Mise au point de réactions tandems catalytiques incluant une étape d'isomérisation pour la synthèse de molécules naturelles

Limiter la perte d'atomes, privilégier l'usage de catalyseurs, s'abstenir de l'utilisation de réactifs toxiques et éviter les étapes de purifications sont certains des challenges de la chimie moderne. De nombreuses recherches ont donc été consacrées au développement de réactions dites ''tandems''. La réaction d'isomérisation d'alcène permet dans certains cas de générer une toute nouvelle réactivité au sein d'une molécule, en déplaçant une double liaison. Cette réaction requiert souvent un catalyseur de type hydrure avec un métal de transition. Ce mémoire décrit la mise au point de nouvelles réactions ''tandems'' dont l'une des composantes mise en jeu est une réaction isomérisation d'oléfine. Une attention toute particulière a été adressée à la synthèse de vinylboronates notamment par métathèse croisée. Outre les nombreuses applications en synthèse organique qui sont présentées dans ce mémoire, ces intermédiaires peuvent être isomérisés en allylboronates. Ces derniers peuvent réagir avec un aldéhyde pour donner des alcools homoallyliques avec une complète diastéréosélectivité. Ces alcools ont, entre autres, été utilisés en synthèse totale de plusieurs molécules naturelles complexes présentant un motif 2,3-dihydrobenzofurane.Some of the new challenges of modern synthetic chemistry are: atom economy, employment of catalytic processes, avoidance of toxic reactants and limitation of purification steps. A lot of work has been devoted to the development of tandem reactions. A new reactivity could be generated in a molecule thanks to an isomerisation (or migration) reaction of an alkene. This reaction often needs an hydride specie which comes from a transition metal catalyst. This PhD thesis is about the development of new tandem reactions in which at least one step is an isomerisation of an olefin. A great attention has been dedicated to the synthesis of vinylboronates especially with a cross-metathesis strategy. These intermediates are of great importance in organic chemistry and can be useful in a wide range of reactions. One of those reactions is the transformation of vinylboronates to allylboronates thanks to an isomerisation step. Allylboronates can then react with aldehydes to generate homoallylic alcohols with total diastereoselectivity. These new reactions have found applications in total synthesis of natural molecules with a 2,3-dihydrobenzofuran core.RENNES1-Bibl. électronique (352382106) / SudocSudocFranceF

Synthesis of alkenyl boronates from allyl-substituted aromatics using an olefin cross-metathesis protocol.

International audienceAn efficient synthesis of 3-aryl-1-propenyl boronates from pinacol vinyl boronic ester and allyl-substituted aromatics by cross metathesis is reported. Although the allylbenzene derivatives are prone to isomerization reaction under metathesis conditions, we found that some ruthenium catalysts are effective for this methodology. This strategy thus provides an interesting alternative approach to alkyne hydroboration, leading to the preparation of unknown compounds. Moreover, the boron substituent can be replaced by various functional groups in good yields

A Diastereoselective Route to trans-​2-​Aryl-​2,​3-​dihydrobenzofurans through Sequential Cross-​Metathesis​/Isomerization​/Allylboration Reactions: Synthesis of Bioactive Neolignans

International audienceA new highly diastereoselective synthetic route to trans-2,3-dihydrobenzofuran systems, in particular those bearing an aryl substituent at the C2 position, is described. The cornerstone of our strategy is the implementation of a cross-metathesis/isomerization/allylboration sequence starting from 2-allyl-substituted phenols and aldehydes. After an intramolecular Mitsunobu cyclization step, the anti-homoallylic alcohols allow the synthesis of the desired skeleton in a stereoselective fashion. As an illustration, we used this strategy for the preparation of the dihydrodehydrodiconiferyl alcohol (1a), a natural dihydrobenzofuran neolignan, as well as for a formal synthesis of its O-demethylated derivative 1b. An enantioselective version of this approach employing a chiral phosphoric acid in the allylboration step is also studied

Cross-metathesis/isomerization/allylboration sequence for a diastereoselective synthesis of anti-homoallylic alcohols from allylbenzene derivatives and aldehydes.

International audienceWe describe a highly diastereoselective approach to anti-homoallylic alcohols from allylbenzene derivatives and aldehydes. The strategy is based on a cross-metathesis/isomerization/allylboration sequence catalyzed successively by ruthenium and iridium. This methodology provides another way to access this class of compounds, which leads to the preparation of hitherto-unknown homoallylic alcohols without the requirement to control the stereochemistry of the 1-alkenyl boronate intermediates. Our study towards an enantioselective version of this sequential reaction is also reported

Synthesis of Alkenyl Boronates from Allyl-Substituted Aromatics Using an Olefin Cross-Metathesis Protocol

An efficient synthesis of 3-aryl-1-propenyl boronates from pinacol vinyl boronic ester and allyl-substituted aromatics by cross metathesis is reported. Although the allylbenzene derivatives are prone to isomerization reaction under metathesis conditions, we found that some ruthenium catalysts are effective for this methodology. This strategy thus provides an interesting alternative approach to alkyne hydroboration, leading to the preparation of unknown compounds. Moreover, the boron substituent can be replaced by various functional groups in good yields

Introduction of the 4,4,4-Trifluorobut-2-ene Chain Exploiting a Regioselective Tsuji–Trost Reaction Catalyzed by Palladium Nanoparticles

A palladium-nanoparticle-catalyzed Tsuji–Trost reaction of 4,4,4-trifluorobut-2-en-1-yl acetate and ethyl­(4,4,4-trifluorobut-2-en-1-yl)­carbonate was accomplished with various nucleophiles including phenols, amines, and malonates. In the case of the phenols, isomerization of the double bond in the product (up to 20%) was observed as a side reaction. Further synthetic transformations including hydrogenation, the Diels–Alder reaction, and asymmetric dihydroxylation of a product were also examined