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Mechanistic Investigation, Development and Synthetic Applications of a Catalytic Enantioselective and Diastereoselective Allylboration MethodologyRauniyar, Vivek 11 1900 (has links)
Over the past two decades and continuing on, carbonyl allylation chemistry has been a very useful and popular tool for the stereocontrolled formation of carbon-carbon bonds in the field of organic synthesis. In the context of natural product synthesis, the efficiency and status of aldehyde allylboration method is only matched by the asymmetric and diastereoselective aldol methodology. Unfortunately, prior to the new millennium, the means to control the absolute stereoselectivity in the addition of allylic boron reagents had been restricted to stoichiometric chiral directors, appended onto the metal center. In 2002, the research groups of Hall and Miyaura reported a new Lewis acid-catalyzed allylboration reaction manifold, which raised intriguing mechanistic questions and also paved the way for a catalytic enantioselective methodology development.
Chapter 2 of this thesis details mechanistic studies related to the new Lewis acid-catalyzed allylboration. In this chapter, various control experiments and kinetic studies are presented, the results of which allowed us to propose a hypothesis involving the electrophilic boronate activation as the key factor for the observed rate enhancement.
Chapter 3 describes the initial phase of our research to develop a catalytic enantioselective allylboration methodology. We discovered that Brnsted acid catalysts derived from diolSnCl4 complexes were promising catalysts for the asymmetric addition of air and moisture stable and commercially available allylic pinacol boronates. Under this 1st generation catalyst-system, the corresponding homoallylic alcohols were obtained in moderate to good enantioselectivity and excellent diastereoselectivity.
The development of a novel chiral Brnsted acid catalyst for the highly enantio- and diastereoselective allylboration reaction methodology is the single most important result to come from this thesis. Chapter 4 outlines the development of the 2nd generation catalyst system. A systematic study of the diol component of the catalyst system led us to arrive at a novel diol nicknamed Vivol on behalf of my contribution. The resulting Brnsted acid derived from VivolSnCl4 now provided the corresponding homoallylic alcohol products in very good to excellent enantioselectivity. Preliminary mechanistic studies along with the X-ray diffraction structure of the catalyst system are also presented. Based on this information, an even better performaning diol (termed F-Vivol) was developed. This 3rd generation catalyst system derived from F-VivolSnCl4 complex was shown to display consistently superior reactivity and selectivity over its 2nd generation predecessor.
Chapter 5 describes our efforts to expand the reagent scope of the Brnsted acid catalyzed allylboration methodology. Furthermore, this chapter also describes the successful application of the catalytic process towards the synthesis of simple and complex molecules. Accordingly, the preparation and application of the Brnsted acid-catalyzed addition of 2-bromoallyl boron pinacolate is described. The successful transformation of the corresponding bromo-homoallylic alcohols to a compelling class of -butyrolactones is also presented. The later part of the Chapter presents the synthesis of natural products (+) dodoneine and palmerolide A.
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Mechanistic Investigation, Development and Synthetic Applications of a Catalytic Enantioselective and Diastereoselective Allylboration MethodologyRauniyar, Vivek Unknown Date
No description available.
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Étude et applications du réarrangement sigmatropique [3,3] d'allyl cyanates pour la synthèse de molécules d'intêret biologique / Study and applications of [3,3] sigmatropic rearrangement of allyl cyanates for the synthesis of molecules of biological interest.Henrion, Sylvain 19 December 2017 (has links)
De nos jours, parmi toutes les transformations chimiques dont disposent les chimistes organiciens, le réarrangement sigmatropique [3,3] constitue un outil puissant afin de créer une liaison C-C ou encore C-hétéroatome. Le réarrangement d’allyl cyanate en allyl isocyanate, jusqu’ici peu utilisé, est en train d’émerger, comme une nouvelle méthode efficace de préparation d’allylamines substituées. C’est dans ce contexte que s’inscrit mon travail de thèse qui a pour objectif d’étudier et d’utiliser le réarrangement sigmatropique [3,3] d’allyl cyanates diversement substitués pour la synthèse de molécules d’intérêt biologique. Dans une première partie, l’emploi d’allyl cyanates borylés nous a permis de synthétiser, de façon stéréocontrôlée, des ènecarbamates et des ènehydroxyurées cycliques à 7 chainons ainsi que des γ-butyrolactones. Cette méthodologie a été appliquée à la première synthèse totale de la (-)-Galbacin. Les ènecarbamates cycliques ont fait l’objet, en seconde partie, d’une étude structure-activité en tant qu’inhibiteur du protéasome humain. Dans une troisième partie, nous avons étudié le réarrangement d’allyl cyanates silylés ce qui nous a permis d’accéder à des α-amino allylsilanes énantioenrichis. En dernière partie, nous avons mis en évidence un oxo-réarrangement à partir d’allyl carbamates substitués par un groupement aryle. / Nowadays, among all chemical transformations in the organic chemist’s toolbox, [3,3] sigmatropic rearrangements represent a powerful method to create carbon-carbon or even carbon-heteroatom bonds. The allyl cyanate to allyl isocyanate rearrangement, underused so far, is becoming an attractive method to prepare substituted allylamines. In this context, I studied and applied in my thesis this [3,3] rearrangement on diversely substituted allyl cyanates for the synthesis of molecules of biological interest. First, we used borylated allyl cyanates to prepare, stereoselectively, cyclic seven membered enecarbamates and enehydroxyureas as well as γ-butyrolactones. This methodology was applied to the first total synthesis of (-)-Galbacin. Then, a library of cyclic enecarbamates was performed to study the structure-activity relationship on the human proteasome. Next, the study of silylated allyl cyanates allowed us to prepare some new enantioenriched α-amino allylsilanes. Finally, we brought to light an unexpected oxo-rearrangement from aryl substituted allyl carbamates.
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