Stereoselective synthesis synthetic transformations

Synthetic transformations of the products of the intramolecular bis-silylation have been examined. The five-membered ring products derived from homopropargylic alcohols were hydrogenated in a stereoselective manner (Scheme ll).90 Oxidation of the products under the Tamao oxidation conditions (H202/F /base)96 leads to the stereoselective synthesis of 1,2,4-triols. This method can be complementary to the one involving intramolecular bis-silylation of homoallylic alcohols (vide infra). 

Among chiral auxiliaries, l,3-oxazolidine-2-thiones (OZTs) have attracted important interest thanks to there various applications in different synthetic transformations. These simple structures, directly related to the well-documented Evans oxazolidinones, have been explored in asymmetric Diels-Alder reactions and asymmetric alkylations (7V-enoyl derivatives), but mainly in condensation of their 7V-acyl derivatives on aldehydes. Those have shown interesting characteristics in anti-selective aldol reactions or combined asymmetric addition. Normally, the use of chiral auxiliaries which can accomplish chirality transfer with a predictable stereochemistry on new generated stereogenic centers, are indispensable in asymmetric synthesis. The use of OZTs as chiral copula has proven efficient and especially useful for a large number of stereoselective reactions. In addition, OZT heterocycles are helpful synthons that can be specifically functionalized. 

In order to apply tartrate ester-modified allyl- and crotylboronates to synthetic problems,23 Roush and Palkowitz undertook the stereoselective synthesis of the C19-C29 fragment 48 of rifamycin S, a well-known member of the ansamycin antibiotic group24 (Scheme 3.1u). The synthesis started with the reaction of (S,S)-43E and the chiral aldehyde (S)-49. This crotylboration provided the homoallylic alcohol 50 as the major component of an 88 11 1 mixture. Compound 50 was transformed smoothly into the aldehyde 51, which served as the substrate for the second crotylboration reaction. The alcohol 52 was obtained in 71% yield and with 98% diastereoselectivity. After a series of standard functional group manipulations, the alcohol 53 was oxidized to the corresponding aldehyde and underwent the third crotylboronate addition, which resulted in a 95 5 mixture... 

Thioxanthenes are not only valuable synthetic intermediates [1], they also find considerable interest in pharmaceutical research [2] and as dyes for numerous applications [3]. Only few methods are known for the stereoselective synthesis of S-heterocycles [4], Sequential transformations are a powerful strategy in organic synthesis frequently allowing the synthesis of complex molecules in a single synthetic operation [5]. It was anticipated that 4-silyloxy-l-benzothiopyrylium-salts 1 [6], which represent double-activated 4-thiochromanones, can be used for the stereoselective synthesis of aimulated thiochromanones 3 by reaction with 2-silyloxy-l,3-butadienes 2 [7]. 

The versatility and efficiency of this method were demonstrated in the first catalytic asymmetric synthesis of (—)-phaseolinic acid 188 , a biologically active compound of the paraconic acid family (equation 50). Using the 1,4-addition-aldol pathway, the paraconic acid skeleton could be synthesized in only four synthetic transformations with excellent stereoselectivities and 54% overall yield. 

Thiazolidinethiones constitute a class of versatile chiral auxiliaries for asymmetric synthesis. Their easy preparation from readily available /3-amino alcohols and the high levels of asymmetric induction they provide make them excellent chiral auxiliaries for the preparation of chiral intermediates in the synthesis of natural products. These chiral auxiliaries have been utilized in a wide variety of synthetic transformations such as asymmetric aldol-type acyloin condensation, stereoselective alkylation of different electrophiles (Stetter reaction), and stereoselective differentiation of enantiotopic groups in molecules bearing prochiral centers <2002COR303>. 

There are a few efficient methods for the stereoselective synthesis of vinyl halides, and this transformation remains a synthetic challenge. Research by S. Roy showed that the Hunsdiecker reaction can be made metal free and catalytic catalytic Hunsdiecker reaction) and can be used to prepare ( )-vinyl halides from aromatic a,p-unsaturated carboxylic acids. The unsaturated aromatic acids were mixed with catalytic amounts of TBATFA and the A/-halo-succinimide was added in portions over time at ambient temperature. The yields are good to excellent even for activated aromatic rings which do not undergo the classical Hunsdiecker reaction. The fastest halodecarboxylation occurs with NBS, but NCS and NIS are considerably slower. The nature of the applied solvents is absolutely critical, and DCE proved to be the best. This strategy was extended and applied in the form of a one-pot tandem Hunsdiecker reaction-Heck coupling to prepare aryl substituted (2 ,4 )-dienoic acids, esters, and amides. 

Under the same basic conditions /ra . -l-acetoxymethyl-1-methyl-2-tosylcyclopropane generated an a-sulfonyl anion, which attacked the ester group intramolecularly and afforded 2,5-dimethyl-l-tosyl-3-oxabicyclo[3.1.0]hexan-2-ol (22) in 50% yield.Stereoselective synthesis with a chiral cyclopropyl sulfoxide was experienced when ( )-4-tolylsulfinylcyclopropane was reacted first with butyllithium and then with methyl benzoate and gave 1-benzoyl-1-[(5)-4-tolylsulfinyl]cyclopropane (23a) in 62% yield. A useful reaction took place when 2-(hy-droxymethyl)cyclopropyl phenyl sulfide was treated first with an excess of butyllithium and then with dimethylformamide and gave 2-hydroxy-l-phenylsulfanyl-3-oxabicyclo[3.1.0]hexane (24), a lactol which has been used to carry out various useful synthetic transformations. Another useful reaction occurred when cyclopropyl phenyl sulfones were treated with butyllithium followed by an acyl imidazole to give acyl cyclopropanes in decent yield. 

One of the most fascinating aspects in the history of asymmetric catalysis with its countless successful applications in the stereoselective synthesis of a broad variety of functional groups is the structural variety of the complexes which are able to be used as catalysts [1,2]. Many catalysts have been developed based on different ideas and concepts of mechanistic effect. However, in spite of the abundance of such catalysts which have been successfully applied in asymmetric catalysis, not a handful of them possess multifunctional abilities catalyzing different type of enantioselective reactions. The development of such a type of chiral catalyst, the catalytic effect of which is not limited to one reaction but to different types of asymmetric synthetic organic transformations, remained an attractive challenge for a long time. 

Interest in die synthesis of enantiomerically pure compounds is also significant since both enantiomers of the same product often show distinctly different biological activities. In recent decades an enormous effort has been focused on the development of new methods for the stereoselective synthesis of natural products. These methods include a number of approaches for achieving enantioselective transformations of achiral substrates by using chiral auxiliaries, chiral reagents, or chiral catalysts [3]. However, from the range of different synthetic approaches available, the most useful for the synthesis of enantiomerically pure sesquiterpenes is still the hemi-synthesis from readily available natural sesquiterpenes. 

The field of organic synthesis has seen equally rapid advances. The emphasis has been in the development of new stereoselective methods for achieving specific synthetic transformations. The exciting synthetic approaches in the field of macrolide antibiotics, anti-tumor agents and other biologically important natural products serve to exemplify these developments. 

The versatihty of the present furanone synthetic method was demonstrated in the stereoselective synthesis of the Z-isomer of multicolanate (139) [118] (Scheme 26). The prerequisite compound 137 was prepared by successive treatment of appropriate organomagnesium and organohthium reagents, and it was transformed smoothly with lead tetraacetate to the target molecule (the incomplete acetate product 138 was subjected to elimination reaction with DBU). 

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