphasis on the synthesis of aryl benzyl and aryl alkyl sulfoxides. Chapter 1 contains a review of the methods employed for the asymmetric synthesis of sulfoxides, compounds with many applications in stereoselective synthesis and in some cases with pharmaceutical application. Chapter 1 describes asymmetric oxidation, including metal-catalysed, non metal-catalysed and enzyme-catalysed, in addition to synthetic approaches via nucleophilic substitution of appropriately substituted precursors. Kinetic resolution in oxidation of sulfoxides to the analogous sulfones is also discussed; in certain cases, access to enantioenriched sulfoxides can be achieved via a combination of asymmetric sulfoxidation and complementary kinetic resolution. The design and synthesis of a series of sulfides to enable exploration of the substituent effects of the copper-mediated oxidation was undertaken, and oxidation to the racemic sulfoxides and sulfones to provide reference samples was conducted. Oxidation of the sulfides using copper-Schiff base catalysis was undertaken leading to enantioenriched sulfoxides. The procedure employed is clean, inexpensive, not air-sensitive and utilises aqueous hydrogen peroxide as oxidant. Extensive investigation of the influence of the reaction conditions such as solvent, temperature, copper salt and ligand was undertaken to lead to the optimised conditions. While the direct attachment of one aryl substituent to the sulfide is essential for efficient enantiocontrol, in the case of the second substituent the enantiocontol is dependent on the steric rather than electronic features of the substituent. Significantly, use of naphthyl-substituted sulfides results in excellent enantiocontrol; notably 97% ee, obtained in the oxidation of 2-naphthyl benzyl sulfide, represents the highest enantioselectivity reported to date for a copper-mediated sulfur oxidation. Some insight into the mechanistic features of the copper-mediated sulfur oxidation has been developed based on this work, although further investigation is required to establish the precise nature of the catalytic species responsible for asymmetric sulfur oxidation. Full experimental details, describing the synthesis and structural characterisation, and determination of enantiopurity are included in chapter 3.

Transformações organocatalíticas e mediadas por metais de transição na síntese de novos heterociclos nitrogenados e ciclo-hexanos

Nas últimas décadas a quiralidade tornou-se essencial na conceção, descoberta, desenvolvimento e comercialização de novos medicamentos. A importância da quiralidade na eficácia e segurança dos fármacos tem sido globalmente reconhecida tanto pelas indústrias farmacêuticas como pelas agências reguladoras de todo o mundo. De forma a produzir eficazmente medicamentos seguros e dar resposta à demanda da indústria de compostos enantiomericamente puros, a pesquisa de novos métodos de síntese assimétrica, assim como o desenvolvimento estratégico dos métodos já disponíveis tem sido um dos principais objetos de estudo de diversos grupos de investigação tanto na academia como na indústria farmacêutica No primeiro capítulo desta dissertação são introduzidos alguns dos conceitos fundamentais associados à síntese de moléculas quirais e descritas algumas das estratégias que podem ser utilizadas na sua síntese. Apresenta-se ainda uma breve revisão bibliográfica acerca dos antecedentes do grupo de investigação e sobre a ocorrência natural, atividade biológica e métodos de síntese e transformações de compostos do tipo (E,E)-cinamilidenoacetofenona. O segundo capítulo centra-se na adição de Michael enantiosseletiva de diversos nucleófilos a derivados de (E,E)-cinamilidenoacetofenona. Inicialmente descreve-se a síntese de derivados de (E,E)-cinamilidenoacetofenona através de uma condensação aldólica de acetofenonas e cinamaldeídos apropriadamente substituídos. Estes derivados são posteriormente utilizados como substratos na adição de Michael enantiosseletiva de três diferentes nucleófilos: nitrometano, malononitrilo e 2-[(difenilmetileno)amino]acetato de metilo. Nestas reações são utilizados diferentes organocatalisadores de forma a induzir enantiosseletividade nos aductos de Michael para serem utilizados na síntese de compostos com potencial interesse terapêutico. É descrita ainda uma nova metodologia de síntese de Δ1-pirrolinas através de um procedimento one-pot de redução/ciclização/desidratação mediada por ferro na presença de ácido acético de (R,E)-1,5-diaril-3-(nitrometil)pent-4-en-1-onas com bons rendimentos e excelentes excessos enantioméricos. O terceiro capítulo centra-se no estabelecimento de novas rotas de síntese e transformação de derivados do ciclo-hexano. Após uma breve revisão bibliográfica, são descritas três metodologias enantiosseletivas distintas, sendo que a primeira envolve a utilização de organocatalisadores e catalisadores de transferência de fase derivados de alcaloides cinchona. Os derivados do ciclo-hexano foram obtidos a partir da reação entre as (E,E)-cinamilidenoacetofenonas e o malononitrilo com bons rendimentos, mas baixas enantiosseletividades independentemente do catalisador utilizado. De forma a contornar este problema e uma vez que a formação do derivado do ciclo-hexano envolve inicialmente a formação in-situ do aducto de Michael, a segunda e terceira metodologias de síntese envolvem a utilização dos aductos de Michael enantiomericamente puros preparados no segundo capítulo. Assim, a reação do (S,E)-2-(1,5-diaril-1-oxopent-4-en-3-il)malononitrilo com os derivados de (E,E)-cinamilidenoacetofenona organocatalisada pela hidroquinina permitiu obter os compostos pretendidos com excelentes excessos enantioméricos. A utilização de um catalisador de transferência de fase não foi tão eficiente em termos de enantiosseletividades obtidas na reação entre as (R,E)-1,5-diaril-3-(nitrometil)pent-4-en-1-onas e os derivados de (E,E)-cinamilidenoacetofenona, apesar de estes terem sido obtidos em bons rendimentos. A preparação destes derivados levou ainda à idealização de uma nova metodologia de síntese de análogos do ácido γ-aminobutírico (GABA) devido à presença de um grupo nitro em posição gama relativamente a um grupo carboxílico. No entanto, apesar de terem sido testadas várias metodologias, não foi possível obter os compostos pretendidos. No quarto capítulo apresenta-se uma breve revisão bibliográfica acerca da ocorrência natural, atividade biológica e métodos de síntese de derivados de di-hidro- e tetra-hidropiridinas, assim como um enquadramento teórico acerca das reações pericíclicas utilizadas na síntese dos compostos pretendidos. Inicialmente é descrita a preparação de N-sulfonilazatrienos substituídos através da condensação direta de derivados de (E,E)-cinamilidenoacetofenona e sulfonamidas. Estes compostos são posteriormente utilizados na síntese de derivados de 1,2-di-hidropiridinas através de uma aza-eletrociclização-6π por duas metodologias distintas: utilização de organocatalisadores quirais e utilização de complexos metálicos de bisoxazolinas. Na síntese das tetra-hidropiridinas os N-sulfonilazatrienos são utilizados como dienos e o étoxi-eteno como dienófilo numa reação hetero-Diels-Alder inversa utilizando também os complexos metálicos de bisoxazolinas como catalisadores. Todos os novos compostos sintetizados foram caracterizados estruturalmente recorrendo a estudos de espetroscopia de ressonância magnética nuclear (RMN), incluindo espetros de 1H e 13C e estudos bidimensionais de correlação espetroscópica homonuclear e heteronuclear e de efeito nuclear de Overhauser (NOESY). Foram também efetuados, sempre que possível, espetros de massa (EM) e análises elementares ou espetros de massa de alta resolução (EMAR) para todos os novos compostos sintetizados.

Sels d’imidazolium avec des anions catalytiques : vers le développement de nouveaux catalyseurs bio-hybrides actifs en milieu liquide ionique

Les liquides ioniques connaissent depuis quelques décennies un essor particulier en raison de leurs nombreuses propriétés physico-chimiques intéressantes, telles qu’une faible pression de vapeur saturante, une viscosité limitée, une faible miscibilité avec la plupart des solvants communs, ou encore des propriétés d’agencement supramoléculaire, qui en font des outils puissants dans de nombreux domaines de la chimie. Les sels d’imidazolium représentent la plus grande famille de liquides ioniques à ce jour. Leur modulabilité leur permet d’être dérivés pour de nombreuses applications spécifiques, notamment en synthèse organique, où ils sont utilisés majoritairement comme solvants, et plus récemment comme catalyseurs. Les travaux présentés dans cette thèse se concentrent sur leur utilisation en synthèse organique, à la fois comme solvants et principalement comme catalyseurs chiraux, catalyseurs pour lesquels l’anion du sel est l’espèce catalytique, permettant d’ajouter de la flexibilité et de la mobilité au système. En tirant parti de la tolérance des liquides ioniques envers la majorité des macromolécules naturelles, l’objectif principal des travaux présentés dans cette thèse est le développement d’un nouveau type de catalyseur bio-hybride reposant sur l’encapsulation d’un sel d’imidazolium dans une protéine. Par le biais de la technologie biotine-avidine, l’inclusion supramoléculaire de sels d’imidazolium biotinylés portant des contre-anions catalytiques dans l’avidine a été réalisée et exploitée en catalyse. Dans un premier temps, le développement et l’étude de deux sels de 1-butyl-3-méthylimidazolium possédant des anions chiraux dérivés de la trans-4-hydroxy-L-proline sont rapportés, ainsi que leur comportement dans des réactions énantiosélectives d’aldol et d’addition de Michael. Ces types de composés se sont révélés actifs et performants en milieu liquide ionique. Dans un second temps, la préparation de sels d’imidazolium dont le cation est biotinylé et portant un contre-anion achiral, a été réalisée. Le comportement de l’avidine en milieu liquide ionique et son apport en termes de chiralité sur le système bio-hybride ont été étudiés. Les résultats montrent le rôle crucial des liquides ioniques sur la conformation de la protéine et l’efficacité du catalyseur pour des réactions d’aldol. Dans un dernier temps, l’influence de la structure du cation et de l’anion sur le système a été étudiée. Différents espaceurs ont été introduits successivement dans les squelettes cationiques et anioniques des sels d’imidazolium biotinylés. Dans le cas du cation, les résultats ne révèlent aucune influence majeure sur l’efficacité du catalyseur. La structure de l’anion se montre cependant beaucoup plus importante : la préparation de différents catalyseurs bio-hybrides possédant des anions aux propriétés physico-chimiques différentes a permis d’obtenir de plus amples informations sur le mode de fonctionnement du système bio-hybride et de la coopérativité entre l’avidine et l’anion du sel d’imidazolium.La nature ionique de la liaison cation-anion offrant une liberté de mouvement accrue à l’anion dans la protéine, la tolérance à différents substrats a également été abordée après optimisation du système.

Asymmetric aziridine synthesis by aza-Darzens reaction of N-diphenylphosphinylimines with chiral enolates. Part 2: inversion of diastereoselectivity

The aza-Darzens ('ADZ') reactions of N-diphenylphosphinyl ('N-Dpp') imines with chiral enolates derived from N-bromoacetyl 2S-2,10-camphorsultam proceed in generally good yield to give N-diphenylphosphinyl aziridinoyl sultams. However, the stereoselectivity of the reaction is dependent upon the structure of the imine substituent: when the chiral enolate was reacted with arylimines substituted in the ortho-position, mixtures of cis- and trans-2'R,3'R-aziridines were obtained, often with a complete selectivity in favour of the trans-isomer. (c) 2006 Elsevier Ltd. All rights reserved.

Synthesis and application of chiral beta-amino disulfides as ligands for the enantioselective addition of diethylzinc to aldehydes

A new class of chiral beta-amino disulfides was synthesized from readily available and inexpensive starting materials by a straightforward method and their abilities as ligands were examined in the enantioselective addition of diethylzinc to aldehydes. Enantiomeric excesses of up to 99% have been obtained using 0.5 mol % of the chiral catalysts.

Rhodium-Catalyzed Hydroboration: Directed Asymmetric Desymmetrization

Rhodium-catalyzed asymmetric hydroboration in conjunction with directing groups can be used control relative and absolute stereochemistry. Hydroboration has the potential to create new C–C, C–O, and C–N bonds from an intermediate C–B bond with retention of stereochemistry. Desymmetrization resulting in the loss of one or more symmetry elements can give rise to molecular chirality, i.e., the conversion of a prochiral molecule to one that is chiral. Unsaturated amides and esters hold the potential for two-point binding to the rhodium catalyst and have been shown to direct the regiochemistry and impact stereochemistry in asymmetric hydroborations of acyclic β,γ-unsaturated substrates. In the present study, the pendant amide functionality directs the hydroboration cis in the cyclic substrates studied; the corresponding ester substrates do so to a lesser extent. The enantioselectivity is determined by regioselective addition to the re or si site of the rhodium-complexed alkene. The effect of catalyst, ligand and borane on the observed diastereoselectivity and enantioselectivity for a variety of cyclopentenyl ester and amide substrates is discussed.

Stereoselective Catalytic Processes for the Synthesis of Polycyclic Aromatic Compounds

In this PhD-thesis, two methodologies for enantioselective intramolecular ring closing reaction on indole cores are presented. The first methodology represents a highly stereoselective alkylation of the indole N1-nitrogen, leading to 3,4-dihydro-pyrazinoindol-1-ones – a structural class which is known for its activity on the CNS and therefore of high pharmacological interest concerning related diseases. In this approach, N-benzyl cinchona-alkaloids were used for the efficient catalysis of intramolecular aza-Michael reactions. Furthermore, computational studies in collaboration with the research group Prof. Andrea Bottoni (Department of Chemistry “G. Ciamician”, Bologna) were accomplished in order to get insight into the key interactions between catalyst and substrate, leading to enantiomeric excesses up to 91%. The results of the calculations on a model system are in accordance with the experimental results and demonstrate the high sensibility of the system towards structural modifications. The second project deals with a metal catalyzed, intramolecular Friedel-Crafts (FC)-reaction on indolyl substrates, carrying a side chain which on its behalf is furnished with an allylic alcohol unit. Allylic alcohols are part of the structural class of “π-activated alcohols” – alcohols, which are more easily activated due to the proximity to a π-unit (allyl-, propargyl-, benzyl-). The enantioselective intramolecular cyclization event is catalyzed efficiently by employment of a chiral Au(I)-catalyst, leading to 1-vinyl- or 4-vinyl-tetrahydrocarbazoles (THCs) under the formation of water as byproduct. This striking and novel process concerning the direct activation of alcohols in catalytic FC-reactions was subsequently extended to similar precursors, leading to functionalized tetrahydro-β-carbolines. These two methodologies represent highly efficient approaches towards the synthesis of scaffolds, which are of enormous pharmaceutical interest and amplify the spectra of enantioselective catalytic functionalisations of indoles.

Asymmetric aminocatalysis: a modern strategy for molecules, challenges and life

The studies conducted during my Phd thesis were focused on two different directions: 1. In one case we tried to face some long standing problems of the asymmetric aminocatalysis as the activation of encumbered carbonyl compounds and the control of the diastereoisomeric ratio in the diastero- and enantioselective construction of all carbon substituted quaternary stereocenters adjacent a tertiary one. In this section (Challenges) was described the asymmetric aziridination of ,-unsaturated ketones, the activation of ,-unsaturated -branched aldehydes and the Michael addition of oxindoles to enals and enones. For the activation via iminium ion formation of sterically demanding substrates, as ,-unsaturated ketones and ,-unsaturated -branched aldehydes, we exploited a chiral primary amine in order to overcome the problem of the iminium ion formation between the catalyst and encumbered carbonylic componds. For the control of diastereoisomeric ratio in the diastero- and enantioselective construction of all carbon substituted quaternary stereocenters adjacent a tertiary one we envisaged that a suitable strategy was the Michael addition to 3 substituted oxindoles to enals activated via LUMO-lowering catalysis. In this synthetic protocol we designed a new bifunctional catalyst with an amine moiety for activate the aldehyde and a tioureidic fragment for direct the approach of the oxindole. This part of the thesis (Challenges) could be considered pure basic research, where the solution of the synthetic problem was the goal itself of the research. 2. In the other hand (Molecules) we applied our knowledge about the carbonylic compounds activation and about cascade reaction to the synthesis of three new classes of spirooxindole in enantiopure form. The construction of libraries of these bioactive compounds represented a scientific bridge between medicinal chemistry or biology and the asymmetric catalysis.

Development of Organocatalytic stereoselective SN1 type reactions

The proposal in my thesis has been the study of Stereoselective α-alkylation through SN1 type reaction. SN1 type reaction involves a stabilized and reactive carbocation intermediate By taking advantages of stability of particular carbocations, the use of carbocations in selective reactions has been important. In this work has been necessary to know the stability and reactivity of carbocations. And the work of Mayr group has helped to rationalize the behaviour and reactivity between the carbocations and nucleophiles by the use of Mayr’s scale of reactivity. The use of alcohols to performed the stable and reactive carbocations have been the key in my thesis. The direct nucleophilic substitution of alcohols has been a crucial scope in the field of organic synthesis, because offer a wide range of intermediates for the synthesis of natural products and pharmaceutics synthesis. In particular the catalytic nucleophilic direct substitution of alcohols represents a novel methodology for the preparation of a variety of derivatives, and water only as the sub-product in the reaction. The stereochemical control of the transformation C-H bond into stereogenic C-C bond adjacent to carbonyl functionalized has been studied for asymmetric catalysis. And the field of organocatalysis has introduced the use of small organic molecule as catalyst for stereoselective transformations. Merging these two concepts Organocatalysis and Mayr’s scale, my thesis has developed a new approach for the α-alkylation of aldehydes and ketones through SN1 type reaction.

Regiocontrolled Synthesis of Pyrazole Derivatives Through 1,3-Dipolar Cycloaddition Reaction And Synthesis of Helicene-Thiourea based and Polymer Supported Soos's Catalyst for Asymmetric Synthesis

In first part we have developed a simple regiocontrolled protocol of 1,3-DC to get ring fused pyrazole derivatives. These pyrazole derivatives were synthesized using 1,3-DC between nitrile imine and various dipolarophiles such as alkynes, cyclic α,β-ketones, lactones, thiocatones and lactums. The reactions were found to be highly regiospecific. In second part we have discussed about helicene, its properties, synthesis and applications as asymmetric catalyst.Due to inherent chirality, herein we have made an attempt to synthesize the helicene-thiourea based catalyst for asymmetric catalysis. The synthesis involved formation of two key intermediates viz, bromo-phenanthrene 5 and a vinyl-naphthalene 10. The coupling of these two intermediates leads to formation of hexahelicene.

Enantioselective Synthesis of Succinimides by Michael Addition of Aldehydes to Maleimides Organocatalyzed by Chiral Primary Amine-Guanidines

The monoguanylation of (1S,2S)- and (1R,2R)-cyclohexane-1,2-diamine affords chiral primary amine-guanidines that are used as chiral organocatalysts in the enantioselective Michael addition of aldehydes, particularly α,α-disubstituted aldehydes, to maleimides. The reaction is carried out in the presence of imidazole, as an additive, in aqueous N,N-dimethylformamide, as the solvent, and affords the corresponding enantioenriched succinimides in high or quantitative yields with enantioselectivities up to 96 % ee. Theoretical calculations (DFT and M06–2X) suggest a different hydrogen-bonding coordination pattern between the maleimide (C=O) and the catalyst (NH groups) is responsible for the enantioinduction switch that is observed when the reaction is carried out using primary amine-guanidines versus primary amine-thioureas as the organocatalysts.

Three-dimensional hydrogen-bonded structures in the guanidinium salts of the monocyclic dicarboxylic acids rac-trans-cyclohexane-1,2-dicarboxylic acid (2:1, anhydrous), isophthalic acid (1:1, monohydrate) and terephthalic acid (2:1, trihydrate).

The structures of bis(guanidinium)rac-trans-cyclohexane-1,2-dicarboxylate, 2(CH6N3+) C8H10O4- (I), guanidinium 3-carboxybenzoate monohydrate CH6N3+ C8H5O4- . H2O (II) and bis(guanidinium) benzene-1,4-dicarboxylate trihydrate, 2(CH6N3+) C8H4O4^2- . 3H2O (III) have been determined and the hydrogen bonding in each examined. All three compounds form three-dimensional hydrogen-bonded framework structures. In anhydrous (I), both guanidinium cations give classic cyclic R2/2(8) N--H...O,O'(carboxyl) and asymmetric cyclic R1/2(6) hydrogen-bonding interactions while one cation gives an unusual enlarged cyclic interaction with O acceptors of separate ortho-related carboxyl groups [graph set R2/2(11)]. Cations and anions also associate across inversion centres giving cyclic R2/4(8) motifs. In the 1:1 guanidinium salt (II), the cation gives two separate cyclic R1/2(6) interactions, one with a carboxyl O-acceptor, the other with the water molecule of solvation. The structure is unusual in that both carboxyl groups give short inter-anion O...H...O contacts, one across a crystallographic inversion centre [2.483(2)\%A], the other about a two-fold axis of rotation [2.462(2)\%A] with a half-occupancy hydrogen delocalized on the symmetry element in each. The water molecule links the cation--anion ribbon structures into a three-dimensional framework. In (III), the repeating molecular unit comprises a benzene-1,4-dicarboxylate dianion which lies across a crystallographic inversion centre, two guanidinium cations and two water molecules of solvation (each set related by two-fold rotational symmetry), and a single water molecule which lies on a two-fold axis. Each guanidinium cation gives three types of cyclic interactions with the dianions: one R^1^~2~(6), the others R2/3(8) and R3/3(10) (both of these involving the water molecules), giving a three-dimensional structure through bridges down the b cell direction. The water molecule at the general site also forms an unusual cyclic R2/2(4) homodimeric association across an inversion centre [O--H...O, 2.875(2)\%A]. The work described here provides further examples of the common cyclic guanidinium cation...carboxylate anion hydrogen-bonding associations as well as featuring other less common cyclic motifs.

Isolation, structure determination and cytotoxicity studies of tryptophan alkaloids from an Australian marine sponge Hyrtios sp

Mass-guided fractionation of the MeOH extract from a specimen of the Australian marine sponge Hyrtios sp. resulted in the isolation of two new tryptophan alkaloids, 6-oxofascaplysin (2), and secofascaplysic acid (3), in addition to the known metabolites fascaplysin (1) and reticulatate (4). The structures of all molecules were determined following NMR and MS data analysis. Structural ambiguities in 2 were addressed through comparison of experimental and DFT-generated theoretical NMR spectral values. Compounds 1–4 were evaluated for their cytotoxicity against a prostate cancer cell line (LNCaP) and were shown to display IC50 values ranging from 0.54 to 44.9 μM.