Enols specific

Summary of methods for alkylating enolates Specific enoi equivaient... 

The direct oxidation of enolates with (lb) gives a-hydroxy carbonyl compounds in excellent yield <91TL715>. The reaction of (lb), isolated or in situ, with the enolates and/or enols of ketones, esters, /i-diketones, (i-oxo esters, and fi-oxo lactones affords the a-hydroxy carbonyl compounds in good yields <91CB2369>. In 1994, Adam et al. have shown that the diastereoselectivity of the dioxirane-enolate reaction is dependent on the metal partner in the enolate. Specifically, use of titanium enolates give much higher diastereoselectivities than sodium enolates <94JOC2358>. 

Enolates are undoubtedly the most versatile intermediates for C-C, C-N, C-O bond-forming reactions [36]. Continuous progress has been made not only in fundamental operations involving these anionic species but also during the synthesis of complex natural products. Compared with metal enolates with counter cations of, e.g., B, Si, Li, Na, K, Mg, Ti, Sn, Cu, etc., aluminum enolates have found fewer apphcations, probably because no particular advantages over the other metals have been perceptible. There are, however, still intriguing aspects of novel reactivity and selectivity in the formation and reaction of aluminum enolates. Specifically, very recent development have highhghted pre-formation of Lewis acid-carbonyl complexes by use of bulky aluminum compounds as precursors of aluminum enolates the behavior of these complexes is unprecedented. 

The first three chapters discuss fundamental bonding theory, stereochemistry, and conformation, respectively. Chapter 4 discusses the means of study and description of reaction mechanisms. Chapter 9 focuses on aromaticity and aromatic stabilization and can be used at an earlier stage of a course if an instructor desires to do so. The other chapters discuss specific mechanistic types, including nucleophilic substitution, polar additions and eliminations, carbon acids and enolates, carbonyl chemistry, aromatic substitution, concerted reactions, free-radical reactions, and photochemistry. 

Site-specificity of the reaction is established in the first step since enolate formation involves the carbonyl carbon and the former halide bearing carbon, while the stereospecificity of the incoming deuterium is determined during the second step. It appears that the ketonization in deuterioacetic acid yields mainly the kinetic product (axial attack) although deuteration is... 

Bromination of 5j5-3-ketones yields the equatorial 4 -bromo compounds (22) as the thermodynamic or kinetic products,although the presence of a considerable amount of 2-bromo isomer has been reported in bromination with phenyltrimethylammonium bromide-perbromide. This is in keeping with other evidence that enolization of 5j5-3-ketones is not specifically directed to C-4. Cleaner results would probably be obtained via thermodynamic enol acelylation. ... 

Agnello and Laubach suggested that the dehydrogenation of A" -3-ketones to A -3-ketones by chloranil proceeds through the A -enol, which suffers hydride loss from C-7. The failure of 7a-methyl-A -3-ketones to undergo dehydrogenation while the 7/5-isomers do so readily indicates that specific removal of the 7a (axial) hydrogen probably occurs in unsubstituted compounds. ... 

The smooth conversion of the enol acetate (151) into an A -acyl derivative (152) under extremely mild conditions points to the high acylating capacity of these esters. This cleavage of isoxazolium salts is also caused by other anions of carboxylic acids, and thus they can be readily converted to reactive enol esters. A very convenient and specific synthesis of peptides due to Woodward et is based on... 

Ketones, esters, and nitriles can all be alkylated using LDA or related dialkyl-amide bases in THE. Aldehydes, however, rarely give high yields of pure products because their enolate ions undergo carbonyl condensation reactions instead of alkylation. (We ll study this condensation reaction in the next chapter.) Some specific examples of alkylation reactions are shown. 

The key step in a short and efficient synthesis of pleraplysillin-1 (127) is the palladium-catalyzed cross-coupling of vinylstannane 125 with vinyl triflate 126 (see Scheme 33). This synthesis is noteworthy in two respects. First, vinyl triflate 126 is generated regio-specifically from the kinetic enolate arising from a conjugate reduction of enone 124 the conjugate reduction of an enone is, in fact, a... 

Due to mechanistic requirements, most of these enzymes are quite specific for the nucleophilic component, which most often is dihydroxyacetone phosphate (DHAP, 3-hydroxy-2-ox-opropyl phosphate) or pyruvate (2-oxopropanoate), while they allow a reasonable variation of the electrophile, which usually is an aldehyde. Activation of the donor substrate by stereospecific deprotonation is either achieved via imine/enamine formation (type 1 aldolases) or via transition metal ion induced enolization (type 2 aldolases mostly Zn2 )2. The approach of the aldol acceptor occurs stereospecifically following an overall retention mechanism, while facial differentiation of the aldehyde is responsible for the relative stereoselectivity. 

Three types of synthases catalyze the addition of phosphoenolpyruvate (PEP) to aldoses or the corresponding terminal phosphate esters. By concurrent release of inorganic phosphate from the preformed enolate nucleophile, the additions are essentially irreversible. None of the enzymes are yet commercially available and little data are available oil the individual specificities for the aldehydic substrates. A bacterial NeuAc synthase (EC 4.1.3.19) has been used for the microscale synthesis of A -acetylncuraminic acid from Af-acetyl-D-mannosamine31 and its 9-azido analog from 2-acetamido-6-azido-2,6-dideoxy-D-mannose32. 

Although Baldwin s rules can be applied to ketone enolates, additional rules were added to make the terminology more specific. The orientation of the orbital as it approaches the reactive center must be considered for determining the correct angle of approach. Diagrams that illustrate the enolate rules are... 

Disconnection of the 1,3-dlketone obviously comes next but it will be better to add an activating group to control the reaction. One possibility is to acylate specific enol equivalent (56) with acid chloride (57). 

Specific enol equivalents will be needed for both synthons (61) and (66), Since (61) is to give a double bond but (66) is to give an alcohol, the logical choices are a Wittig reagent - actually (67) - for (61) and a Reformatsky reagent for (66). The ester to aldehyde conversion (65 63) Is easiest by over-reduction and re-... 

The problem arises in controlling the reaction. Cyclohexanone enolises easily but attacks Itself easily too. Direct acylation with RC02Jit and EtO catalyst gives poor yields. " Clearly a specific enol is needed. An activating group could easily be added, as in (72), but acylation of this, to replace the last remaining proton, is not a good idea (cf p 211 ),... 

The analysis uses the same starting material s whichever bond you disconnect iirst raalonate ester, PhCHO, and the specific enolate (2). This last could be an enamine, or an activated version (4) (cl p T 160 ff ) ... 

An uer Disconnection at the branchpoint is best giving acry.late (15) and specific enol (14),... 

Ansyr r Alkylation of the specific enol of the aldehyde In (13) will give (17). The enamine Is again the best way to do this. 

Tiic synthesis of enone (34) requires an aldol condensation between acetone and KCHO this may not give a good yield as RCHO may prefer to condense with Itself if it has enolisable protons. The alternative disconnection (33b) avoids this problem as we can use acetoacetatc for the synthon (34) and a specific enol equivalent for (35),... 

This is a l,4 diketone and disconnection of the central bond separates the two rings. We require a specific enol equivalent lor (4) - they used activated ketone (6) - and a reagent for unnatural synthon (5) -they used a-chloroketone (7). 

Disconnection of the central bond is unhelpful neither specific enolate (34) nor a-haloketone (35) will be easy to make. 

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