Chiral auxiliaries, diastereoselectivity, asymmetric stereoselectivity

Besides their application in asymmetric alkylation, sultams can also be used as good chiral auxiliaries for asymmetric aldol reactions, and a / -product can be obtained with good selectivity. As can be seen in Scheme 3-14, reaction of the propionates derived from chiral auxiliary R -OH with LICA in THF affords the lithium enolates. Subsequent reaction with TBSC1 furnishes the 0-silyl ketene acetals 31, 33, and 35 with good yields.31 Upon reaction with TiCU complexes of an aldehyde, product /i-hydroxy carboxylates 32, 34, and 36 are obtained with high diastereoselectivity and good yield. Products from direct aldol reaction of the lithium enolate without conversion to the corresponding silyl ethers show no stereoselectivity.32... 

The A -acyl derivatives of 4-substituted-3,4,5,6-tetrahydro-27/-l,3-oxazin-2-ones proved to behave as effective chiral auxiliaries in asymmetric enolate alkylations and aldol reactions, the stereoselectivities of which were found to be higher for 4-isopropyl than for 4-phenyl derivatives <2006OBC2753>. The transformations of 4-isopropyl-6,6-dimethyl-3-propa-noyl-3,4,5,6-tetrahydro-2/7-l,3-oxazin-2-one 251 to 252 or 253 proceeded with excellent diastereoselectivities (Scheme 47). 6,6-Dimethyl substitution within the oxazine ring facilitated exclusive exocyclic cleavage upon hydrolysis of the C-alkylated and the aldol products 252 and 253, to furnish a-substituted carboxylic acids 254 or a-methyl-/ -hydroxycarboxylic acids 256. 

Stereosectivity is a broad term. The stereoselectivity in cyclopropanation which has been discussed in the above subsection, in fact, can also be referred to as diastereoselectivity. In this section, for convenience, the description of diastereoselectivity will be reserved for selectivity in cyclopropanation of diazo compounds or alkenes that are bound to a chiral auxiliary. Chiral diazoesters or chiral Ar-(diazoacetyl)oxazolidinone have been applied in metal catalysed cyclopropanation. However, these chiral diazo precursors and styrene yield cyclopropane products whose diastereomeric excess are less than 15% (equation 129)183,184. The use of several a-hydroxy esters as chiral auxiliaries for asymmetric inter-molecular cyclopropanation with rhodium(II)-stabilized vinylcarbenoids have been reported by Davies and coworkers. With (R)-pantolactone as the chiral auxiliary, cyclopropanation of diazoester 144 with a range of alkenes provided c yield with diastereomeric excess at levels of 90% (equation 130)1... 

In Diels-Alder (D-A) reactions, racemic products are obtained from enantiomeric diene or dienophile. D-A reactions are widely applied in the synthesis of bioactive asymmetric natural products and hence enantio- and diastereoselectivities of the D-A reactions are very much needed to get the desired products as major products. Several approaches have been developed in the last three decades in this respect by the use of different Lewis acid catalysts as chiral auxiliary or asymmetric catalysts. Catalytic D-A reactions have twofold benefits. On one side, it provides high enantiomeric/ diastereomeric excess of product and on the other side, it affords high yield of products by reducing the activation energy of the transition states (TSs). In NED D-A reactions, it lowers the LUMO energy of the dienophile and in lED D-A reactions, it lowers the energy of LUMO of the diene so that the reaction occurs at low temperature with ease (Fig. 3.10). At higher temperature the stereoselectivity of the D-A reactions is lost. 

The first three sections of this chapter describe diastereoselective alkylations of chiral enolates including heteroatom-substituted enolates [15, 20]. Section 3.4 deals with the class of enolate alkylations that have typically been included under the rubric of chiral-auxiliary-controlled processes. As suggested by the term, the auxiliary is only transiently utilized and, following alkylation, is subsequently excised. The facile use of chiral auxiliaries in asymmetric enolate alkylations has played and continues to play a pivotal role in the stereoselective formation of new C-C bonds. After a brief survey of the relatively few developments in catalytic enantioselective enolate alkylations (Section 3.5) [21, 22], selected examples of enolate a-hydroxylations (Section 3.6) [23-25] and a-halogenations (Section 3.7) [26, 27] are covered. The corresponding a-aminations of enolates are discussed in Chapter 10, describing stereoselective formation of a-amino acids. 

The utilization of a-amino acids and their derived 6-araino alcohols in asymmetric synthesis has been extensive. A number of procedures have been reported for the reduction of a variety of amino acid derivatives however, the direct reduction of a-am1no acids with borane has proven to be exceptionally convenient for laboratory-scale reactions. These reductions characteristically proceed in high yield with no perceptible racemization. The resulting p-amino alcohols can, in turn, be transformed into oxazolidinones, which have proven to be versatile chiral auxiliaries. Besides the highly diastereoselective aldol addition reactions, enolates of N-acyl oxazolidinones have been used in conjunction with asymmetric alkylations, halogenations, hydroxylations, acylations, and azide transfer processes, all of which proceed with excellent levels of stereoselectivity. 

One problem in the anti-selective Michael additions of A-metalated azomethine ylides is ready epimerization after the stereoselective carbon-carbon bond formation. The use of the camphor imines of ot-amino esters should work effectively because camphor is a readily available bulky chiral ketone. With the camphor auxiliary, high asymmetric induction as well as complete inhibition of the undesired epimerization is expected. The lithium enolates derived from the camphor imines of ot-amino esters have been used by McIntosh s group for asymmetric alkylations (106-109). Their Michael additions to some a, p-unsaturated carbonyl compounds have now been examined, but no diastereoselectivity has been observed (108). It is also known that the A-pinanylidene-substituted a-amino esters function as excellent Michael donors in asymmetric Michael additions (110). Lithiation of the camphor... 

In diastereoselective asymmetric oxygenation of chiral enolates the introduction of new stereo-genic centers (chiral a-hydroxy carbonyl structural units) are induced by covalently bonded chiral units that are i) incorporated into the target molecule (substrate-induced diastereosclec-tivity) or ii) removed after the stereoinduction step (auxiliary-induced stereoselectivity). 

In addition to being an efficient chiral controller in a number of stereoselective transformations of chiral acrylates, (i.e. the Diels-Alder reaction, the conjugate reduction, the asymmetric dihydroxylation, and the nitrile oxide cycloaddition ) the bomanesultam (11) has been shown to be an exceptionally efficient chiral auxiliary for stereoselective aldol condensations (eqs eq 3 and eq 4). Depending upon the reaction conditions, A -propionylsultam can produce either the syn or anti aldol product with an excellent diastereoselectivity, Furthermore, good diastereoselectiv-ities are also observed for the corresponding acetate aldol reaction (eq 5), ... 

Reactions that involve asymmetric synthesis are traditionally classified separately from other dia-stereoselective transformations of chiral substrates, even though there is little fundamental differoice between them. The degree of success realized in both categories depends on the ability of the chemist to distinguish between competing, diastereomeric transition states the critical objective is to maximize AAG - This classification system undoubtedly evolved since the chiral auxiliary used in asymmetric reactions, whether it is introduced as part of a catalyst or is covalently bound to the substrate, is not destined to be an integral structural component of subsequent transformation products, while the reverse situation obviously pertains in the more frequently encountered diastereoselective transformations of chiral substrates. Work that has been reported for asymmetric IMDA reactions is summarized in this section." ... 

Major interest has been expressed in the synthesis of chiral sulfoxides since the early 1980s, when it was discovered that chiral sulfoxides are efficient chiral auxiliaries that are able to bring about important asymmetric transformations [22]. Sulfoxides are also constituents of important drugs (e.g., omeprazole (Losec , Priso-lec )) [23]. There is a plethora of routes of access to enantioenriched sulfoxides, and many involve metal-catalyzed asymmetric oxidations [24]. Examples of ruthenium metal-based syntheses of sulfoxides are scarce, presumably due to the tendency of sulfur atoms to bind irreversibly to a ruthenium center. Schenk et al. reported a dia-stereoselective oxidation of Lewis acidic Ru-coordinated thioethers with dimethyl-dioxirane (DMD) (Scheme 10.16) [25[. Coordination of the prochiral thioether to the metal is followed by diastereoselective oxygen transfer from DMD in high yield. The... 

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