Enolate amide

Hydrogen bonding to a carbonyl group causes a shift to lower frequency of 40 to 60 cm k Acids, amides, enolized /3-keto carbonyl systems, and o-hydroxyphenol and o-aminophenyl carbonyl compounds show this effect. All carbonyl compounds tend to give slightly lower values for the carbonyl stretching frequency in the solid state compared with the value for dilute solutions. 

Af-Fluorobis(trifluoromethanesulfonyl)imide is also effective in the mono-fluonnation of ester and amide enolates, and of neutral dicarbonyl compounds. Excellent stereoselectivity is observed [48, 80, 81] (equations 39-41)... 

With (Z)-amide enolates and (Z)-thioamide enolates a strong preference for sm-adducts is also observed. In general, boron or zirconium (Z)-enolates of ketones and amides display a higher simple diastereoselectivity in favor of syn-products than the corresponding lithium or magnesium enolates6,7. 

Thus, in the above reactions of cither enantiomer of chiral aldehydes with the ketone enolate, as well as with the amide enolate, the stereochemical outcome in each case is largely determined by the inherent selectivity of the chiral enolate reagent. 

For amide enolates (X = NR2), with Z geometry, model transition state D is intrinsically favored, but, again, large X substituents favor the formation of nt/-adducts via C. Factors that influence the diastereoselectivity include the solvent, the enolate counterion and the substituent pattern of enolate and enonc. In some cases either syn- or unh-products are obtained preferentially by varying the nature of the solvent, donor atom (enolate versus thioeno-late), or counterion. Most Michael additions listed in this section have not been examined systematically in terms of diastereoselectivity and coherent transition stale models are currently not available. Similar models to those shown in A-D can be used, however all the previously mentioned factors (among others) may be critical to the stereochemical outcome of the reaction. 

Although the methodology described so far produces <5-oxo esters via diastereoselective enolate additions to enones, the same product may be obtained via an alternate sequence, i.e., addition of ketone or aldehyde enolates to a,j3-unsaturated esters or amides. Enolates of ketones are known to react with a,/ -unsaturated esters to give the Michael adducts50, however, the study of simple diastcrcoselectivity has, so far, been limited to special cases (MIMIRC reactions, Section 1.5.2.4.4.). 

C4-insertions by means of a sigmatropic rearrangement process have been described using either a thermal Cope reaction, anionic Claisen amide enolate and zwitterionic aza-Claisen rearrangements. 

SRNl substitution include ketone enolates,183 ester enolates,184 amide enolates,185 2,4-pentanedione dianion,186 pentadienyl and indenyl carbanions,187 phenolates,188 diethyl phosphite anion,189 phosphides,190 and thiolates.191 The reactions are frequently initiated by light, which promotes the initiating electron transfer. As for other radical chain processes, the reaction is sensitive to substances that can intercept the propagation intermediates. 

Preparation of (R)-(+)-3-hydroxy-4-methylpentanoic acid has been reported previously by the submitters.5 Alternative syntheses of (R)-(+)- or (S)-(-)-3-hydroxy-4-methylpentanoic acid rely on aidoi reactions of chiral ketone, ester, or amide enolates,2 8 10 and Lewis-acid mediated additions of chiral silyl ketene acetals to Isobutyraldehyde.3 11 Since both enantiomers of HYTRA are readily available this method enables one to prepare (S)-3-hydroxy-4-methylpentanoic acid as well. 

In conjunction with our studies on the synthetic utility of amide enolates (35,36), we have postulated that the high (Z)-stereoselection observed in the deprotonation of dialkylamides is a consequence of ground state allylic strain considerations (37), which strongly disfavor amide conformation B (Scheme 8), and consequently the associated transition state T (Scheme 7) for deprotonation, to give ( )-enolates. 

It is significant to note that the sense of asymmetric induction noted for amide enolates 157 and 158 is the same as that found for the boryl enolates derived from the chiral oxazolidone imides 146 and 145, respectively (cf. Scheme 22). The arguments presented... 

Somfai enhanced the driving force of some amide enolate aza-Claisen rearrangements by choosing vinylaziridines as reactants [24]. The additional loss of ring strain offered the advantage of running most of the reactions at room temperature to synthesize unsaturated chiral azepinones. Various substitution... 

The third mechanism starts with addition of the AT-allylamine 103 to the cumulated acceptor system of an allene carbonester 108 (Acc=CHC02Me) to form an intermediate iV-allyl ammonium amide enolate 109 (allene carbonester Claisen rearrangement). The anion stabilizing group is exclusively placed... 

Reduction of the aromatic nucleus in AjjV-dimethylbenza-mide occurs by an initial single electron transfer to give a radical anion. Protonation of the radical anion generates a radical and a second electron transfer gives the amide enolate 1. Protonation of the cross-conjugated trienolate moiety in 1 occurs carbonyl group to give the cyclohexa-1,4-diene 2. ... 

Birch reduction of the chiral benzamide 5 generates the amide enolate 6 (Scheme 4). This enolate has been characterized by NMR spectroscopy and by an extensive examination of the effects of changes in alkali metal, solvent, reaction... 

Catalytic asymmetric protonation of a prochiral amide enolate by a chiral diamine (10mol%) has been achieved through careful optimization of the proton-shuttle conditions which must apply. ... 

With phenyllithium, the iminophosphoranes of benzoic acid hydrazides 157 can be deprotonated, as shown in Scheme 62.0-Acylation of the amide-enolates 158 affords intermediates 159, which are in turn cyclized by an aza-Wittig reaction to 1,3,4-oxadiazoles 160 (68JA5626). 

By contrast, lithium enolates derived from tertiary amides do react with oxiranes The diastereoselectivity in the reaction of simple amide enolates with terminal oxiranes has been addressed and found to be low (Scheme 45). The chiral bicyclic amide enolate 99 reacts with a good diastereoselectivity with ethylene oxide . The reaction of the chiral amide enolate 100 with the chiral oxiranes 101 and 102 occurs with a good diastereoselectivity (in the matched case ) interestingly, the stereochemical course is opposite to the one observed with alkyl iodides. The same reversal is found in the reaction of the amide enolate 103. By contrast, this reversal in diastereoselectivity compared to alkyl iodides was not found in the reaction of the hthium enolate 104 with the chiral oxiranes 105 and 106 °. It should be noted that a strong matched/mismatched effect occurs for enolates 100 and 103 with chiral oxiranes, and excellent diastereoselec-tivities can be achieved. 

Birch reduction of enantiomcrieally pure benzamides followed by alkylation of the amide enolate was used with remarkable success to obtain chiral cyclohexadiene derivatives22. In this case the chiral auxiliary was located in the benzamide moiety. 

Chiral amide enolates are very useful vehicles for constructing new stereogenic centers. Many examples can be found in this volume and in several recently published reviews1-6. 

Rotation is hindered in the enolate. Thus, if the a-substituent R1 4= R2, the enolate can exist in two forms, the syn- and anti-forms (enolates 2 and 3, respectively, if R2 has higher priority than R1). Attack of an electrophile on either face of the enolates, 2 or 3, leads to a mixture of the alkylated amides, 4 and 5. If R1 and R2 and the A-substituents R3 and R4 are all achiral, the two alkylated amides will be mirror images and thus a racemate results. If, however, any of the R substituents are chiral, enolate 2 will give a certain ratio of alkylated amide 4/5, whereas enolate 3 will give a different, usually inverted, ratio. Thus, for the successful design of stereoselective alkylation reactions of chiral amide enolates it is of prime importance to control the formation of the enolate so that one of the possible syn- or anti-isomers is produced in large excess over the other,... 

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