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Zirconocene mediated co-cyclisation reactionsOwen, David Rodney January 2000 (has links)
No description available.
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Exploratory study of ionophoric spiroethers and spioketalsSelvaraj, Peter Rajan 22 September 2006 (has links)
No description available.
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Studies toward completion of the C1-C28 segment of spongistatin 1. Synthesis and photochemistry of 4bH-pyrido[2,1-a]isoindol-6-oneModolo, Isabelle 27 August 2009 (has links)
No description available.
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Synthetic studies toward the total synthesis of azaspiracid-1Su, Dong 31 May 2012 (has links)
Azaspiracid-1, a novel marine toxin that contains 9 rings and 20 stereogenic centers, has drawn considerable attention from synthetic groups worldwide due to its structural complexity, which includes a unique trioxabisspiroketal fused to a tetrahydrofuran ring (ABCD rings), a piperidine-tetrahydrofuran spiroaminal system fused to a 2,9-dioxabicyclo[3.3.1]nonane system (FGHI rings), a connecting six-membered cyclic hemiketal bridge (E ring) and a ��,��-unsaturated terminal carboxylic acid side chain. Our efforts toward the total synthesis of azaspiracid-1 led to the completion of both C1-C26 northern and C27-C40 southern halves of azaspiracid-1.
Herein, our improved and scalable synthetic studies toward the total synthesis of azaspiracid-1 is described. In particular, an improved and scalable synthesis of sulfone 3.6 with a key one-pot ketalization and methylation of ketone 3.22 to methylated hemiketal 3.24 is illustrated. A total 19 mmol of sulfone 3.6 has been prepared by this approach. An improved and scalable synthesis of aldehyde 3.7 utilizing allyl bromide 3.31 to couple with Evans auxiliary 3.33 has been developed. A total of 10 mmol of aldehyde 3.7 has been prepared by this approach. An improved synthesis toward the ABC ring fragment 3.52 with a high yield Julia coupling step is shown.
Large scale improved syntheses of the linkage fragment 3.2, the aldehyde fragment 4.9 and the azide fragment 4.10 of the southern portion of (���)-azaspiracid-1 have been described.
With an abundant material prepared by this scalable improved approach, we are confident that completing the total synthesis of (���)-azaspiracid-1 will occur in the near future. / Graduation date: 2013
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Síntese total dos ácidos pterídicos A e B / Total synthesis of pteridic acids A and BSalles Junior, Airton Gonçalves, 1977- 12 April 2009 (has links)
Orientador: Luiz Carlos Dias / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-15T23:16:23Z (GMT). No. of bitstreams: 1
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Previous issue date: 2009 / Resumo: Este trabalho relata a síntese total dos ácidos pterídicos A e B. O plano sintético utiliza como etapa-chave a reação aldólica syn com adição anti-Felkin intermediada por enolato de lítio entre a etil cetona a,b-insaturada de geometria Z 5 e o aldeído 4 para obtenção do fragmento C5-C15. Até onde sabemos este é o primeiro exemplo da utilização de um enolato de uma etil cetona a,b-insaturada quiral com geometria Z em uma reação aldólica. Uma eficiente reação de espirocetalização seguida de transformações adicionais conduziu ao ácido pterídico A em 2,9% de rendimento global para 13 etapas e ao ácido pterídico B em 2,8% de rendimento global também para 13 etapas. Em relação às outras sínteses totais, esta rota sintética apresenta um rendimento global comparável, mas chama a atenção pela nova e interessante abordagem na obtenção do fragmento C5-C15 via reação aldólica intermediada por lítio / Abstract: This work describes the convergent stereoselective synthesis of pteridic acids A and B. Our strategy involved a lithium enolate-mediated aldol reaction between ethyl ketone 5 and aldehyde 4 as the key step to set up C5-C15 fragment favoring 1,2-syn anti-Felkin adduct. As far we know, this is the first example of an aldol reaction between a chiral enolate of a (Z) enone and a chiral aldehyde. Efficient spiroketalization followed by additional transformations provided pteridic acids A and B in 2.9% and 2.8% overall yields, respectively. This approach compares very well with previously published routes and attracts attention to the novel and interesting C9-C10 bond construction to obtain C5-C15 fragment / Doutorado / Quimica Organica / Doutor em Ciências
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Sintese total das (+)-crocacinas C e D : sintese dos fragmentos 6,6-espirocetal das espirofunginas A e B / Total synthesis of (+)-crocacins "C" and"D": synthesis of the 6,6-spiroketalsOliveira, Luciana Gonzaga de 17 December 2004 (has links)
Orientador: Luiz Carlos Dias / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Quimica / Made available in DSpace on 2018-09-11T21:06:50Z (GMT). No. of bitstreams: 1
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Previous issue date: 2004 / Doutorado / Quimica Organica / Doutor em Quimica
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Synthesis of the ABC fragment of pectenotoxin-4Lipinski, Radoslaw Michal January 2012 (has links)
This thesis details the application of two synthetic methodologies, developed by the Donohoe group, to the synthesis of the ABC fragment of pectenotoxin-4, a macrolide marine natural product that consists of 19 stereogenic centres, three tetrahydrofuran rings, one spiroketal and one bicyclic ketal embedded within a 26-membered macrocycle. Pivotal to the developed synthetic route was the utilisation of an unprecedented cascade osmium catalysed oxidative cyclisation for the construction of two THF rings (the BC ring system). After successfully developing a model system for the synthesis of the AB anomeric 6,5 spiroketal, which involved the employment of a hydride shift initiated oxo carbenium ion formation followed by intramolecular spiroketalisation, the developed system was then applied to the fully elaborated synthesis of the ABC fragment. The synthesis of the ABC fragment of pectenotoxin-4 was completed in 20 linear steps, with an overall yield of 3.3%.
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Metal complex catalysed C-X (X = S, O and N) bond formationVuong, Khuong Quoc, Chemistry, Faculty of Science, UNSW January 2006 (has links)
This thesis describes the catalysed addition of X-H bonds (X = S, O and N) to alkynes using a range of novel rhodium(I) and iridium(I) complexes containing hybrid bidentate phosphine-pyrazolyl, phosphine-imidazolyl and phosphine-N heterocyclic carbene (NHC) donor ligands. The synthesis of novel bidentate phosphine-pyrazolyl, phosphine-imidazolyl (P-N) and phosphine-NHC (PC) donor ligands and their cationic and neutral rhodium(I) and iridium(I) complexes [M(P N)(COD)]BPh4, [M(PC)(COD)]BPh4, [Ir(P-N)(CO)2]BPh4 and [M(P-N)(CO)Cl] were successfully performed. An unusual five coordinate iridium complex with phosphine-NHC ligands [Ir(PC)(COD)(CO)]BPh4 was also obtained. Seventeen single crystal X-ray structures of these new complexes were determined. A range of these novel rhodium and iridium complexes were effective as catalysts for the addition of thiophenol to a variety of alkynes. Iridium complexes were more effective than rhodium analogues. Cationic complexes were more effective than neutral complexes. Complexes with hybrid phosphine-nitrogen donor were more effective than complexes containing bidentate nitrogen donor ligands. An atom-economical, efficient method for the synthesis of cyclic acetals and bicyclic O,O-acetals was successfully developed based on the catalysed hydroalkoxylation. Readily prepared terminal and non-terminal alkyne diols were cyclised into bicyclic O,O-acetals in quantitative conversions in most cases. The efficiency of a range of rhodium and iridium complexes containing bidentate P-N and PC donor ligands as catalysts for the cyclisation of 4-pentyn-1-amine to 2-methyl-1-pyrroline varied significantly. The cationic iridium complexes with the bidentate phosphine-pyrazolyl ligands, [Ir(R2PyP)(COD)]BPh4 (2.39-2.42) were extremely efficient as catalysts for this transformation. Increasing the size of the substituent on or adjacent to the donor led to improvement in catalytic activity of the corresponding metal complexes. The mechanism of the catalysed hydroalkoxylation was proposed to proceed by the initial activation of the alkyne via ?? coordination to the metal centre. The ?? binding of both aliphatic and aromatic alkynes to [Ir(PyP)(CO)2]BPh4 (2.44) was observed by low temperature NMR and no reaction between 2.44 and alcohols was observed. In contrast, the facility in which thiol and amine oxidatively added to 2.44 led the proposal that in the hydrothiolation and hydroamination reaction, the catalytic cycle commences with the activation of the X-H bond (X = S, N) by an oxidative addition process.
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Toward green processes organic synthesis by catalysis with metal-doped solidsBorghese, Sophie 15 February 2013 (has links) (PDF)
Nowadays, the modern chemical industry has to deal with increasing environmental concerns, including the disposal of waste and its economic impact, or the diminution of important worldwide resources such as transition metals. In this Ph.D. thesis, we aimed to bring improvement in this area by the development of green processes, based on the use of recyclable heterogeneous catalysts. By combining the catalytic properties of several metal cations with the properties of solid catalysts such as polyoxometalates or zeolites, we were able to set up new tools for organic synthesis. Silver-doped polyoxometalates proved to be very efficient catalysts in the rearrangement of alkynyloxiranes to furans. Acetals and spiroketals were synthetized by dihydroalkoxylation of alkynediols under catalysis with silver-zeolites. As a perspective, we highlighted the potential applications of such green procedures in the total synthesis of more complex molecules. The first results suggested that these environmental friendly processes should gain increasing interest in the future.
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Metal complex catalysed C-X (X = S, O and N) bond formationVuong, Khuong Quoc, Chemistry, Faculty of Science, UNSW January 2006 (has links)
This thesis describes the catalysed addition of X-H bonds (X = S, O and N) to alkynes using a range of novel rhodium(I) and iridium(I) complexes containing hybrid bidentate phosphine-pyrazolyl, phosphine-imidazolyl and phosphine-N heterocyclic carbene (NHC) donor ligands. The synthesis of novel bidentate phosphine-pyrazolyl, phosphine-imidazolyl (P-N) and phosphine-NHC (PC) donor ligands and their cationic and neutral rhodium(I) and iridium(I) complexes [M(P N)(COD)]BPh4, [M(PC)(COD)]BPh4, [Ir(P-N)(CO)2]BPh4 and [M(P-N)(CO)Cl] were successfully performed. An unusual five coordinate iridium complex with phosphine-NHC ligands [Ir(PC)(COD)(CO)]BPh4 was also obtained. Seventeen single crystal X-ray structures of these new complexes were determined. A range of these novel rhodium and iridium complexes were effective as catalysts for the addition of thiophenol to a variety of alkynes. Iridium complexes were more effective than rhodium analogues. Cationic complexes were more effective than neutral complexes. Complexes with hybrid phosphine-nitrogen donor were more effective than complexes containing bidentate nitrogen donor ligands. An atom-economical, efficient method for the synthesis of cyclic acetals and bicyclic O,O-acetals was successfully developed based on the catalysed hydroalkoxylation. Readily prepared terminal and non-terminal alkyne diols were cyclised into bicyclic O,O-acetals in quantitative conversions in most cases. The efficiency of a range of rhodium and iridium complexes containing bidentate P-N and PC donor ligands as catalysts for the cyclisation of 4-pentyn-1-amine to 2-methyl-1-pyrroline varied significantly. The cationic iridium complexes with the bidentate phosphine-pyrazolyl ligands, [Ir(R2PyP)(COD)]BPh4 (2.39-2.42) were extremely efficient as catalysts for this transformation. Increasing the size of the substituent on or adjacent to the donor led to improvement in catalytic activity of the corresponding metal complexes. The mechanism of the catalysed hydroalkoxylation was proposed to proceed by the initial activation of the alkyne via ?? coordination to the metal centre. The ?? binding of both aliphatic and aromatic alkynes to [Ir(PyP)(CO)2]BPh4 (2.44) was observed by low temperature NMR and no reaction between 2.44 and alcohols was observed. In contrast, the facility in which thiol and amine oxidatively added to 2.44 led the proposal that in the hydrothiolation and hydroamination reaction, the catalytic cycle commences with the activation of the X-H bond (X = S, N) by an oxidative addition process.
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