New approaches to the syntheses of nikkomycin B and hypoglycin A

Gair, Susan

January 1997

No description available.

547

Organozinc reagents; Amino acids

Cobalt-catalyzed carbon-carbon bond formation by activation of carbon-halogen or carbon-hydrogen bonds / Formation de liaisons carbone-carbone catalysée par le cobalt par activation de liaisons carbone-halogène ou carbone-hydrogène

Cai, Yingxiao

22 September 2016

Ce travail de thèse présente le développement de nouvelles réactions de formation de liaisons carbone-carbone. Le premier chapitre décrit la cyanation d’arylzinciques par catalyse au cobalt à partir d’une source non toxique et bénigne, le N-cyano-N-phenyl-p-methylbenzenesulfonamide (NCTS), et conduit à de bons rendements en benzonitriles correspondants. Dans cette réaction, le cobalt sert de catalyseur non seulement pour la formation des arylzinciques mais aussi pour la formation de liaisons C-CN. Les groupements fonctionnels, cétone et nitrile, sont permis lorsque le complexe de cobalt associé au ligand bipyridine est utilisé. Le deuxième chapitre porte sur l’homocouplage Csp3-Csp3. Un simple halogénure de cobalt permet de catalyser la dimérisation des halogénures d’alkyles et des acétates d’allyles avec de bons à d’excellents rendements. L’ajout d’iodure de sodium permet d’étendre cette réaction aux chlorures et tosylates d’alkyles. Le couplage croisé entre 2 halogénures d’alkyle différents a également été testé mais les conditions doivent être optimisées. Dans le troisième chapitre, le couplage croisé catalysé au cobalt entre des bromures vinyliques et des chlorures benzyliques est présenté. Des halogénures de vinyles et de benzyles porteurs de groupements electrodonneurs ou electroattrateurs peuvent ainsi être couplés efficacement avec rétention de la configuration de la double liaison. Un mécanisme radicalaire semble être impliqué. Enfin, le dernier chapitre décrit l’arylation d’une 2-phenylpyridine avec un arylzincique par catalyse au cobalt par activation d’une liaison C-H et conduit à de premiers résultats encourageants. / This thesis presents the development of cobalt-catalyzed carbon-carbon bonds formation. The first chapter describes a novel cobalt-catalyzed electrophilic cyanation of arylzinc species, employing benign and non-toxic N-cyano-N-phenyl-p-methylbenzenesulfonamide (NCTS) as the cyano source. In this reaction, cobalt catalyzes both the formation of arylzinc species and the cyanation reaction. Various benzonitriles are synthesized affording good to excellent yields. Using cobalt-bipyridine complexes instead of CoBr2, ketone and nitrile groups can be tolerated. The second chapter reports cobalt-catalyzed Csp3-Csp3 homocoupling reaction. A simple catalytic system could deliver dimers of a number of alkyl halides/pseudohalides and allylic acetates. Sodium iodide is crucial for the homocoupling of unactivated alkyl chlorides and tosylates. This method is extended to alkyl-alkyl cross-coupling; however, the conditions still need to be optimized. The third chapter describes a cobalt-catalyzed vinyl-benzyl cross-coupling. A variety of functionalized vinyl bromides and benzyl chlorides are efficiently coupled under mild conditions in good to excellent yields, with retention of Z/E configuration. A few mechanistic experiments indicate a single electron transfer involved. The last chapter discusses the progress on the cobalt-catalyzed arylation of 2-phenylpyridine with an arylzinc species by C-H activation and promising results are obtained.

Cobalt

Catalyse

Couplages croisés

Organozinciques

Cyanation

C-H activation

Cobalt

Catalysis

Cross-Coupling

Organozinc reagents

Cyanation

C-H activation

Transition Metal Catalysis: Activation of CO2, C–H, and C–O Bonds En Route to Carboxylic Acids, Biaryls, and N-containing Heterocycles

Yeung, Charles See Ho

12 January 2012

Transition metal catalysis is a powerful tool for the construction of biologically active and pharmaceutically relevant architectures. With the challenge of continually depleting resources that this generation of scientists faces, it is becoming increasingly important to develop sustainable technologies for organic synthesis that utilize abundant and renewable feedstocks while minimizing byproduct formation and shortening the length of synthetic sequences by removing unnecessary protecting group manipulations and functionalizations. To this end, we have developed four new methods that transform inexpensive starting materials to valuable products. This dissertation covers the following key areas: 1) activation of CO2 for a mild and functional group tolerant synthesis of carboxylic acids, 2) oxidative twofold C–H bond activations as a strategy toward biaryls, 3) migratory O- to N-rearrangements in pyridines and related heterocycles for the preparation of N-alkylated heterocycles, and 4) asymmetric hydrogenations of cyclic imines and enamines en route to chiral 1,2- and 1,3-diamines and macrocyclic peptides.

organic chemistry

synthesis

transition metal catalysis

carbon dioxide

organozinc reagents

carboxylic acids

nickel

C-H activation

biaryls

palladium

heterocycles

ruthenium

diamines

cyclic peptides

asymmetric hydrogenation

rhodium

0490

Transition Metal Catalysis: Activation of CO2, C–H, and C–O Bonds En Route to Carboxylic Acids, Biaryls, and N-containing Heterocycles

Yeung, Charles See Ho

12 January 2012

Transition metal catalysis is a powerful tool for the construction of biologically active and pharmaceutically relevant architectures. With the challenge of continually depleting resources that this generation of scientists faces, it is becoming increasingly important to develop sustainable technologies for organic synthesis that utilize abundant and renewable feedstocks while minimizing byproduct formation and shortening the length of synthetic sequences by removing unnecessary protecting group manipulations and functionalizations. To this end, we have developed four new methods that transform inexpensive starting materials to valuable products. This dissertation covers the following key areas: 1) activation of CO2 for a mild and functional group tolerant synthesis of carboxylic acids, 2) oxidative twofold C–H bond activations as a strategy toward biaryls, 3) migratory O- to N-rearrangements in pyridines and related heterocycles for the preparation of N-alkylated heterocycles, and 4) asymmetric hydrogenations of cyclic imines and enamines en route to chiral 1,2- and 1,3-diamines and macrocyclic peptides.

organic chemistry

synthesis

transition metal catalysis

carbon dioxide

organozinc reagents

carboxylic acids

nickel

C-H activation

biaryls

palladium

heterocycles

ruthenium

diamines

cyclic peptides

asymmetric hydrogenation

rhodium

0490

Σύνθεση μη-πρωτεϊνικών αμινοξέων για εφαρμογές τους στην πεπτιδική σύνθεση σε στερεή φάση / Synthesis of unnatural amino acids for applications in solid phase peptide synthesis

Αντωνίου, Αντωνία

07 June 2013

Στην παρούσα διατριβή παρουσιάζεται μια νέα μεθοδολογία σύνθεσης μη-πρωτεϊνικών αμινοξέων (ΜΠΑ) κατάλληλων για εφαρμογές στην πεπτιδική σύνθεση με χρήση του ασπαραγινικού οξέος ως χειρόμορφου εκμαγείου. Η μεθοδολογία αυτή βασίζεται στην επιτυχή και σε καλές αποδόσεις σύνθεση της β-αλδεΰδης του Ν-τριτυλοασπαραγινικού τριτ-βουτυλεστέρα, η οποία αποτελεί την ένωση «κλειδί». Αυτή στη συνέχεια έδωσε μια ποικιλία νέων ΜΠΑ μέσω αντιδράσεων Wittig, Horner-Emmons ή με επίδραση οργανοψευδραργυρικών αντιδραστηρίων. Ανάλογες μελέτες με σκοπό την σύνθεση των αντίστοιχων ομολόγων τους με έναν άνθρακα λιγότερο ή περισσότερο στην πλευρική αλυσίδα, ξεκινώντας από σερίνη ή γλουταμινικό οξύ δεν απέδωσαν τα αναμενόμενα αποτελέσματα ή ήταν ανεπιτυχείς. / In the present dissertation a new methodology is reported for the synthesis of novel non-proteinogenic amino acids (NPAAs) suitable for applications in solid phase peptide synthesis. This methodology involves aspartic acid as chiral template and relies on the successful and in good yields pepraration of the key N-tritylaspartic tert-butyl ester’s β-aldehyde, which when followed by Wittig, Horner-Emmons or Grignard type reactions may result in a variety of new NPAAs. Furthermore unsuccessful attempts towards the application of the present methodology for the synthesis of NPAA homologues bearing one carbon atom less or more in the side chain by using as chiral templates serine or glutamic acid, respectively, are also reported.

Ασπαραγινικό οξύ

Αναγωγή Fukuyama

Αντίδραση Wittig

Αντίδραση HWE

Βενζοθειαζόλιο

γ-κετο-α-αμινοξέα

572.65

Non-proteinogenic amino acids

Aspartic acid

Fukuyama reduction

Wittig reaction

HWE reaction

Benzothiazole

Organozinc reagents

γ-keto-α-amino acids