Overview

Catalysis in Asymmetric Synthesis, 2nd Edition Asymmetric synthesis has become a major aspect of modern organic chemistry. The stereochemical properties of an organic compound are often essential to its bioactivity, and the need for stereochemically pure pharmaceutical products is a key example of the importance of stereochemical control in organic synthesis. However, achieving high levels of stereoselectivity in the synthesis of complex natural products represents a considerable intellectual and practical challenge for chemists. Written from a synthetic organic chemistry perspective, this text provides a practical overview of the field, illustrating a wide range of transformations that can be achieved. The book captures the latest advances in asymmetric catalysis with emphasis placed on non-enzymatic methods. Topics covered include: Reduction of alkenes, ketones and imines Nucleophilic addition to carbonyl compounds Catalytic carbon-carbon bond forming reactions Catalytic reactions involving metal carbenoids Conjugate addition reactions Catalysis in Asymmetric Synthesis bridges the gap between undergraduate and advanced level textbooks and provides a convenient point of entry to the primary literature for the experienced synthetic organic chemist.

Full Product Details

Author:   Vittorio Caprio (University of Auckland) ,  Jonathan M. J. Williams (University of Bath)
Publisher:   John Wiley and Sons Ltd
Imprint:   Wiley-Blackwell
Edition:   2nd edition
Dimensions:   Width: 16.00cm , Height: 2.80cm , Length: 23.60cm
Weight:   0.717kg
ISBN:  

9781405190916

ISBN 10:   1405190914
Pages:   408
Publication Date:   02 January 2009
Audience:   Professional and scholarly ,  Professional & Vocational
Format:   Hardback
Publisher's Status:   Active
Availability:   Out of stock  
The supplier is temporarily out of stock of this item. It will be ordered for you on backorder and shipped when it becomes available.

Table of Contents

Preface to the Second Edition. Preface to the First Edition. 1 Introduction. 1.1 Reactions Amenable to Asymmetric Catalysis. 1.2 Assignment of (R) and (S) Stereochemical Descriptors. Futher Reading. References. 2 Reduction of Alkenes. 2.1 Asymmetric Hydrogenation with Rhodium Complexes. 2.2 Asymmetric Hydrogenation with Ruthenium Catalysts. 2.3 Alkene Hydrogenation with Titanium and Zirconium Catalysts. 2.4 Alkene Hydrogenation with Iridium Catalysts. 2.5 Alkene Hydrogenation with Organocatalysts. 2.6 Alkene Hydrosilylation. 2.7 Alkene Hydroboration. 2.8 Hydroamination. 2.9 Hydroformylation. 2.10 Hydroacylation of Alkenes. 2.11 Hydrocyanation of Alkenes. References. 3 Reduction of Ketones and Imines. 3.1 Hydrogenation of Ketones. 3.2 Hydrogenation and Transfer Hydrogenation of Imines and Related Compounds. 3.3 Transfer Hydrogenation of Ketones. 3.4 Heterogeneous Hydrogenation. 3.5 Reduction of Ketones Using Enantioselective Borohydride Reagents. 3.6 Hydrosilylation of Ketones. 3.7 Hydrosilylation of Imines and Nitrones. References. 4 Epoxidation. 4.1 Epoxidation of Allylic Alcohols. 4.2 Epoxidation with Metal(salen) Complexes. 4.3 Epoxidation Using Metal–Porphyrin-Based Catalysts. 4.4 OtherMetal-Catalysed Epoxidations of Unfunctionalised Olefins. 4.5 Epoxidation of Electron-Deficient Alkenes. 4.6 Epoxidation with Iminium Salts. 4.7 Epoxidation with Ketone Catalysts. 4.8 Epoxidation of Aldehydes. 4.9 Aziridination of Alkenes. 4.10 Aziridination of Imines. References. 5 Further Oxidation Reactions. 5.1 Dihydroxylation. 5.2 Aminohydroxylation. 5.3 α-Heterofunctionalisation of Aldehydes and Ketones. 5.4 Oxidation of C–H. 5.5 Baeyer–Villiger Oxidation. 5.6 Oxidation of Sulfides. References. 6 Nucleophilic Addition to Carbonyl Compounds. 6.1 Addition of Organozincs to Carbonyl Compounds. 6.2 Addition of Cyanide to Aldehydes and Ketones. 6.3 Allylation of Aldehydes. 6.4 Hydrophosphonylation of Aldehydes. 6.5 Nucleophilic Additions to Imines. References. 7 The Aldol and Related Reactions. 7.1 The Aldol Reaction. 7.2 Isocyanide and Related Aldol Reactions. 7.3 The Nitroaldol Reaction. 7.4 Addition of Enolates to Imines. 7.5 Darzens Condensation. 7.6 Morita–Baylis–Hillman Reaction. 7.7 Carbonyl-Ene Reactions. References. 8 Cycloadditions. 8.1 Diels–Alder Reactions. 8.2 Inverse Electron Demand Diels–Alder Reactions. 8.3 Hetero-Diels–Alder Reactions. 8.4 1,3-Dipolar Cycloaddition Reactions. 8.5 [2+2] Cycloadditions. 8.6 Pauson–Khand-Type Reactions. References. 9 Catalytic Reactions Involving Carbenes and Ylides. 9.1 Cyclopropanation. 9.2 Insertion Reactions. 9.3 Asymmetric Ylide Reactions. References. 10 Catalytic Carbon–Carbon Bond-Forming Reactions. 10.1 Cross-Coupling Reactions. 10.2 Metal-Catalysed Allylic Substitution. 10.3 Heck Reactions. 10.4 Alkylmetalation of Alkenes. References. 11 Conjugate Addition Reactions. 11.1 Conjugate Addition of Enolates. 11.2 Conjugate Addition of Sulfur Nucleophiles. 11.3 Conjugate Addition of Nonstabilised Nucleophiles. 11.4 Conjugate Addition with Nitrogen-Based Nucleophiles and Electrophiles. References. 12 Further Catalytic Reactions. 12.1 Isomerisations and Rearrangements. 12.2 Deprotonation Reactions. 12.3 Protonation Reactions. 12.4 Alkylation and Allylation of Enolates. 12.5 Formation of Alkenes. 12.6 Oxyselenylation-Elimination Reactions. 12.7 The Benzoin Condensation. 12.8 Ester Formation and Hydrolysis. 12.9 Ring-Opening of Epoxides. References. Index.

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Author Information

Dr Vittorio Caprio, Lecturer in Organic and Medicinal Chemistry in the Department of Chemistry, University of Auckland, New Zealand. His research interests lie in the application of synthetic organic methods to the synthesis of bioactive natural products of diverse structure. A central aim is the efficient and elegant syntheses of target core structures in a stereocontrolled manner using nature as the source of chirality. The ultimate goal is to use natural medicines as the basis for designing and synthesizing drugs of greater therapeutic value. Professor Jonathan MJ Williams (author of the first edition), Department of Chemistry, University of Bath, UK. Research involves with the use of transition metals for the synthesis of useful organic molecules. In particular, we have been developing reactions using 'borrowing hydrogen.' In this chemistry, ruthenium or iridium catalysts temporarily remove hydrogen to give an aldehyde.  This aldehyde then reacts to give an alkene (or imine) and the hydrogen is then returned to give a C-C or C-N bond. These procedures allow alcohols to be used as alkylating agents in place of more conventional, but often toxic/mutagenic alkyl halides.

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