6-Dicarbonyl compounds enol form

In solution, open-chain 1,3-dicarbonyl compounds enolize practically exclusively to the czls-enolic form (4b), which is stabilized by intramolecular hydrogen bonding. In contrast, cyclic 1,3-dicarbonyl compounds e.g. cycloalkane-1,3-diones [46]), can give either trans-Qnols (for small rings) or czk-enols (for large rings). As the diketo form is usually more dipolar than the chelated cu-enolic form, the keto/enol ratio often depends on solvent polarity. This will be discussed in more detail for the cases of ethyl acetoacetate and acetylacetone [47-50, 134, 135]. 

Dicarbonyl compounds are formed by reaction of silyl enol ethers with methyl vinyl ketones in the presence of BF3 Et20 and an alcohol (Eq. 84) [139]. 

There are scanty reports about the Baker-Venkataraman rearrangement which is used in synthesis very seldom. Thus, in the approach mentioned in equation 106 the C-glycoside 239 undergo O-benzoylation to afford the ester 240, which rearranges into the 1,3-dicarbonyl compound 241 formed as a keto-enol mixture in 48% yield (equation 109) ° . 

Dicarbonyl compounds are formed from the reaction of silyl enol ethers with methyl vinyl ketones in the presence of BF3 OEt2 and an alcohol (eq 9). a-Methoxy ketones are formed from a-diazo ketones with BF3-OEt2 and methanol, or directly from silyl enol ethers using iodobenzene/BF3-OEt2 in methanol. ... 

The TiCU-promoted Michael reaetion proceeds under very mild conditions (—78 °C) this suppresses side-reactions and 1,5-dicarbonyl compounds are formed in good yields. For TiCU-sensitive compounds, a mixture of TiCU and Ti(0-/-Pr)4 is used. From silyl enol ethers and a,p-unsaturated ketones, 1,5-dicarbonyl compounds are formed (eq 32). The reaction also proceeds for a,p-unsaturated acetals. Silylketene acetals react with a,p-unsaturated ketones or their acetals to form 8-0x0 esters (eq 33). ... 

The carbonyl group forms a number of other very stable derivatives. They are less used as protective groups because of the greater difficulty involved in their removal. Such derivatives include cyanohydrins, hydrazones, imines, oximes, and semicarbazones. Enol ethers are used to protect one carbonyl group in a 1,2- or 1,3-dicarbonyl compound. 

Although the antithyroid activity of compounds incorporating an enolizable thioamide function was discussed earlier, this activity was in fact first found in the pyrimidine series. The simplest compound to show this activity, methylthiouracil (80) (shown in both enol and keto forms), is prepared quite simply by condensation of ethyl acetoacetate with thiourea.Further work in this series shows that better activity was obtained by incorporation of a lipophilic side chain. Preparation of the required dicarbonyl compound starts with acylation of the magnesium enolate of the unsyrametrically esterified malonate, 81, with butyryl chlo-... 

It becomes clear that in all these compounds it is the conjugate base that takes part in the substitution proper. For mono- and particularly 1,3-dicarbonyl compounds this result actually removes the problem of whether it is the keto or the enol form which enters into an electrophilic substitution by diazonium ions, halogenating agents, and many other reagents. The keto and the enol form are distinct species, but they have one (common) conjugate base This was made clear quite early, but even today there are many chemists who seem not to be aware of it. 

The enolized form of 2-acetyl-2-cyclohexen-l-one has been synthesized in low yield by dehydrochlorination of 2-acetyl-2-chlorocyclohexanone in collidine at 180° and by elimination of acetamide from 3-acetamido-2-acetylcyclohexanone at 120-140°. The preparation of other a,/3-unsaturated /3-dicarbonyl compounds has been attempted with varying degrees of success. The... 

Ketones such as methyl cyclohexyl ketone 1284 react with DMSO/TCS 14, via their enol form, to give 21% of the chloroketone 1285 a and 63% of the a-methyl mercaptoketone 1286 [70]. Reaction of 1284 with DMSO/MesSiBr (TBS) 16 affords 85% of the bromo compound 1285 b and 12% hexahydrophenacyl bromide 1287 but no 1286 [71]. Whereas reaction of tra s-4-phenyl-3-buten-2-one (benzalacetone) 1288 with DMSO/TCS 14 gives 81% of the sulfonium salt 1289 [70], the y9-dicar-bonyl compound ethyl acetoacetate furnishes 69% of 1290 [70]. In contrast with DMSO/TCS 14, the combination DMSO/TBS 16 effects selective monobromina-tion of y9-dicarbonyl compounds [71] (Scheme 8.28). 

Version (b) has a four-channel flow guidance that encompasses two mixing tees in two simple mixing tees (Figure 4.5) [8]. An example of this function is the flow guidance for the Michael addition. In a first step, the base and 1,3-dicarbonyl compound streams merge. The enolate stream thus formed is then mixed with the Michael acceptor. Microporous silica frits are set into the channels to minimize... 

As the name implies, the first step of this domino process consists of a Knoevenagel condensation of an aldehyde or a ketone 2-742 with a 1,3-dicarbonyl compound 2-743 in the presence of catalytic amounts of a weak base such as ethylene diammonium diacetate (EDDA) or piperidinium acetate (Scheme 2.163). In the reaction, a 1,3-oxabutadiene 2-744 is formed as intermediate, which undergoes an inter- or an intramolecular hetero-Diels-Alder reaction either with an enol ether or an alkene to give a dihydropyran 2-745. 

In 1997, the controversial mechanism of the Biginelli reaction was reinveshgated by Kappe using NMR spectroscopy and trapping experiments [94], and the current generally accepted process was elucidated (see Scheme 9.23). The N-acyliminium ion 9-112 is proposed as key intermediate this is formed by an acid-catalyzed reaction of an aldehyde with urea or thiourea via the semiaminal 9-111. Intercephon of 9-112 by the enol form of the 1,3-dicarbonyl compound 9-113 produces the open-chain ureide 9-114, which cyclizes to the hexahydropyrimidine 9-115. There follows an elimination to give the final product 9-116. 

Schreiber and his coworkers have published extensively over the past decade on the use of this photocycloaddition for the synthesis of complex molecules730 81. Schreiber was the first to recognize that the bicyclic adducts formed in these reactions could be unmasked under acidic conditions to afford threo aldol products of 1,4-dicarbonyl compounds (175 to 176) (Scheme 40). The c -bicyclic system also offers excellent stereocontrol in the addition of various electrophilic reagents (E—X) to the enol ether of these photoadducts on its convex face (175 to 177). This strategy has been exploited in the synthesis of a variety of architecturally novel natural products. 

Cyclopentenones. 1,3-Dicarbonyl compounds add to enol ethers or esters (terminal) in the presence of Mn30(OAc)7 (excess) to form l-alkoxy-l,2-dihydro-furans. These can be converted to a 1,4-diketone, which undergoes aldol cyclization to fused (or spiro) cyclopentenones.1... 

Furans.2 Enol ethers, p-dicarbonyl compounds, and Mn(III) acetate (2 equiv.) react in acetic acid (25°) to form l-aIkoxy-l,2-dihydrofurans, which form furans readily on acid-catalyzed elimination of ROH. 

Like reaction rates, the effect of solvent polarity on equilibria may be rationalized by consideration of the relative polarities of the species on each side of the equilibrium. A polar solvent will therefore favour polar species. A good example is the keto-enol tautomerization of ethyl acetoacetate, in which the 1,3-dicarbonyl, or keto, form is more polar than the enol form, which is stabilized by an intramolecular H-bond. The equilibrium is shown in Scheme 1.3. In cyclohexane, the enol form is slightly more abundant. Increasing the polarity of the solvent moves the equilibrium towards the keto form [28], In this example, H-bonding solvents will compete with the intramolecular H-bond, destabilizing the enol form of the compound. 

The authors point out that all 1,3-dicarbonyl compounds exist in the solid as the enol forms, many of which are in the internally hydrogen-bonded syn configuration. All known structures of the latter materials appear to belong to one of two classes those in which the formal C-0(H) and 0=0 bonds are significantly different in length, and those in which they are not. The authors term the first group ordered and the second disordered, referring to the possible populations of the two states 59. 

The preferential -configuration of the enol esters, derived from p-dicarbonyl compounds under phase-transfer conditions, contrasts with the formation of the Z-enol esters when the reaction is carried out by classical procedures using alkali metal alkoxides. In the latter case, the U form of the intermediate enolate anion is stabilized by chelation with the alkali metal cation, thereby promoting the exclusive formation of the Z-enol ester (9) (Scheme 3.5), whereas the formation of the ion-pair with the quaternary ammonium cation allows the carbanion to adopt the thermodynamically more stable sickle or W forms, (7) and (8), which lead to the E-enol esters (10) [54],... 

The reductive cyclization of readily available enol phosphates of 1,3-dicarbonyl compounds bearing pendant olefinic units has been explored [66,67]. The chemistry is exceptionally interesting, and provides a unique route to structures possessing a cyclopropyl unit which is suitable for structural elaboration. The reaction occurs in a manner wherein the phosphate-bearing carbon behaves like a carbene that adds to the pendant alkene to form a cyclopropane. While this provides a useful way of viewing the transformation, mechanistic studies indicate that a carbene is not an actual intermediate. Examples are portrayed in Table 11. 

A mechanistic study of acetophenone keto-enol tautomerism has been reported, and intramolecular and external factors determining the enol-enol equilibria in the cw-enol forms of 1,3-dicarbonyl compounds have been analysed. The effects of substituents, solvents, concentration, and temperature on the tautomerization of ethyl 3-oxobutyrate and its 2-alkyl derivatives have been studied, and the keto-enol tautomerism of mono-substituted phenylpyruvic acids has been investigated. Equilibrium constants have been measured for the keto-enol tautomers of 2-, 3- and 4-phenylacetylpyridines in aqueous solution. A procedure has been developed for the acylation of phosphoryl- and thiophosphoryl-acetonitriles under phase-transfer catalysis conditions, and the keto-enol tautomerism of the resulting phosphoryl(thiophosphoryl)-substituted acylacetonitriles has been studied. The equilibrium (388) (389) has been catalysed by acid, base and by iron(III). Whereas... 

Vitamin C, also known as L-ascorbic acid, clearly appears to be of carbohydrate nature. Its most obvious functional group is the lactone ring system, and, although termed ascorbic acid, it is certainly not a carboxylic acid. Nevertheless, it shows acidic properties, since it is an enol, in fact an enediol. It is easy to predict which enol hydroxyl group is going to ionize more readily. It must be the one P to the carbonyl, ionization of which produces a conjugate base that is nicely resonance stabilized (see Section 4.3.5). Indeed, note that these resonance forms correspond to those of an enolate anion derived from a 1,3-dicarbonyl compound (see Section 10.1). Ionization of the a-hydroxyl provides less favourable resonance, and the remaining hydroxyls are typical non-acidic alcohols (see Section 4.3.3). Thus, the of vitamin C is 4.0, and is comparable to that of a carboxylic acid. 

The asymmetric allylic C-H activation of cyclic and acyclic silyl enol ethers furnishes 1,5-dicarbonyl compounds and represents a surrogate of the Michael reaction [136]. When sufficient size discrimination is possible the C-H insertion is highly diastereoselective, as in the case of acyclic silyl enol ether 193 (Eq. 22). Reaction of aryldia-zoacetate 192 with 193 catalyzed by Rh2(S-DOSP)4 gives the C-H insertion product 194 (>90% de) in 84% enantiomeric excess. A second example is the reaction of the silyl enol ether 195 with 192 to form 196, a product that could not be formed from the usual Michael addition because the necessary enone would be in its tautomeric naphthol form (Eq. 23). 

In its original form, the Michael addition consisted on the addition of diethyl malonate across the double bond of ethyl cinnamate in the presence of sodium ethoxide to afford a substituted pentanedioic acid ester. Currently, all reactions that involve a 1,4-addition of stabilized carbon nucleophiles to activated 7i-systems are known as Michael additions. Among the various reactants, enolates derived from p-dicarbonyl compounds are substrates of choice due to their easy deprotonation under mild conditions. Recently, Michael addition-based MCRs emerged as highly potential methodologies for the synthesis of polysubstituted heterocycles in the five- to seven-membered series. 

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