Enol ethers from 1,3-dicarbonyl compounds

The procedure described illustrates a general method for the preparation of a, S-unsaturated aldehydes and ketones from the enol ethers of -dicarbonyl compounds. 

The reaction of tnfluoromethyl-substituted A -acyl umnes toward nucleophiles in many aspects parallels that of the parent polyfluoro ketones Heteronucleophiles and carbon nucleophiles, such as enarmnes [37, 38], enol ethers [38, 39, 40], hydrogen cyanide [34], tnmethylsilylcarbomlnle [2,47], alkynes [42], electron-nch heterocycles [43], 1,3-dicarbonyl compounds [44], organolithium compounds [45, 46, 47, 48], and Gngnard compounds [49,50], readily undergo hydroxyalkylation with hexafluoroace-tone and amidoalkylation with acyl imines denved from hexafluoroacetone... 

The 1,3-dicarbonyl components can be replaced by an enol ether, which can be prepared by Claisen condensation from an ortho ester and a reactive methylene compound. ... 

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). 

It is not customary to attempt the isolation of ketone or aldehyde intermediates (121) the formula serves merely as a reminder that once hydrolysis of the protecting enol ether or acetal occurs, the same type of structure is formed from any given dicarbonyl compound. Cyclization has been carried out in refluxing ethanolic picric acid or acetic anhydride with a few drops of sulfuric acid, but Hansen and Amstutz (63JOC393) offered excellent theoretical reasons for avoiding an excess of acid, and reported that best results (Table 3) can be obtained by refluxing the dry hydrobromide in acetic anhydride containing no sulfuric acid. 

While fluoroxy compounds react well with enol derivatives, fluorine in general does not. However, there are various reports where such reactions are described and in certain cases even with decent yields. In 1982 it was reported that pyruvates with a dominant enolic form react well with fluorine, to give the corresponding fluoro derivatives l.78 Several silyl enol ethers 2 and 379 including ones made from 1,3-dicarbonyl derivatives 480 react quite satisfactorily with fluorine to give the expected a-fluoro ketones. Steroidal 16-enol acetates react with fluorine to form mainly 16a-fluoro-17-oxo steroids e.g. 5.81... 

Dicarbonyl compounds.1 The reaction of enol silyl ethers with methyl vinyl ketone catalyzed by BF3 etherate results in 1,5-dicarbonyl compounds. Almost quantitative yields can be obtained, even from hindered ketones, by addition of an alcohol or even, to a less extent, of water. 

Solid-phase three-component domino-Knoevenagel-hetero-Diels-Alder reaction can also be performed using a resin-linked 1,3-dicarbonyl compound such as 100 with aldehydes and an enol ether to give dihydropyrans 102 via the intermediately formed 1-oxa-l,3-butadiene 101 (Scheme 5.18) [30], The resin can be deaved off after the reaction by solvolysis, for instance using sodium methanolate to give the corresponding methyl ester 103 as a mixture of diastereomers. The overall yield varies from 12 to 37% and the selectivity from 1 1 to 1 5 in favor of the tis-product depending on the applied aldehyde. The crude dihydropyrans thus obtained are reasonably pure (> 90% HPLC). 

The kinetic reprotonation by a series of carbonyl-based acids, of the lithium enolate obtained from 2,4-dimethyltetralone either by LDA-mediated deprotonation or by cleavage of its silyl enol ether, was studied by Eames (Scheme 71)352. The diastereoselective ratio, close to the thermodynamic value, obtained with methanol (pKa = 29 in DMSO) is probably due to equilibration. The difference observed in the presence of an additive was interpreted as the result of a fine balance between the coordinating ability, the intrinsic acidity, and probably the concentration of the enolic form of the cyclic and linear dicarbonyl acidic compounds. 

Treatment of 1,3-dicarbonyl compounds with DBP in a methoxide/methanol system affords 2-alkyl-4-[(phenylsulfonyl)methyl]furans, where reaction proceeds by Initial addition-elimination on the vinyl sulfone moiety. In contrast, silyl enol ethers in the presence of silver tetrafluoroborate resulted in products derived from Sn2 displacement at the allylic site.11 Anions derived from 1,3-dicarbonyls substituted at the C-2 position are found to induce a complete reversal in the mode of ring closure.12 The major products obtained are 3-[(phenylsulfonyl)methyl]-substituted cyclopentenones. The internal displacement reaction leading to the furan ring apparently encounters an unfavorable Ai -interaction in the transition state when a substituent group is present at the 2-position ol the dicarbonyl compound. This steric Interaction is not present in the transition state leading to the cyclopentenone ring. 

When ethoxide is used as a base to abstract a-proton, it could react with the alkyl halide (Sn2) to form ether. However, the acid-base equilibrium with the diketone prefers the more stable, less basic enolate over the ethoxide, essentially consuming the ethoxide. Thus, the very stable enolates from 1,3-dicarbonyl compounds are able to undergo Sn2 reactions with alkyl halides without competition from the alkoxide catalyst. 

In the acid-catalyzed ortho ester Claisen rearrangement of allylic alcohol (303) with trimethyl orthobutyrate, diastereomers (304), (305) and (306) were isolated in a ratio of 63 30 7 (Scheme 53). The 3,3-sigmatropic rearrangement occuned with a high degree of stereofacial selectivity from the p-face of the allylic alcohol (a >13 1 for Ht). In contrast, Qaisen rearrangement of the enol ether (307) at 135-140 C (PhH, sealed tube) provid the desired -dicarbonyl compound (308) as a single diastereomer at... 

Michael reactions of silyl enolates or ketene silyl acetals with a, -unsaturated carbonyl compounds are among the most important carbon-carbon bond-forming processes in organic synthesis. Sc(OTf)3 was found to be effective [4], and the reactions proceeded smoothly in the presence of a catalytic amount of Sc(OTf)3, under extremely mild conditions, to give the corresponding 1,5-dicarbonyl compounds in high yields after acid work-up (Eq. 2). Silyl enolates derived from ketones, thioesters, and esters were applicable, and no 1,2-addition products were obtained. The products could, furthermore, be isolated as synthetically valuable silyl enol ethers (I) when acid-free work-up was performed. The catalyst could be recovered almost quantitatively and could be re-used. 

The reductive coupling of carbonyl compounds with formation of C-C double bonds was developed in the early seventies and is now known as McMurry reaction [38, 39]. The active metal in these reactions is titanium in a low-valent oxidation state. The reactive Ti species is usually generated from Ti(IV) or Ti(III) substrates by reduction with Zn, a Zn-Cu couple, or lithium aluminum hydride. A broad variety of dicarbonyl compounds can be cyclized by means of this reaction, unfunctionalized cycloalkenes can be synthesized from diketones, enolethers from ketone-ester substrates, enamines from ketone-amide substrates [40-42], Cycloalkanones can be synthesized from external keto esters (X = OR ) by subsequent hydrolysis of the primary formed enol ethers (Scheme 9). 

If the 1,5-dicarbonyl compound is required, then an aqueous work-up with either acid or base cleaves the silicon-oxygen bond in the product but the value of silyl enol ethers is that they can undergo synthetically useful reactions other than just hydrolysis. Addition of the silyl enol ether derived from acetophenone (PhCOMe) to a disubstituted enone promoted by titanium tetrachloride is very rapid and gives the diketone product in good yield even though a quaternary carbon atom is created in the conjugate addition. This is a typical example of this very powerful class of conjugate addition reactions. 

A TMSOTf-initiated cyclization of the dicarbonyl substrate was invoked to explain the reactivity pattern [79]. Selective complexation of the less hindered carbonyl group activates it toward intramolecular nucleophilic attack by the more hindered carbonyl which leads to an oxocarbenium species. Subsequent attack by the enol ether results in addition to the more hindered carbonyl group. The formation of this cyclic intermediate also explains the high stereochemical induction by existing asymmetric centers in the substrates, as demonstrated by Eq. 52, where the stereochemistry at four centers is controlled. A similar reactivity pattern was observed for the bis-silyl enol ethers of / -diketones. The method is also efficient for the synthesis of oxabicyclo[3.3.1] substrates via 1.5-dicarbonyl compounds, as shown in Eq. 53. Rapid entry into more complex polycyclic annulation products is possible starting from cyclic dicarbonyl electrophiles [80]. 

Interesting heteroatom-substituted derivatives such as 67 have also been synthesized via the reaction of bis enol ether 66 with thiol-containing dicarbonyl electrophiles, Eq. 54 [81]. Compound 68 bearing a bridgehead silyl substituent was produced from the reaction of 65 with a ketoacylsilane [82], Subsequent decarboxylation and desilylation of 68 generates 69, Eq. 55. The overall sequence represents a method to obtain the product of a formal inversion of the usual reactivity of 65 with ketoaldehydes. Extensive studies failed to reverse the observed regio selectivity. 

I, 5-dicarbonyl compounds and their interesting and varied chemistry, e.g., the formation of cyclohexenones from aldol condensation of the products. As an extension of the de Mayo reaction (the photocycloaddition of enolated /i-diketones to double bonds) enol esters, enol ethers, vinylogous esters and amides, and dioxinone have been employed as the enone components. Some intermolecular examples have already been discussed in Section 1.6.1.4.2.1.6. (cf. Table 4, entries 2 and 3) and some intramolecular systems are collected in Table 5, entries 10,... 

Cycloaddition. Different versions of [2+2+2]cycloaddition are known to be induced by cationic Rh(I) salts with support of BINAP ligands. Diynes combining with enol ethers lead to products containing a new benzene ring/° and ring fused dihydropyrans are formed from enynes and a-dicarbonyl compounds. 

Symmetrical 1,5- diketones may be prepared by addition of a THF solution of a ketone lacking a1 - hydrogens to a solution of potassium in DMF - THF the central methylene appears to derive from the formal carbon of dimethylformamide [equation (42)].143 A more general preparation of 1,5- dicarbonyl compounds uses the boron trifluoride etherate catalysed reaction of silyl enol ethers with 3-methoxyallyl alcohols in nitromethane [equation (43)]. The... 

If the retrosynthesis follows route I (addition of water to the fiiran C-2/C-3 bond followed by bond opening O/C-2, i.e. an enol ether hydrolysis according to steps a-c), then the 1,4-dicarbonyl system 8 is obtained as the first suggested educt. Starting from 8, the fiiran system should be formed by a cyclic dehydration. Further retroanalysis of 8 leads via f to the ar-halocarbonyl compound 10 and to the enolate of the carbonyl compound 11. The latter should be convertible into the 1,4-dicarbonyl system 8 by alkylation with 10. 

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