Enolates, alkoxy

In all cases examined the ( )-isomers of the allylic alcohols reacted satisfactorily in the asymmetric epoxidation step, whereas the epoxidations of the (Z)-isomers were intolerably slow or nonstereoselective. The eryfhro-isomers obtained from the ( )-allylic alcohols may, however, be epimerized in 95% yield to the more stable tlireo-isomers by treatment of the acetonides with potassium carbonate (6a). The competitive -elimination is suppressed by the acetonide protecting group because it maintains orthogonality between the enolate 7i-system and the 8-alkoxy group (cf the Baldwin rules, p. 316). 

The oxidation of the cyclic enol ether 93 in MeOH affords the methyl ester 95 by hydrolysis of the ketene acetal 94 formed initially by regioselective attack of the methoxy group at the anomeric carbon, rather than the a-alkoxy ketone[35]. Similarly, the double bond of the furan part in khellin (96) is converted ino the ester 98 via the ketene acetal 97[l23],... 

The chemoselective desilylation of one of the two different silyi enoi ethers in 10 to give the monosilyl enol ether II is realized by the Pd-catalyzed reaction of Bu3SnF. The chemoselectivity is controlled by steric congestion and the relative amount of the reagent[7,8]. An interesting transformation of the 6-alkoxy-2,3-dihydro-6//-pyran-3-one 12 into the cyclopentenone derivative 13 proceeds smoothly with catalysis by Pd(OAc)2 (10 mol%)[9]. 

Cross-conjugated dienones are quite inert to nucleophilic reactions at C-3, and the susceptibility of these systems to dienone-phenol rearrangement precludes the use of strong acid conditions. In spite of previous statements, A " -3-ketones do not form ketals, thioketals or enamines, and therefore no convenient protecting groups are available for this chromophore. Enol ethers are not formed by the orthoformate procedure, but preparation of A -trienol ethers from A -3-ketones has been claimed. Another route to A -trien-3-ol ethers involves conjugate addition of alcohol, enol etherification and then alcohol removal from la-alkoxy compounds. 

In the 1,2-diphenyl-4-alkoxy series, the keto and enol forms have both been isolated the latter is unstable and changes irreversibly into the former. ... 

Furthermore, being a member of the family of nonprostereogenic allylmetals, 2-(alkoxy- or alkylaminocarbonyl)-2-propenyl reagents offer the possibility of introducing the a-methylene-propanoic acid /f-enolate to aldehydes. 

The a-alkoxy-substituted iron-acyl complex 8 is prepared by oxidation of the enolate prepared from iron-acetyl complex 6 and subsequent etherification12. 

The a-alkoxy iron-acyl complex 5 may be deprotonated to generate the lithium enolate 6, which undergoes a highly diastereoselective aldol reaction with acetone to generate the adduct 7 as the major product. Deprotonation of acetone by 6 is believed to be a competing reaction 30% of the starting complex 5 is found in the product mixture48 40. 

The lithium enolate of a-alkoxy substituted complex 9 also exhibited little selectivity upon reaction with aldehydes all four possible diastereomers were produced when it was treated with acetaldehyde49. 

The diastereomeric a-alkoxy complexes (1 )-15 and (S)-15, separable by chromatography, were each converted to the corresponding aluminum enolates and reacted with 2-methylpropanal (17)49. Enolate (/ )-16 selectively provided a mixture of two diastereomers with the (Fe/ ,2, 3 i )-complex (/ )-18 identified as the major constituent of a 94 6 mixture. The two chiral auxiliaries of complex (S j-lS exerted antagonistic effects and an undefined mixture of all four possible diastereomers was obtained. 

In y-alkoxyfuranones the acetal functionality is ideally suited for the introduction of a chiral auxiliary simultaneously high 71-face selectivity may be obtained due to the relatively rigid structure that is present. With ( + )- or (—(-menthol as auxiliaries it is possible to obtain both (5S)- or (5/ )-y-menthyloxy-2(5//)-furanones in an enantiomerically pure form293. When the auxiliary acts as a bulky substituent, as in the case with the 1-menthyloxy group, the addition of enolates occurs trans to the y-alkoxy substituent. The chiral auxiliary is readily removed by hydrolysis and various optically active lactones, protected amino acids and hydroxy acids are accessible in this way294-29s-400. 

A number of chiral alcohols and amino alcohols have been applied as auxiliaries to enolates. The induction may be explained by the shielding of one of the faces of the cnolate by a bulky alkoxy or aryl substituent. Representative examples, together with the results in diastereoselec-tive 1,4-additions with different Michael acceptors, are given in the following. 

Various diastereoselective Michael reactions are based on y-bromo-, y-alkyl-, or y-alkoxy-2(5//)-furanones following the trans-face selectivity shown in Section 1.5.2.3.1.2. Thus the lithium enolates of esters such as ethyl propanoate, ethyl a-methoxyacetate and ethyl a-phenylacetate add to methoxy-2(5/f)-furanone with complete face selectivity269-273 (see Section 1.5.2.4.4.2.). 

A solution of the trimethylsilyl enol ether of propionyl trimethylsilane (5 mmol) (Chapter 12) and benzaldehyde diethyl acetal (5 mmol) in dichloromethane (10ml) was added to a solution of BF3.OEt2 (5 mmol) in dichloromethane (5ml), cooled to —78 C. After being stirred for lh at -78°C and 2h at -30°C, the mixture was quenched with excess saturated sodium hydrogen carbonate solution, and extracted with ether. Concentration and distillation gave the product -ethoxy acylsilane, (4.6mmol, 95%). b.p. 105-106 C/2mmHg. Treatment of this alkoxy... 

Alkoxy ketones react with lithium enolates particularly rapidly. ... 

The lithium enolates of a-alkoxy esters exhibit high stereoselectivity, which is consistent with involvement of a chelated enolate.374 39 The chelated ester enolate is approached by the aldehyde in such a manner that the aldehyde R group avoids being between the a-alkoxy and methyl groups in the ester enolate. A syn product is favored for most ester groups, but this shifts to anti with extremely bulky groups. 

The Mukaiyama aldol reaction can provide access to a variety of (3-hydroxy carbonyl compounds and use of acetals as reactants can provide (3-alkoxy derivatives. The issues of stereoselectivity are the same as those in the aldol addition reaction, but the tendency toward acyclic rather than cyclic TSs reduces the influence of the E- or Z-configuration of the enolate equivalent on the stereoselectivity. 

The potential for coordination depends on the oxy substituents.82 Alkoxy substituents are usually chelated, whereas highly hindered silyloxy groups usually do not chelate. Trimethylsiloxy groups are intermediate in chelating ability. The extent of chelation also depends on the Lewis acid. Studies with a-alkoxy and (3-alkoxy aldehydes with lithium enolates found only modest diastereoselectivity.83... 

In each instance, the silyl enol ether approaches anti to the methyl substituent on the chelate. This results in a 3,4-syn relationship between the hydroxy and alkoxy groups for a-alkoxy aldehydes and a 3,5-anti relationship for (3-alkoxy aldehydes with the main chain in the extended conformation. 

Heteroatom substituents also introduce polar effects. In the case of a-alkoxy aldehydes the preferred TS appears to be F and G for the E- and Z-enolates, respectively. These differ from the normal Felkin TS for nucleophilic addition. The reactant conformation is believed to be determined by minimization of dipolar repulsion between the alkoxy substituent and the carbonyl group.96 This model predicts higher 3,4-anti ratios for Z-enolates, and this is observed. 

E-enolate 2,3-anti, 3,4-weak Z-enolate 2,3-syn,3,4-anti Y13 = alkoxy 3,5-anti... 

Polar effects appear to be important for 3 -alkoxy substituents in enolates. 3-Benzyloxy groups enhance the facial selectivity of /(-boron enolates, and this is attributed to a TS I in which the benzyloxy group faces toward the approaching aldehyde. This structure is thought to be preferable to an alternate conformation J, which may be destabilized by electron pair repulsions between the benzyloxy oxygen and the enolate oxygen.109... 

The structure of the products is determined by the site of protonation of the radical anion intermediate formed after the first electron transfer step. In general, ERG substituents favor protonation at the ortho position, whereas EWGs favor protonation at the para position.215 Addition of a second electron gives a pentadienyl anion, which is protonated at the center carbon. As a result, 2,5-dihydro products are formed with alkyl or alkoxy substituents and 1,4-products are formed from EWG substituents. The preference for protonation of the central carbon of the pentadienyl anion is believed to be the result of the greater 1,2 and 4,5 bond order and a higher concentration of negative charge at C(3).216 The reduction of methoxybenzenes is of importance in the synthesis of cyclohexenones via hydrolysis of the intermediate enol ethers. 

The stereoselectivity of silyl ketene acetal Claisen rearrangements can also be controlled by specific intramolecular interactions.246 The enolates of a-alkoxy esters adopt the Z-configuration because of chelation by the alkoxy substituent. 

In the presence of zinc chloride, stereoselective aldol reactions can be carried out. The aldol reaction with the lithium enolate of /-butyl malonate and various a-alkoxy aldehydes gave anti-l,2-diols in high yields, and 2-trityloxypropanal yielded the syn-l,2-diol under the same conditions.633 Stoichiometric amounts of zinc chloride contribute to the formation of aminoni-tropyridines by direct amination of nitropyridines with methoxyamine under basic conditions.634 Zinc chloride can also be used as a radical initiator.635... 

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