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1	Réactions de cycloisomérisation catalysées par des complexes d’argent ou de rhodium pour accéder à des dérivés de furoquinoléine, pyranoquinoléine et dibenzofurane / Silver and rhodium-catalyzed cycloisomerization reactions leading to furoquinolines, pyranoquinolines and dibenzofurans Parker, Évelyne 16 December 2010 (has links) Ce mémoire de thèse est composé de deux parties distinctes ayant comme thématique commune, les réactions de cycloisomérisation. Nous nous sommes intéressés dans un premier temps au développement d’une réaction tandem d’acétalisation / cycloisomérisation catalysée par des sels d’argents. Cette méthodologie nous a permis d’accéder sélectivement aux familles des furoquinoléines et des pyranoquinoléines. Ces composés ont été testés comme agents antipaludiques et ont donné des résultats prometteurs. Une gamme de dérivés de furoquinoléine a également donné des activités cytotoxiques intéressantes. L’étude de leur potentielle activité antitumorale s’inscrit dans le cadre d’un projet financé par la Ligue Nationale contre le Cancer. Une étude approfondie de la réaction tandem, nous a permis de mettre en évidence l’influence de composés azotés sur le comportement du sel d’argent. Cette caractéristique nous a conduits à catalyser nos réactions grâce à un complexe inusité jusqu’alors en catalyse organométallique : l’imidazolate d’argent. Dans un deuxieme temps, nous avons étudié une réaction de benzannélation catalysée par des sels de rhodium ou d’argent. La stratégie de synthèse implique des systèmes de type benzofurane, porteurs d’énynes fonctionnalisées par un éther d’énol silylé, et conduit à des dérivés de dibenzofuranes. Ces hétérocycles, connus pour être biologiquement actifs, présentent un intérêt particulier dans la chimie thérapeutique. Nous avons également travaillé sur des indoles et avons pu synthétiser des dérivés d’oxindole originaux / Among a variety of new synthetic transformations, transition-metal-catalyzed reactions are some of the most attractive methodologies for synthesizing heterocyclic compounds. In this context, two different cycloisomerization reactions are studied. We first developed an efficient and versatile access to pyranoquinoline and furoquinoline derivatives, thanks to a tandem silver-catalyzed acetalization /cycloisomerization reaction. The synthesized compounds presented interesting antimalarial activity when tested on a resistant strain of the parasite Plasmodium Falciparum. The antitumoral activity of some furoquinolines was also investigated within a project funded by the French National League Against Cancer. Interestingly, we noticed that the regioselectivity of the cyclization can be controlled depending on the type of silver catalyst used. The observed reaction regioselectivity, including also an interesting nitrogen effect, led us to develop a silver imidazolate polymer as a stable and new silver catalyst. We also described a rhodium-catalyzed benzannulation reaction of silyl-enol-ethers onto alkynes, leading to dibenzofurans derivatives. These heterocycles are well-known for their biological properties and their interest in therapeutic chemistry. Finally, we developed an original methodology for the synthesis of oxindole derivatives Cycloisomérisation Acétalisation 6-endo-dig 5-exo-dig Benzannélation Argent Rhodium Catalyse Cycloisomerization Acetalization 6-endo-dig 5-exo-dig Benzannulation Silver Rhodium Catalysis 547.2
2	Development of New Biarylphosphane Coinage Metal Complexes for the Regioselective Synthesis of Fused Carbocycles Levesque, Patrick Pierre 02 October 2012 (has links) In the last century, no less than five nobel prizes have been awarded for the construction of carbon-carbon bonds : The Grignard reaction (1912), the Diels-Alder reaction (1950), the Wittig reaction (1979), Olefin metathesis (2005) and palladium cross-coupling reactions (2011). The latter two are transition metal catalyzed transformations and their impact on the synthesis of pharmaceutically active compounds, bulk chemicals, fine chemicals, high tech materials as well as agricultural chemicals has been phenomenal. These reactions have changed the way the scientific community views the science of synthesis. Unlike palladium, gold has long been considered to be an expensive and inert metal and therefore, research on Au catalysis was scarse until the begining of the new millenium. Once the scientific community realized the treasure trove of reactivity that gold had to offer, the number of chemical transformations as well as total syntheses involving Au(I)/Au(III) catalysis has sky rocketed. A methodology initially developped by Toste and coworkers has shown that intramolecular addition of a silyl enol ether on alkynes proceeds via a 5-exo¬-dig¬ process. In the first part of this thesis, we will discuss how the ancilary ligand on Au(I) species can influence pathway selectivity for these cyclizations, therefore opening the door to selective 6-endo-dig cyclizations to generate fused carbocycles. With biological processes as well as other competing processes becoming ever more efficient, the future of chemical synthesis is threatened. If it is to survive, the focus of new chemical transformations will have to be on the cost and the greeness of the process. In the second part of this thesis, we will demonstrate how Ag(I) and Cu(I) complexes can offer even better 6-endo-dig¬ selectivity than analogous Au(I) complexes. Silver is about 56 times less expensive than gold, and copper is about 453 times less expensive than gold. Due to the greatly increased selectivity as well as the diminished cost of the catalysts, we have provided access to an attractive 6-endo-dig¬ cyclization process. Biarylphosphane Gold catalysis Silver catalysis Copper catalysis 6 endo-dig 5-exo dig Carbocycly synthesis
3	Development of the 5-exo-dig/Prins Reaction and Efforts towards the Total Synthesis of (±)-Magellanine Bétournay, Geneviève L. 02 November 2012 (has links) Gold catalysis has attracted much attention within the chemical community in recent years, and its importance as a synthetic tool has only started to be uncovered. This thesis describes the development of a gold(I) catalyzed transformation and its application to the synthesis of a structurally unique Lycopodium alkaloid, Magellanine. Although there have been a few reports on the synthesis of the magellanane core to date, the approach described herein would represent a new and efficient strategy to construct the angularly fused tetracyclic core. The 5 exo dig/Prins reaction that would be the key step of the synthesis was first developed and studied on a model substrate, enabling the verification of the hypothesis that this transformation could indeed form the A and B rings of Magellanine and be applied to its synthesis. This reaction formed the tricyclic products in good yields and in good exo:endo ratios. The synthesis of Magellanine was undertaken, but problems of isomerization prevented the synthesis of the desired 5 exo dig/Prins substrate, which contained the C and D rings of Magellanine with a cis relationship at the ring junction. However, an almost identical substrate, save for a trans configuration between the C and D rings instead of the cis configuration, was prepared and served in further establishing the applicability of this methodology to the synthesis of Magellanine by successfully undergoing the 5-exo-dig/Prins reaction and generating the tetracyclic products. Studies of the steps following the key transformation were performed on the model substrate, allowing for the evaluation of these steps prior to their use in the synthesis. The results of the studies indicate a possible need to revisit the order in which the steps should be carried out. Promising solutions to the different obstacle encountered during the work are presented, demonstrating how the synthesis of Magellanine through a route featuring the 5-exo-dig/Prins cyclization is attainable. 5-exo-dig Prins Gold catalysis Synthesis Magellanine magellanane alkaloids Lycopodium alkaloids Organic
4	Development of New Biarylphosphane Coinage Metal Complexes for the Regioselective Synthesis of Fused Carbocycles Levesque, Patrick Pierre 02 October 2012 (has links) In the last century, no less than five nobel prizes have been awarded for the construction of carbon-carbon bonds : The Grignard reaction (1912), the Diels-Alder reaction (1950), the Wittig reaction (1979), Olefin metathesis (2005) and palladium cross-coupling reactions (2011). The latter two are transition metal catalyzed transformations and their impact on the synthesis of pharmaceutically active compounds, bulk chemicals, fine chemicals, high tech materials as well as agricultural chemicals has been phenomenal. These reactions have changed the way the scientific community views the science of synthesis. Unlike palladium, gold has long been considered to be an expensive and inert metal and therefore, research on Au catalysis was scarse until the begining of the new millenium. Once the scientific community realized the treasure trove of reactivity that gold had to offer, the number of chemical transformations as well as total syntheses involving Au(I)/Au(III) catalysis has sky rocketed. A methodology initially developped by Toste and coworkers has shown that intramolecular addition of a silyl enol ether on alkynes proceeds via a 5-exo¬-dig¬ process. In the first part of this thesis, we will discuss how the ancilary ligand on Au(I) species can influence pathway selectivity for these cyclizations, therefore opening the door to selective 6-endo-dig cyclizations to generate fused carbocycles. With biological processes as well as other competing processes becoming ever more efficient, the future of chemical synthesis is threatened. If it is to survive, the focus of new chemical transformations will have to be on the cost and the greeness of the process. In the second part of this thesis, we will demonstrate how Ag(I) and Cu(I) complexes can offer even better 6-endo-dig¬ selectivity than analogous Au(I) complexes. Silver is about 56 times less expensive than gold, and copper is about 453 times less expensive than gold. Due to the greatly increased selectivity as well as the diminished cost of the catalysts, we have provided access to an attractive 6-endo-dig¬ cyclization process. Biarylphosphane Gold catalysis Silver catalysis Copper catalysis 6 endo-dig 5-exo dig Carbocycly synthesis
5	Development of the 5-exo-dig/Prins Reaction and Efforts towards the Total Synthesis of (±)-Magellanine Bétournay, Geneviève L. 02 November 2012 (has links) Gold catalysis has attracted much attention within the chemical community in recent years, and its importance as a synthetic tool has only started to be uncovered. This thesis describes the development of a gold(I) catalyzed transformation and its application to the synthesis of a structurally unique Lycopodium alkaloid, Magellanine. Although there have been a few reports on the synthesis of the magellanane core to date, the approach described herein would represent a new and efficient strategy to construct the angularly fused tetracyclic core. The 5 exo dig/Prins reaction that would be the key step of the synthesis was first developed and studied on a model substrate, enabling the verification of the hypothesis that this transformation could indeed form the A and B rings of Magellanine and be applied to its synthesis. This reaction formed the tricyclic products in good yields and in good exo:endo ratios. The synthesis of Magellanine was undertaken, but problems of isomerization prevented the synthesis of the desired 5 exo dig/Prins substrate, which contained the C and D rings of Magellanine with a cis relationship at the ring junction. However, an almost identical substrate, save for a trans configuration between the C and D rings instead of the cis configuration, was prepared and served in further establishing the applicability of this methodology to the synthesis of Magellanine by successfully undergoing the 5-exo-dig/Prins reaction and generating the tetracyclic products. Studies of the steps following the key transformation were performed on the model substrate, allowing for the evaluation of these steps prior to their use in the synthesis. The results of the studies indicate a possible need to revisit the order in which the steps should be carried out. Promising solutions to the different obstacle encountered during the work are presented, demonstrating how the synthesis of Magellanine through a route featuring the 5-exo-dig/Prins cyclization is attainable. 5-exo-dig Prins Gold catalysis Synthesis Magellanine magellanane alkaloids Lycopodium alkaloids Organic
6	Development of New Biarylphosphane Coinage Metal Complexes for the Regioselective Synthesis of Fused Carbocycles Levesque, Patrick Pierre January 2012 (has links) In the last century, no less than five nobel prizes have been awarded for the construction of carbon-carbon bonds : The Grignard reaction (1912), the Diels-Alder reaction (1950), the Wittig reaction (1979), Olefin metathesis (2005) and palladium cross-coupling reactions (2011). The latter two are transition metal catalyzed transformations and their impact on the synthesis of pharmaceutically active compounds, bulk chemicals, fine chemicals, high tech materials as well as agricultural chemicals has been phenomenal. These reactions have changed the way the scientific community views the science of synthesis. Unlike palladium, gold has long been considered to be an expensive and inert metal and therefore, research on Au catalysis was scarse until the begining of the new millenium. Once the scientific community realized the treasure trove of reactivity that gold had to offer, the number of chemical transformations as well as total syntheses involving Au(I)/Au(III) catalysis has sky rocketed. A methodology initially developped by Toste and coworkers has shown that intramolecular addition of a silyl enol ether on alkynes proceeds via a 5-exo¬-dig¬ process. In the first part of this thesis, we will discuss how the ancilary ligand on Au(I) species can influence pathway selectivity for these cyclizations, therefore opening the door to selective 6-endo-dig cyclizations to generate fused carbocycles. With biological processes as well as other competing processes becoming ever more efficient, the future of chemical synthesis is threatened. If it is to survive, the focus of new chemical transformations will have to be on the cost and the greeness of the process. In the second part of this thesis, we will demonstrate how Ag(I) and Cu(I) complexes can offer even better 6-endo-dig¬ selectivity than analogous Au(I) complexes. Silver is about 56 times less expensive than gold, and copper is about 453 times less expensive than gold. Due to the greatly increased selectivity as well as the diminished cost of the catalysts, we have provided access to an attractive 6-endo-dig¬ cyclization process. Biarylphosphane Gold catalysis Silver catalysis Copper catalysis 6 endo-dig 5-exo dig Carbocycly synthesis
7	Development of the 5-exo-dig/Prins Reaction and Efforts towards the Total Synthesis of (±)-Magellanine Bétournay, Geneviève L. January 2012 (has links) Gold catalysis has attracted much attention within the chemical community in recent years, and its importance as a synthetic tool has only started to be uncovered. This thesis describes the development of a gold(I) catalyzed transformation and its application to the synthesis of a structurally unique Lycopodium alkaloid, Magellanine. Although there have been a few reports on the synthesis of the magellanane core to date, the approach described herein would represent a new and efficient strategy to construct the angularly fused tetracyclic core. The 5 exo dig/Prins reaction that would be the key step of the synthesis was first developed and studied on a model substrate, enabling the verification of the hypothesis that this transformation could indeed form the A and B rings of Magellanine and be applied to its synthesis. This reaction formed the tricyclic products in good yields and in good exo:endo ratios. The synthesis of Magellanine was undertaken, but problems of isomerization prevented the synthesis of the desired 5 exo dig/Prins substrate, which contained the C and D rings of Magellanine with a cis relationship at the ring junction. However, an almost identical substrate, save for a trans configuration between the C and D rings instead of the cis configuration, was prepared and served in further establishing the applicability of this methodology to the synthesis of Magellanine by successfully undergoing the 5-exo-dig/Prins reaction and generating the tetracyclic products. Studies of the steps following the key transformation were performed on the model substrate, allowing for the evaluation of these steps prior to their use in the synthesis. The results of the studies indicate a possible need to revisit the order in which the steps should be carried out. Promising solutions to the different obstacle encountered during the work are presented, demonstrating how the synthesis of Magellanine through a route featuring the 5-exo-dig/Prins cyclization is attainable. 5-exo-dig Prins Gold catalysis Synthesis Magellanine magellanane alkaloids Lycopodium alkaloids Organic
8	Réactions de cycloisomérisation catalysées par des complexes d'argent ou de rhodium pour accéder à des dérivés de furoquinoléine, pyranoquinoléine et dibenzofurane Parker, Évelyne 16 December 2010 (has links) (PDF) Ce mémoire de thèse est composé de deux parties distinctes ayant comme thématique commune, les réactions de cycloisomérisation. Nous nous sommes intéressés dans un premier temps au développement d'une réaction tandem d'acétalisation / cycloisomérisation catalysée par des sels d'argents. Cette méthodologie nous a permis d'accéder sélectivement aux familles des furoquinoléines et des pyranoquinoléines. Ces composés ont été testés comme agents antipaludiques et ont donné des résultats prometteurs. Une gamme de dérivés de furoquinoléine a également donné des activités cytotoxiques intéressantes. L'étude de leur potentielle activité antitumorale s'inscrit dans le cadre d'un projet financé par la Ligue Nationale contre le Cancer. Une étude approfondie de la réaction tandem, nous a permis de mettre en évidence l'influence de composés azotés sur le comportement du sel d'argent. Cette caractéristique nous a conduits à catalyser nos réactions grâce à un complexe inusité jusqu'alors en catalyse organométallique : l'imidazolate d'argent. Dans un deuxieme temps, nous avons étudié une réaction de benzannélation catalysée par des sels de rhodium ou d'argent. La stratégie de synthèse implique des systèmes de type benzofurane, porteurs d'énynes fonctionnalisées par un éther d'énol silylé, et conduit à des dérivés de dibenzofuranes. Ces hétérocycles, connus pour être biologiquement actifs, présentent un intérêt particulier dans la chimie thérapeutique. Nous avons également travaillé sur des indoles et avons pu synthétiser des dérivés d'oxindole originaux [CHIM:OTHE] Chemical Sciences/Other [CHIM:OTHE] Chimie/Autre Cycloisomérisation Acétalisation 6-endo-dig 5-exo-dig Benzannélation Argent Rhodium Catalyse

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