Tsuji–Trost reaction

About: Tsuji–Trost reaction is a research topic. Over the lifetime, 2305 publications have been published within this topic receiving 63241 citations. The topic is also known as: Trost asymmetric allylic alkylation & Tsuji-Trost reaction.

Asymmetric Transition Metal-Catalyzed Allylic Alkylations.

Abstract: Efficient and reliable amplification of chirality has borne its greatest fruit with transition metal-catalyzed reactions since enantiocontrol may often be imposed by replacing an achiral or chiral racemic ligand with one that is chiral and scalemic While the most thoroughly developed enantioselective transition metal-catalyzed reactions are those involving transfer of oxygen (epoxidation and dihydroxylation)1,2 and molecular hydrogen,3 the focus of this review is on the area of enantioselective transition metal-catalyzed allylic alkylations which may involve C-C as well as C-X (X ) H or heteroatom) bond formation4-9 The synthetic utility of transitionmetal-catalyzed allylic alkylations has been soundly demonstrated since its introduction nearly three decades ago10-21 In contrast to processes where the allyl moiety acts as the nucleophilic partner, we will limit our discussion to processes which result in nucleophilic displacements on allylic substrates (eq 1) Such reactions have been recorded with a broad

Asymmetric transition-metal-catalyzed allylic alkylations: applications in total synthesis.

Abstract: A. Primary Alcohols as Nucleophiles 2931 B. Carboxylates as Nucleophiles 2931 C. Alkylations with Phenols 2932 IV. Nitrogen Nucleophiles in AAA Total Synthesis 2935 A. Alkylamines as Nucleophiles 2935 B. Azides as a Nucleophile 2936 C. Sulfonamide Nucleophiles 2937 D. Imide Nucleophiles 2938 E. Heterocyclic Amine Nucleophiles 2940 V. Sulfur Nucleophiles 2941 VI. Summary and Conclusions 2941 VII. Acknowledgment 2941 VIII. References 2942 I. Considerations for Enantioselective Allylic Alkylation

Metal-catalyzed enantioselective allylation in asymmetric synthesis.

Abstract: Metal-catalyzed enantioselective allylation, which involves the substitution of allylic metal intermediates with a diverse range of different nucleophiles or S(N)2'-type allylic substitution, leads to the formation of C-H, -C, -O, -N, -S, and other bonds with very high levels of asymmetric induction. The reaction may tolerate a broad range of functional groups and has been applied successfully to the synthesis of many natural products and new chiral compounds.

Catalytic asymmetric conjugate addition and allylic alkylation with Grignard reagents.

Abstract: Catalytic asymmetric C-C bond-forming reactions using organometallic reagents are among the most important of organic transformations. Frequently, these transformations are key steps in the synthesis of complex biologically active molecules. The conjugate addition (CA) and allylic alkylation (AA) with organometallic compounds are especially versatile in asymmetric C-C bond-forming reactions. These transformations are complementary to the catalytic asymmetric allylic alkylation and the Michael addition, both based on soft carbon nucleophiles (Scheme 1A). For both CA and AA, the organic moiety of the organometallic reagent reacts with the sp carbon of an electron-deficient substrate, converting it to an sp carbon (Scheme 1B). In the case of CA, subsequent quenching of the enolate leads to the final product, whereas for the related AA an appropriate leaving group is expelled to form the chiral product. The organometallic compounds used most frequently for these transformations are organozinc, Grignard, organoaluminium, organolithium and cuprate reagents. Over the last three decades considerable effort has been directed toward the development of efficient catalytic systems for the asymmetric CA and AA reactions using organometallic reagents. Complexes derived from Cu salts and chiral ligands have provided the broadest scope in the catalyzed enantioselective CA and AA of organometallic reagents. Organozinc reagents have been the most successful of the organometallic reagents in this respect. Major contributions and progress in the field of asymmetric CA and AA based on organozinc reagents have been summarized in several reviews. Organomagnesium compounds were among the first organometallic compounds to be applied to synthetic organic chemistry and the use of Grignard reagents in Cu-catalyzed CA was first reported in 1941 by Kharash and Tawney. Achieving chemo-, regioand stereocontrol in both asymmetric conjugate addition (ACA) and asymmetric allylic alkylation (AAA), however, has proven to be challenging and has restricted the application of these transformations, in particular, to total synthesis. Typical selectivity issues pertain to 1,2versus 1,4-addition (Scheme 2A) and SN2versus SN2′-substitution (Scheme 2B). The challenge faced in the development of stereoselective C-C bond-forming reactions is apparent when one considers that, despite three decades of intensive research in this area, only recently has efficient Cu-catalyzed enantioselective CA of Grignard reagents been achieved. The earlier discovery of the highly enantioselective Cu-catalyzed CA of dialkylzinc reagents allowed for replacement of Grignard reagents in this asymmetric C-C bond-forming reaction. Dialkylzinc reagents offer distinct advantages over Grignard reagents in their low reactivity in noncatalyzed reactions and their high tolerance to functional groups both on the substrate and on the organozinc reagent itself. Nevertheless, there are several advantages to the use of common mono-alkylMg halide reagents, most importantly their widespread availability and the ability to transfer all of the alkyl groups of the organometallic compound. The synthetic potential of these asymmetric transformations has driven intensive research in this area, and over the past few years major breakthroughs have been realized in the enantioselective CA and AA of Grignard reagents. * Author for correspondence. E-mail: B.L.Feringa@rug.nl Chem. Rev. 2008, 108, 2824–2852 2824