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Enolate amide, chiral

Diastereoselective hydroxylation of enolates of chiral amides. Davis and coworkers1 have examined the asymmetric hydroxylation of the tetrasubstituted enolates of a chiral amide (2) with these chiral camphoryloxaziridines. Oxidation of the lithium enolate of 2 with (+ )-l proceeds with only moderate diastereoselectivity (48.4% de), which is somewhat less than that observed on hydroxylation with the achiral 2-(phenylsulfonyl)-3-phenyloxaziridine (4). Oxidation of the enolate of 2... [Pg.72]

The chemistry of magnesium bisamides has been reviewed" . They can be used for the regio- and stereoselective formation of enolates", while chiral magnesium amides are applied in asymmetric synthesis for enantioselective enolisations ". [Pg.539]

SlLYL ENOL ETHERS Chiorotrimethylsilane-Zinc, 82 Lithium amides, chiral, 159 Lithium tri-sec-butylborohydride, 167 Organotin reagents, 211 Osmium tetroxide-Trimethylamine N-ox-ide-Pyridine, 223... [Pg.397]

The situation changes when chiral ester enolates or chiral amide enolates are alkylated. There, the half-spaces on the two sides of the enolate planes of the substrates are diastereotopic, and alkylating reagents can react from one of the sides selectively (see discussion in Section 3.4.1). Stereogenic alkylations of such enolates therefore may take place diastereo selectively. [Pg.554]

The chemistry of magnesium bis-amides has been reviewed.21 Magnesium bis-amides have been used for the region- and stereoselective formation of enolates.2 a Enantioselective enolization with chiral magnesium amides has been applied in asymmetric synthesis.23 233... [Pg.34]

SCHEME 59. Various types of solid-state mixed aggregates involving ketone lithium enolates (A) pinacolone enolate/lithium amide [LiHMDS/CH2C(OLi)Bu-i, 2 DME]230 (B) pentan-3-one enolate/2 chiral lithium amide232 (C) pinacolone enolate/lithium amide/LiBr [LiHMDS/2 Cl HCtOI.ijBu-f/LiBr, 2 TMEDA]235... [Pg.563]

TABLE 15. Enantioselective Michael additions of ester enolates using chiral amides (equation 53)... [Pg.392]

The superior nucleophilicity and excellent thermal stability of pseudoephedrine amide enolates make possible alkylation reactions with substrates that are ordinarily unreactive with the corresponding ester and imide-derived enolates, such as (3-branched primary alkyl iodides. Also, alkylation reactions of pseudoephedrine amide enolates with chiral (J-branched primary alkyl iodides proceed with high diastereoselectivity for both the matched and mismatched cases (Table 3). ... [Pg.486]

The imide 6 is an excellent proton source for returning lithium enolates to chiral ketones in ether. The ee value is also greatly influenced by an additive, and LiBr appears to have the best effect. Deracemization of amides by protonation of their enolates in the presence of a chiral l-aryl-l,2,3,4-tetrahydroisoquinoline (catalytic amount) and that of the potassium enolates of A-(2-hydroxypinan-3-ylidene)-a-amino esters have remarkable efficiencies. [Pg.79]

Asymmetric aldol reactions mediated by zirconium enolates with chiral auxiliary were reported (Equations 1 and 2). The zirconium enolate derived firom pseudoephedrine-based amide (1) and Cp2ZrCl2 was treated with a series of aldehydes to afford the corresponding aldol adducts (2) in high yields with excellent diastereoselectivity [2]. The high syn selectivity was explained by dinu-dear cyclic intermediates. In contrast, the aldol reactions with norephedrine-based ester (3) proceed with highly anti-selective manner (Equation 2) [3]. In both cases, 2 equivalent of Cp2ZrCl2 were necessary to achieve such high stereoselectivity. [Pg.296]

Highly enantioselectivity assumed to originate from a mixed aggregate 171 of the trans-lithium enolate of t-butyl propionate 169 and the chiral lithium amide 170 was observed in aldol additions to various aldehydes, as exemplified in Scheme 5.55. Thus, the acylated aldols obtained with benzaldehyde formed in a diastereomeric ratio of 92 8 in favor of the anti-product, with an enantiomeric excess of 94% ee [83]. More recent studies on the structures of mixed aggregates between lithium enolates and chiral amide bases (see also Chapter 3) provided an insight in this type of enantioselective conversion. [Pg.310]

The chemistry of magnesium bisamides has been reviewed. They can also be used for the regioselective and stereoselective enolization, and chiral magnesium amides can be advantageously used for enantioselective enolizations. ... [Pg.244]

Yanagisawa A, Kikuchi T, Watanabe T, Yamamoto H. Enantioselective protonation of lithium enolates with chiral imides possessing a chiral amide. Bull Chem. Soc Jpn. 1999 72 2337 2343. [Pg.988]

Chiral amide and imide enolates are amongst the most effective reagents providing. yv -3-hy-droxycarboxylic acids in both high simple diastereoselectivity and induced stereoselectivity, e.g., the amides 1 and 2, and especially, the imides 3 and 4 (derived from (S(-valine and (l/ ,2S)-norephedrine, respectively)93 and the C2-symmetric amide 594 are highly effective systems ... [Pg.494]

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. [Pg.574]

A variety of chiral amides as well as oxazolidones388 and imidazolidones389,390 may easily be prepared from amino alcohols that are derived from amino acids391 392. The addition of the lithium enolates of these amides under kinetically controlled conditions to a,/i-unsaturated esters yields optically active pentanedioates. Both syn- and //-5-amino-5-oxopcntanoates may be obtained with good diastereomeric ratios192. [Pg.974]

Enantioselective deprotonation of prochiral 4-alkylcyclohexanones using certain lithium amide bases derived from chiral amines such as (1) has been shown (73) to generate chiral lithium enolates, which can be trapped and used further as the corresponding trimethylsilyl enol ethers trapping was achieved using Corey s internal quench described above. [Pg.62]

Chiral phosphinous amides have been found to act as catalysts in enantio-selective allylic alkylation. Horoi has reported that the palladium-catalyzed reaction of ( )-l,3-diphenyl-2-propenyl acetate with the sodium enolate of dimethyl malonate in the presence of [PdCl(7i-allyl)]2 and the chiral ligands 45 gave 46 in 51-94% yields and up to 97% ee (Scheme 38). It is notorious that when the reaction is carried out with the chiral phosphinous amide (S)-45a, the product is also of (S) configuration, whereas by using (R)-45b the enantiomeric (R) product is obtained [165]. [Pg.97]

By analogy, the acetylene aldehyde 500 gives, on addition of the chiral Li-enolate 501 [79-82], the chiral //-lactams 502 and 503 in 75% yield [80-82]. Similar (fhc-tam-forming reactions are discussed elsewhere [70, 83-88]. The ketone 504 affords, with the lithium salt of the silylated lithium amide 505, the Schiff base 506, in 74% yield (Scheme 5.27). The Schiff base 506 is also obtained in 25% yield by heating ketone 504 with (C6H5)3P=N-C6H4Me 507 in boiling toluene for 7 days... [Pg.97]

Whilst the addition of a chiral NHC to a ketene generates a chiral azolium enolate directly, a number of alternative strategies have been developed that allow asymmetric reactions to proceed via an enol or enolate intermediate. For example, Rovis and co-workers have shown that chiral azolium enolate species 225 can be generated from a,a-dihaloaldehydes 222, with enantioselective protonation and subsequent esterification generating a-chloroesters 224 in excellent ee (84-93% ee). Notably, in this process a bulky acidic phenol 223 is used as a buffer alongside an excess of an altemativephenoliccomponentto minimise productepimerisation (Scheme 12.48). An extension of this approach allows the synthesis of enantiomericaUy emiched a-chloro-amides (80% ee) [87]. [Pg.288]

It is also possible to achieve enantioselective enolate formation by using chiral bases. Enantioselective deprotonation requires discrimination between two enantiotopic hydrogens, such as in d.v-2,6-dimethylcyclohexanone or 4-(/-butyl)cyclohcxanonc. Among the bases that have been studied are chiral lithium amides such as A to D.22... [Pg.13]

A number of other types of chiral auxiliaries have been employed in enolate alkylation. Excellent results are obtained using amides of pseudoephedrine. Alkylation occurs anti to the a-oxybenzyl group.93 The reactions involve the Z-enolate and there is likely bridging between the two lithium cations, perhaps by di-(isopropyl)amine.94... [Pg.42]

The enolates of other carbonyl compounds can be used in mixed aldol reactions. Extensive use has been made of the enolates of esters, thiol esters, amides, and imides, including several that serve as chiral auxiliaries. The methods for formation of these enolates are similar to those for ketones. Lithium, boron, titanium, and tin derivatives have all been widely used. The silyl ethers of ester enolates, which are called silyl ketene acetals, show reactivity that is analogous to silyl enol ethers and are covalent equivalents of ester enolates. The silyl thioketene acetal derivatives of thiol esters are also useful. The reactions of these enolate equivalents are discussed in Section 2.1.4. [Pg.78]


See other pages where Enolate amide, chiral is mentioned: [Pg.830]    [Pg.472]    [Pg.329]    [Pg.212]    [Pg.4]    [Pg.214]    [Pg.6]    [Pg.148]    [Pg.247]    [Pg.78]    [Pg.490]    [Pg.25]    [Pg.76]    [Pg.478]    [Pg.494]    [Pg.916]    [Pg.1452]    [Pg.41]    [Pg.175]   
See also in sourсe #XX -- [ Pg.553 ]




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Aggregates, chiral lithium amide/enolate

Amide enolate

Amides Chirality

Amides enolates

Amides: chiral enolates

Amides: chiral enolates

Chiral enolate

Enol amidation

Enolates chiral

Silyl enol ethers Lithium amides, chiral

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