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Carboidratos como matéria-prima para a preparação de substratos quirais: aplicações em catálise enantiosseletiva e processos diastereosseletivos / Carbohydrates as starting materials for the preparation of chiral substrates: applications in enantioselective and diastereoselective processes.Ana Dionéia Wouters 07 January 2013 (has links)
O presente trabalho descreve o uso de carboidratos como materiais de partida para a preparação de catalisadores quirais e também de substratos quirais. Primeiramente estudos envolvendo a aplicação de amino álcoois derivados de carboidratos na arilação assimétrica de aldeídos, usando ácidos arilborônicos como fontes de grupos arila transferíveis, revelaram que um ligante preparado a partir da D-xilose mostrou-se bastante eficiente e conduziu aos produtos em excelentes rendimentos e altos excessos enantioméricos. Posteriormente a arilação de aldeídos derivados de carboidratos é descrita. Em alguns casos diastereosseletividades maiores que 20:1 foram observadas e a metodologia foi aplicada a síntese total da 7-epi-goniofufurona e análogos. / The work described herein is centered on the use of carbohydrates as starting materials for the synthesis of chiral ligands and chiral sugar-derivatives. Initially, chiral amino alcohols were studied as ligands for the asymmetric arylation of aldehydes using aryl boronic acids as the source of transferable aryl groups. We found that a chiral ligand derived from D-xylose was very efficient and the desired products were obtained in excellent yields and enantiomeric excesses. In addition, the arylation of sugar-based aldehydes was also studied. In many cases, excellent diastereoselectivities of >20:1 were achieved and the methodology was employed in the total synthesis of 7-epi-goniofufurone and analogues.
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Organocatalysis : hydrazine and sulfonimide as new functionalities in asymmetric organocatalysisHe, Hao 01 January 2009 (has links)
No description available.
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Chiral Ý-amino sulfoxides and chiral sultams in asymmetric synthesisLin Jing, 01 January 2000 (has links)
No description available.
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Chiral acetylenic sulfoxide in asymmetric alkaloid synthesisLam, Kwun Ting 01 January 2004 (has links)
No description available.
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CaSH (camphor sulfonyl hydrazine) and CSI (chiral sulfonimide) organocatalysisChen, Lingyan 01 January 2010 (has links)
No description available.
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Chiral acetylenic sulfoxide in asymmetric synthesis ; Enantioselective synthesis of yohimbine alkaloidsMo, Tian 01 January 1997 (has links)
No description available.
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Studies in asymmetric synthesisRavindran, Swarnam Shanthi January 1994 (has links)
The stereoselectivity of TiCI₄-catalysed Mukaiyama reactions of a camphor acetal-derived chiral silyl enol ether with a range of substituted aromatic aldehydes has been examined. The enantiomeric excess in each of the resulting ß-hydroxy ketones, determined by ¹H NMR spectroscopy using the lanthanide chiral shift reagent Pr(Etcf₃), ranged between 9 and 13%. The stereo-directing potential of the camphor acetal as a chiral auxiliary in the α-benzylation of carboxylate esters has been studied; the acids were chosen to illustrate substituent effects on asymmetric induction. The observed diastereoselectivity increased with increasing steric bulk of the ester group and α-benzylation of the tert-butylacetate derivative proceeded with 48% diastereoselectivity. It is proposed that the enolate adopts an endo-s-trans conformation in the transition state and preferential attack by the electrophile at the somewhat less hindered Si-face is supported by both the optical rotation data and computer modelling studies. Reductive cleavage and hydrolysis of one of the benzylated esters furnished known products from whose optical rotation the configuration of the major diastereomer was established. In order to improve the steric advantage of Si-facial attack, methods of increasing the steric bulk of the blocking group were explored. A novel 2,2-propylenedioxy hydroxycamphor acetal and its 3,3-propylenedioxy analogue were prepared. Selected carboxylate esters of these propylenedioxy acetals were subjected to α-benzylation and the 2,2-(propylenedioxy)-3-exo-tert-butylacetate derivative showed a diastereoselectivity of 57% during a-benzylation. Hydrolysis of the abenzylated phenylacetate analogue offered the known 2,3-diphenylpropanoic acid whose optical rotation indicated the preferred configuration at the new chiral centre to be (R), a result which is consistent with the proposed approach of the electrophile to the less hindered Re-face of theendo-s-trans enolate moiety and reflects an inversion of the configurational bias observed with 2-v exo-carboxylate analogues. Attempts to prepare the monocatechol acetal of the hydroxy camphor derivative although unsuccessful, led to the isolation of two novel dibornyl ethers whose structures were established by 1- and 2-D NMR spectroscopy. A study of novel applications of camphor-derived auxiliaries in the asymmetric synthesis of α-amino acids has been initiated. The several approaches tried led to the preparation of three novel dural glycine derivatives in good yield
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Development of New Methodologies for the Asymmetric Synthesis of Chiral Sulfoximines via C-S Bond Formation / 炭素―硫黄結合形成反応によるスルホキシイミンの不斉合成法の開発Aota, Yusuke 23 March 2020 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第22267号 / 理博第4581号 / 新制||理||1658(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)准教授 加納 太一, 教授 依光 英樹, 教授 大須賀 篤弘 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM
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Acyl Imidazole : A Promising Template for Asymmetric Lewis and Brønsted Acid Mediated 1,3-Dipolar CycloadditionsRane, Digamber Sadanand January 2011 (has links)
Construction of chiral complex molecules continues to be a challenge for organic chemists all over the world and to address this challenge numerous methodologies have been developed. 1,3-Dipolar cycloaddition reactions is one such simple and elegant method, which can be employed towards the construction of chiral heterocycles. The ability to construct multiple stereocenters in one operation is one of the salient features of dipolar cycloaddition reaction. Asymmetric dipolar cycloaddition via chiral Lewis or Bronsted acid catalyzed processes is aided by the development of various templates, which provide points of attachment for these catalyst. Application of acyl imidazoles as multifunctional templates has been investigated for Lewis and Bronsted acid catalyzed 1,3-dipolar cycloaddition of azomethine imines and nitrones. Chapter 1. A review of 1,3-dipolar cycloaddition towards to construction of chiral nitrogen containing heterocycles is discussed in this chapter. This chapter intends to provide the reader a current state of asymmetric 1,3-dipolar cycloaddition. Chapter 2. Development of exo and enantioselective Cu(II) catalyzed azomethine imine cycloaddition to pyrazolidinone acrylates is discussed in this chapter. The key issues approached in this chapter includes impact of metal geometry on diastereoselectivity as well as effect of N-l and C-5 substitution on enantioselectivity of cycloadducts. Investigation into the scope and limitation of azomethine imines and dipolarophiles has also been discussed. Chapter 3. This chapter introduces acyl imidazoles as multifunctional template for asymmetric azomethine imine cycloaddition. Limitation of substrate scope for azomethine imine cycloaddition encountered in the previous chapter has been resolved by the use of acyl imidazoles as templates. Synthesis of complementary diastereomers of azomethine imine cycloadducts via Lewis acid and Bronsted acid catalyzed reactions has been discussed in this chapter. Chapter 4. This chapter highlights the application of acyl imidazoles as template for first Bronsted acid catalyzed exo and enantioselective nitrone cycloaddition to electron deficient olefins. Study of appropriate chiral Bronsted acid and investigation of breadth and scope of
nitrones and dipolarophiles has also been discussed here. Chapter 5. This chapter address one of the most challenging aspect of synthetic organic chemistry namely the construction of chiral quaternary stereocenters. This study highlights chiral Bronsted catalyzed nitrone cycloaddition to p,|3-disubstituted-a,P-unsaturated acyl imidazole leading to the formation of isoxazolidines with chiral quaternary stereocenter. This methodology is useful for the construction of chiral fluorinated heterocycles.
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Stereochemical Control of Polyketides through Asymmetric Aldol ReactionLou, Samuel 04 May 2000 (has links)
Polyketides are a group of complex natural products that can inhibit the growth of
bacteria, viruses, fungi, and tumor cells. Most polyketides are very difficult to extract from
bacteria. Therefore, numerous syntheses of polyketide-related synthons have been
attempted.
<p>
However, controlling the stereochemistry of the polyketide poses the most
challenging task for researchers. The aim of this report is to discuss control of the
stereochemistry of the polyketide-related synthons in asymmetric aldol reactions. Several
important methodologies for stereochemical control in the aldol reaction exist. The first
approach is to control the enolate geometry and the aldehyde (or ketone) geometry. The second approach is to use a chiral auxiliary and chiral ligands. The third approach is to use
a chiral catalyst, which is the most efficient method if the catalyst operates with complete
efficiency. Proposed transition states are also described to explain the resulting
stereochemistry of the aldol adduct. / Master of Science
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