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Innovative Methods for the Catalyzed Construction of Carbon-Carbon and Carbon-Hydrogen BondsMahoney, Stuart James January 2012 (has links)
The selective transformation of carbon-carbon and carbon-hydrogen bonds represents an attractive approach and rapidly developing frontier in synthesis. Benefits include step and atom economy, as well as the ubiquitous presence in organic molecules. Advances to this exciting realm of synthesis are described in this thesis with an emphasis on the development of catalytic, selective reactions under mild conditions. Additionally some applications of the methodologies are demonstrated.
In Chapter 1, the first examples of inter-and intramolecular enantioselective conjugate alkenylations employing organostannanes are reported. A chiral, cationic Rh(I)-diene complex catalyzed the enantioselective conjugate addition of alkenylstannanes to benzylidene Meldrum’s acids in moderate enantiomeric ratios and yields. Notably, the cationic and anhydrous conditions required for the asymmetric alkenylation are complementary to existing protocols employing other alkenylmetals.
In Chapter 2, a domino, one-pot formation of tetracyclic ketones from benzylidene Meldrum’s acids using Sc(OTf)3 via a [1,5]-hydride shift/cyclization/Friedel-Crafts acylation sequence is described. Respectable yields were obtained in accord with the ability to convert to the spiro-intermediate, and considering the formation of three new bonds: one C-H and two C-C bonds. An intriguing carbon-carbon bond cleavage was also serendipitously discovered as part of a competing reaction pathway.
In Chapter 3, the pursuit of novel C-H bond transformations led to the development of non-carbonyl-stabilized rhodium carbenoid Csp3-H insertions. This methodology enabled the rapid synthesis of N-fused indolines and related complex heterocycles from N-aziridinylimines. By using a rhodium carboxamidate catalyst, competing processes were minimized and C-H insertions were found to proceed in moderate to high yields. Also disclosed is an expedient total synthesis of (±)-cryptaustoline, a dibenzopyrrocoline alkaloid, which highlights the methodology.
In Chapter 4, the Lewis acid promoted substitution of Meldrum’s acid discovered during the course of the domino reaction was explored in detail. The protocol transforms unstrained quaternary and tertiary benzylic Csp3-Csp3 bonds into Csp3-X bonds (X = C, N, H) and has even shown to be advantageous with regards to synthetic utility over the use of alternative leaving groups for substitutions at quaternary benzylic centers. This reaction has a broad scope both in terms of suitable substrates and nucleophiles with good to excellent yields obtained (typically >90%).
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Nouvelles applications de paires d'ions coopératifs chirales en organocatalyse : utilisations dans des réactions mettant en jeu l'acide de Meldrum et ses dérivés. / New applications of chiral pairs of cooperative ions in organocatalysis : applications in reactions involving Meldrum acid ans its derivativesLegros, Fabien 17 November 2017 (has links)
Les travaux présentés dans ce manuscrit de thèse concernent la mise au point de nouvelles méthodologies de synthèse asymétrique en organocatalyse promues par des phénolates d’ammoniums quaternaires, catalyseurs de type paires d’ions coopératifs chirales, et des dérivés de l’acide de Meldrum comme substrats. Dans un premier temps, nous avons utilisé l’acide de Meldrum comme un précurseur de cétène via une cycloréversion induite par O-silylation grâce à une probase silylée, afin de réaliser une réaction de cycloaddition [2+2] avec un aldéhyde ou une imine catalysée par un phénolate d’ammonium chiral, permettant de former des β-lactones et des β-lactames. Les travaux effectués n’ont cependant pas permis d’obtenir le produit désiré. Dans un secont temps, nous avons exploité le caractère électrophile des dérivés disubstitués de l’acide de Meldrum et leur capacité à fragmenter suite à l’addition nucléophile d’un phénolate. Une première partie a été consacrée au développement d’une réaction monotope de désymétrisation de l’acide de Meldrum pour former des malonates dissymétriques après une étape d’alkylation in situ du carboxylate intermédiaire. Bien que de bons rendements isolés aient été obtenus, un maximum de 21% ee a pu seulement être atteint. Dans une seconde partie, nous avons mis au point une séquence originale, catalysée par un phénolate d’ammonium quaternaire chiral, qui est constituée (1) d’une addition nucléophile de phénolate suivie (2) d’une fragmentation avec perte d’acétone qui permet, après (3) une étape de décarboxylation de générer un acétal de cétène acyclique qui va subir (4) une réaction de protonation énantiosélective. Cette méthode a pu être appliquée à un large panel de substrats avec de bons rendements et des excès énantiomériques allant jusqu’à 70% ee. / The work developed in this PhD thesis deals with the development of new asymmetric organocatalytic methodologies implying cooperative chiral ion pairing catalysis, by using chiral ammonium phenoxides as catalysts and Meldrum’s acid derivatives as substrates. First, we used the ability of Meldrum’s acid to generate acylketenes after cycloversion triggered by O-silylation thanks to a silylated probase in the presence of a chiral ammonium phenoxide. Such an approach was applied to the synthesis of β-lactones and β-lactames following a [2+2] cycloaddition reaction with aldehydes or imines respectively. Unfortunately, the desired products have never been observed. Then, we focused on disubstitued derivatives of Meldrum’s acids and their propensity to fragment after a nucleophilic addition of phenoxide. In a first part, we have developed a one-pot desymmetrization reaction of Meldrum’s acid derivatives to form dissymmetric malonates after an in-situ alkylation of the transient carboxylate. However, despite high isolated yields, only an unsatisfactory 21% ee could be reached. In a second part, we have developed an unprecedented sequence consisting of (1) a nucleophilic addition of phenol derivatives to Meldrum’s acid followed by (2) a fragmentation with loss of acetone, leading after (3) decaboxylation to the formation of an acyclic ketene acetal which is involved in (4) an enantioselective protonation reaction to provide a wide range of enantioenriched phenolic esters with moderate to excellent yield and up to 70% ee.
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