Enolate cyclic

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],... 

Addition of a hydroxy group to alkynes to form enol ethers is possible with Pd(II). Enol ether formation and its hydrolysis mean the hydration of alkynes to ketones. The 5-hydroxyalkyne 249 was converted into the cyclic enol ether 250[124], Stereoselective enol ether formation was applied to the synthesis of prostacyclin[131]. Treatment of the 4-alkynol 251 with a stoichiometric amount of PdCl2, followed by hydrogenolysis with formic acid, gives the cyclic enol ether 253. Alkoxypalladation to give 252 is trans addition, because the Z E ratio of the alkene 253 was 33 1. 

The cyclic enol ether 255 from the functionalized 3-alkynoI 254 was converted into the furans 256 by the reaction of allyl chloride, and 257 by elimination of MeOH[132], The alkynes 258 and 260, which have two hydroxy groups at suitable positions, are converted into the cyclic acetals 259 and 261. Carcogran and frontalin have been prepared by this reaction[124]. 

Parham and co-workers have studied the addition of dichloro- and dibro-mocarbene to cyclic enol ethers and the transformations of the resulting dihalocyclopropanes. ... 

Alkylation of enamines with epoxides or acetoxybromoalkanes provided intermediates for cyclic enol ethers (668) and branched chain sugars were obtained by enamine alkylation (669). Sodium enolates of vinylogous amides underwent carbon and nitrogen methylation (570), while vicinal endiamines formed bis-quaternary amonium salts (647). Reactions of enamines with a cyclopropenyl cation gave alkylated imonium products (57/), and 2-benzylidene-3-methylbenzothiazoline was shown to undergo enamine alkylation and acylation (572). A cyclic enamine was alkylated with methylbromoacetate and the product reduced with sodium borohydride to the key intermediate in a synthesis of the quebrachamine skeleton (57i). 

The chiral BOX-copper(ll) complexes, (S)-21a and (l )-21b (X=OTf, SbFg), were found by Evans et al. to catalyze the enantioselective cycloaddition reactions of the a,/ -unsaturated acyl phosphonates 49 with ethyl vinyl ether 46a and the cyclic enol ethers 50 giving the cycloaddition products 51 and 52, respectively, in very high yields and ee as outlined in Scheme 4.33 [38b]. It is notable that the acyclic and cyclic enol ethers react highly stereoselectively and that the same enantiomer is formed using (S)-21a and (J )-21b as the catalyst. It is, furthermore, of practical importance that the cycloaddition reaction can proceed in the presence of only 0.2 mol% (J )-21a (X=SbF6) with minimal reduction in the yield of the cycloaddition product and no loss of enantioselectivity (93% ee). 

As a part of the total synthesis of (+ )-corydalic acid methyl ester (12), a reaction of a cyclic enolate with an imine has been applied. The 2-toluamide enolate 9, which in this case is substituted at the methyl group, adds stereospecifically to imine 10, affording mainly tram-iso-quinolone 11 with a d.r. (transjds) > 95 525. 

Successful methodology for diastereoselective Michael additions with chirality in the donor is so far limited to chiral cyclic enolates. The stereocontrol is mainly due to shielding of one of the jr-faces of the enolate by the ring substituent that resides at the stereogenic center. The (nmv-diastereoselective Michael addition of (5)-2-methyl-3-vinylcyclopentanonc illustrates this principle154-157. 

The addition of sulphinyl chlorides to trimethylsilyl enol ether 138 affording a-ketosulphoxides 139 (equation 76) represents an extension of the reaction of sulphinyl chlorides with ketones. This reaction has attracted attention only recently. Sergeev and coworkers192 reported that treatment of sulphinyl chlorides with acyclic enol ethers afforded a-ketosulphoxides 139 in good to excellent yields. Meanwell and Johnson193 observed that in the case of cyclic enol ethers the corresponding sulphoxides were formed only in very low yields. They found, however, that the introduction of an equivalent amount of a Lewis acid into the reaction mixture markedly promotes the desired reaction, whereas the use of catalytic amounts of a Lewis acid led to a substantial reduction in the yield. This is most probably due to the formation of a complex, between the a-ketosulphoxide and the Lewis acid. 

An alternative approach to cyclic enol ethers that avoids the metathesis of vinyl ethers has recently been developed by Snapper et al. [77a] and by Schmidt... 

Scheme 20 RCM-isomerization sequence for the synthesis of cyclic enol ethers [77b]...

Clark s group also reported on ring-closing enyne metathesis for the preparation of six- and seven-membered cyclic enol ethers 428 n= 1,2) as potential building blocks for the synthesis of marine polyether natural compounds such as brevetoxins and ciguatoxins. Metathesis products 428 were obtained from ene-ynes 427 in 72-98% yield when the NHC-bearing catalyst C was used (Scheme 84) [179]. 

Scheme 84 Synthesis of cyclic enol ethers 428 by enyne RCM [179]...

In the first step an S03 molecule is inserted into the ester binding and a mixed anhydride of the sulfuric acid (I) is formed. The anhydride is in a very fast equilibrium with its cyclic enol form (II), whose double bonding is attacked by a second molecule of sulfur trioxide in a fast electrophilic addition (III and IV). In the second slower step, the a-sulfonated anhydride is rearranged into the ester sulfonate and releases one molecule of S03, which in turn sulfonates a new molecule of the fatty acid ester. The real sulfonation agent of the acid ester is not the sulfur trioxide but the initially formed sulfonated anhydride. In their detailed analysis of the different steps and intermediates of the sulfonation reaction, Schmid et al. showed that the mechanism presented by Smith and Stirton [31] is the correct one. 

Note 1. The term glycal is a non-preferred, trivial name for cyclic enol ether derivatives of sugars having a double bond between carbon atoms 1 and 2 of the ring. It should not be used or modified as a class name for monosaccharide derivatives having a double bond in any other position. 

The facial selectivity of a number of more specialized enolates has also been explored, sometimes with surprising results. Schultz and co-workers compared the cyclic enolate H with I." Enolate H presents a fairly straightforward picture. Groups such as methyl, allyl, and benzyl all give selective (3-alkylation, and this is attributed to steric factors. Enolate I can give either a- or (3-alkylation, depending on the conditions. The presence of NH3 or use of LDA favors a-alkylation, whereas the use... 

A number of cyclic enol ethers have been prepared by Wittig and... 

Li s group prepared a series of substituted 2-(hydroxyalkyl)tetrahydroquinohne derivatives 2-619 and 2-620 starting from anilines 2-617 and cyclic enol ethers 2-618 in the presence of catalytic amounts of InCl3 (Scheme 2.141) [322], Good yields of 73-90 % were obtained with an electron-donating or no substituent R at the aniline moiety. 

It can be assumed that, in the presence of InCl3 and water, the cyclic enol ethers 2-618 form a hydroxy aldehyde which reacts with the aniline to give an aromatic im-inium ion. This represents an electron-poor 1,3-butadiene which can undergo a hetero-Diels-Alder reaction [323] with another molecule of 2-618 to give a mixture of the diastereomeric tetrahydroquinolines 2-619 and 2-620. 

Katsuki et al. have reported that high enantioselectivity can be obtained in the oxidation of nonconjugated cyclic enol ethers by using Mn(salen) (34) as the catalyst.138 The reactions were performed in an alcoholic solvent to obtain a-hydroxy acetals as the products, because a-hydroxy acetals are tolerant to a weak Lewis acid like Mn(salen) and do not racemize during the reaction and the isolation procedure (Scheme 29). 

Interestingly, we were intrigued by the ESI mass spectrum of the compound, as the observed base peak consisted of [M-S02+Na]+. This led us to explore a thermal retro-Diels-Alder reaction that could afford the desired enone 69. It is noteworthy that the chemistry of cyclic enol-sulfites would appear to be an under-explored area with a few references reporting their isolation being found [57]. At last, we were also able to prepare epoxy ketone 70 from 69 in three steps, albeit epoxidation did not take place unless the TES group was removed. Spartan models reaffirmed our initial conformational assessment of enone 69 and epoxy ketone 70, which contain sp3-hybridized C8a and s/r-hybridized C8b (p s e u d o-. v/r - h y b r i d i zed C8b for 70) at the AB-ring junction (Fig. 8.12) and displayed the desired twisted-boat conformation in A-ring. 

Tetrabutylammonium peroxydisulfate-mediated oxidative cycloaddition was recently discovered to be a convenient method for the realization of fused acetal derivatives. It is believed that the reactive intermediate is the cyclic enol ethers of the 1,3-diketones. An example is presented below <00S1091>. 

Recently, Nicolaou and coworkers have devised a novel, one-pot strategy for the direct transformation of acyclic olefinic esters to cyclic enol ethers [34]. Unlike the molybdenum alkylidene 1 (see Sect. 3.2), initial reaction between the Tebbe reagent 93 and an olefinic ester results in rapid carbonyl olefination to afford a diene intermediate. Subsequent heating initiates RCM to afford the desired cyclic product (Scheme 17). 

Scheme 17. Titanium-mediated metathesis strategy for the conversion of olefinic esters (118) to cyclic enol ethers (123) (Nicolaou et al.) [34]...

Scheme 18. The conversion of olefinic ester 125 to cyclic enol ether 127. (a) 4.0 equiv of Tebbe reagent (93), 25°C, 20 min then reflux, 5 h, 71% (b) 1.3 equiv of Tebbe reagent (93), 25°C, 20 min, 77% (c) 2.0 equiv of Tebbe reagent (93), 25°C, 20 min then reflux, 3 h, 65% (Nicolaou et al.) [34a]...

Preliminary investigations in this area involved treatment of olefinic ester 125 with a large excess (4 equiv) of the Tebbe reagent 93 (Scheme 18) [34a]. After 20 min at 25°C, the mixture was heated at reflux for 5 h. This resulted in the formation of tricyclic enol ether 127 in 71% overall yield. If only 1.3 equiv of Tebbe reagent 93 was employed and the reaction stopped after 20 min at 25°C,the olefinic enol ether 126 could be isolated in 77% yield. The proposed intermediacy of diene 126 in the initial tandem sequence was validated by its subsequent conversion into the cyclic enol ether 127 under the original reaction conditions [34a],... 

These initial forays verified the utility of the process and provided mechanistic information which set the stage for further exploration into the scope of the process. Successful reactions with a variety of substrates demonstrated the generality of the process, with 6- and 7-membered cyclic enol ethers being most accessible (Scheme 19). Preservation of the trisubstituted olefin present in the complex substrate 132 indicates the chemoselective nature of the process [34a]. 

A limitation to the use of the Tebbe reagent 93 was observed during the attempted conversion of substrates 139 and 142 to the tricyclic systems 141 and 144 respectively (Scheme 21). The major products from these reactions were olefinic alcohols 140 and 143. These products presumably resulted from sequential hydrolysis and olefination of the initially formed cyclic enol ethers. The problem associated with these sensitive substrates was overcome through use of the less Lewis-acidic Petasis reagent 110, which provided access to the desired products 141 and 144 [34a]. 

Scheme 21. Titanium-mediated metathesis strategy for the synthesis of cyclic enol ethers and hydroxy olefins, (a) Tebbe reagent (93), THF, reflux, 41% (140), 41% (143) (b) Petasis reagent (110), THF, reflux, 60% (141), 30% (144) (Nicolaou et al.) [34a]...

Preparation of the bridging fragment 150 (Scheme 23) followed a similar pathway. In this case, stereoselective reduction of the cyclic enol ether 149 formed by the RCM of 148 was achieved using Et3SiH and TFA, leading after des-ilylation to the WVU ring system 150 [34b]. 

An alternative approach involves a two-step procedure, in which carbonyl olefination, using the Tebbe reagent 93, generates an acyclic enol ether-olefin (Scheme 16). In this case, subsequent RCM using molybdenum alkylidene 1 proceeds to give cyclic enol ethers. An efficient, one-pot carbonyl olefination-RCM approach has been developed by Nicolaou et al. for the formation of cyclic enol... 

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