Aldehydes enolates from

The condensation conditions must be as mild as possible, because we want to get only the most stable of the three possible enols (from the aldehyde). Though you could not haye predicted the exact conditions either for the double bond. cleayage or for the condensation, you should haye seen that control was possible as in each case the two functional groups are different enough. ( J. Amer. Chem. Soc.. 1960, 636 J. Org. Chem.. 1964, 29, 3740 ... 

The selective intermolecular addition of two different ketones or aldehydes can sometimes be achieved without protection of the enol, because different carbonyl compounds behave differently. For example, attempts to condense acetaldehyde with benzophenone fail. Only self-condensation of acetaldehyde is observed, because the carbonyl group of benzophenone is not sufficiently electrophilic. With acetone instead of benzophenone only fi-hydroxyketones are formed in good yield, if the aldehyde is slowly added to the basic ketone solution. Aldols are not produced. This result can be generalized in the following way aldehydes have more reactive carbonyl groups than ketones, but enolates from ketones have a more nucleophilic carbon atom than enolates from aldehydes (G. Wittig, 1968). 

Silyl enol ethers are other ketone or aldehyde enolate equivalents and react with allyl carbonate to give allyl ketones or aldehydes 13,300. The transme-tallation of the 7r-allylpalladium methoxide, formed from allyl alkyl carbonate, with the silyl enol ether 464 forms the palladium enolate 465, which undergoes reductive elimination to afford the allyl ketone or aldehyde 466. For this reaction, neither fluoride anion nor a Lewis acid is necessary for the activation of silyl enol ethers. The reaction also proceed.s with metallic Pd supported on silica by a special method[301j. The ketene silyl acetal 467 derived from esters or lactones also reacts with allyl carbonates, affording allylated esters or lactones by using dppe as a ligand[302]... 

Aldehyde Enolate Alkoxide ion from nucleophilic addition... 

This regiochemistry is consistent with the electrophilic character of Pd(II) in the addition step. Solvent and catalyst composition can affect the regiochemistry of the Wacker reaction. Use of /-butanol as the solvent was found to increase the amount of aldehyde formed from terminal alkenes, and is attributed to the greater steric requirement of /-butanol. Hydrolysis of the enol ether then leads to the aldehyde. 

A jy -diastereoselective aldol reaction based on titanium enolates from (A)-l-benzyloxy-2-methyl-3-pentanone was developed by Solsona et al. (Equation (12)).64 The titanium enolate of this chiral ketone afforded the corresponding syn-syn aldol adducts in high yields and diastereomeric ratios with a broad range of aldehydes. 

Intermolecular cross aldolization of metallo-aldehyde enolates typically suffers from polyaldolization, product dehydration and competitive Tishchenko-type processes [32]. While such cross-aldolizations have been achieved through amine catalysis and the use of aldehyde-derived enol silanes [33], the use of aldehyde enolates in this capacity is otherwise undeveloped. Under hydrogenation conditions, acrolein and crotonaldehyde serve as metallo-aldehyde enolate precursors, participating in selective cross-aldolization with a-ketoaldehydes [24c]. The resulting/ -hydroxy-y-ketoaldehydes are highly unstable, but may be trapped in situ through the addition of methanolic hydrazine to afford 3,5-disubstituted pyridazines (Table 22.4). 

TABLE 3 5. Reaction of Aldehydes with the Enolate from Diethyl Ketone and Bromoborane (R,R)-55b... 

The methods previously used to obtain single aldol products (or their dehydrated derivatives) from reactants where several aldol products are possible8 include the reaction of bromozinc enolates, from a-bromo-ketones, with aldehydes 9 the reaction of bromomagnesium enolates, from either a-bromoketones or from ketones and bromomagnesium... 

Some enantiomerically pure substituted 2-oxazolidinones are excellent as chiral auxiliaries. From the pioneering studies 2 conducted in the early 1980 s of the uses of such auxiliaries has emerged what is perhaps the most widely used method today for the preparation of enantiomerically highly enriched a-alkylalkanoic acids, alcohols and aldehydes, that is, the alkylation of enolates from chiral 3-acylated 2-oxazolidinones followed by auxiliary removal2 59. The early work has been reviewed60-62. These enantiomerically pure cyclic imide auxiliaries have been used not only for alkylations but also in a plethora of a-functionalization reactions, such as diastereoselective aldol, a-hydroxylation, a-amination and Diels-Alder reactions and these are discussed elsewhere in this volume. 

Having identified the (+)-stereoisomer as the biologically active isomer, several independent enantioselective syntheses of this stereoisomer were developed. The initial synthesis developed in discovery chemistry employed the diastereoselective aldol condensation pioneered by Braun as the key component. Thus, treatment of aldehyde 13 from the racemic synthesis with the magnesium enolate of (5)-(+)-2-acetoxy-l,l,2-triphenylethanol at -70 °C, afforded 17 in 60% yield as a 97 3 mixture of the / ,5 5,5-diastereomers by HPLC (Scheme 3). Ester exchange employing sodium methoxide provided the methyl ester in quantitative yield. Reaction of this ester with three equivalents of lithio-f-butylacetate at -40 °C afforded the nearly enantiomerically pure r-butyl ester analog of racemic 14 in 75% yield. 

Enolization is an acid-base reaction (2-24) in which a proton is transferred from the a carbon to the Grignard reagent. The carbonyl compound is converted to its enolate ion form, which, on hydrolysis, gives the original ketone or aldehyde. Enolization is important not only for hindered ketones but also for those that have a relatively high percentage of enol form, e.g., p-keto esters, etc. In reduction, the carbonyl compound is reduced to an alcohol (6-25)... 

If die enolate nucleophile is derived from an aldehyde or ketone different than die carbonyl electrophile, a crossed-aldol condensation results. Normally best success is achieved if the carbonyl electrophile employed for the crossed-aldol condensation is more reactive than the carbonyl electrophile from which the enolate is derived. For example, ketone etiolates react with aldehydes effectively, but aldehyde enolates do not give the crossed aldol with most ketones but self-condense instead. 

Therefore the value of the procedure is greatly improved by using trimethylsilyl (TMS) enol ethers 200, which are easily accessible in situ from aldehydes and ketones in an ( )- or (Z)-selective way [56], Here the liberation of the aldehyde moiety from the initially formed dihydropyran takes place under the reaction conditions after the cycloaddition. TBDMS ethers 197 are too stable and can not be used in the domino process (Scheme 5.39). 

Stoichiometric, irreversible formation of enolates from ketones or aldehydes is usually performed by addition of the carbonyl compound to a cold solution of LDA. Additives and the solvent can strongly influence the rate of enolate formation [23]. The use of organolithium compounds as bases for enolate formation is usually not a good idea, because these reagents will add to ketones quickly, even at low temperatures. Slightly less electrophilic carbonyl compounds, for example some methyl esters [75], can, however, be deprotonated by BuLi if the reactants are mixed at low temperatures (typically -78 °C), at which more metalation than addition is usually observed. A powerful lithiating reagent, which can sometimes be used to deproto-nate ketones at low temperatures, is tBuLi [76],... 

The Mannich reaction of an aldehyde enol (example Formula C in Figure 12.14) or a ketonic enol (example Formula C in Figure 12.15) often proceeds beyond the hydrochloride of a /l-aminocarbonyl compound or the Mannich base. The reason is that the secondary amine or its hydrochloride, which has previously been incorporated as part of the iminium ion, is relatively easy to eliminate from these two types of product. The elimination product is an a,fi-unsaturated aldehyde (example Formula E in Figure 12.14) or an a,/l-unsaturated ketone (example Formula D in Figure 12.15)—that is, an a,/l-unsaturated carbowyl compound. Figure 13.51 will show how the Mannich reaction of a carboxylated lactonic enol provides access to an a-methylene lactone, that is, an a,/l-unsaturated carboxyl compound. 

B as an ester- or lactone-substituted aldehyde enolate. Such enolates undergo condensations with all kinds of aldehydes, including paraformaldehyde. An adduct E is formed initially, acy-lating itself as soon as it is heated. The reaction could proceed intramolecularly via the tetrahedral intermediate D or intermolecularly as a retro-Claisen condensation. In both cases, the result is an acyloxy-substituted ester enolate. In the example given in Figure 13.50, this is the formyloxy-substituted lactone enolate C. As in the second step of an Elcb elimination, C eliminates the sodium salt of a carboxylic acid. The a,/)-unsaturated ester (in Figure 13.50 the 0J,/3-unsaturated lactone) remains as the aldol condensation product derived from the initial ester (here, a lactone) and the added aldehyde (here, paraformaldehyde). 

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