Cydic enol ethers

It can be assumed that, in the presence of InCl3 and water, the cydic 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. 

As vinyl ethers were known to be poor substrates in Ru-catalyzed olefin metath-eses, it has been difficult to obtain cydic enol ethers by RCM of the vinyl ethers. Recently, a novel method to obtain cyclic enol ethers has been reported, which afforded cydic enol ethers directly from easily prepared dienes containing an allyl ether moiety [46]. Treatment of 70 with diene 99 in CH2CI2 in the presence of small amount of H2 resulted in a formation of dihydropyran 101 (Eq. 12.40). Treatment of 70 with H2 has been thought to produce an active catalyst for the olefin isomerization, and only metathesis products are formed until a small amount of H2 is introduced in the reaction. These results implied that this reaction most likely proceeded by way of a formation of the cyclic olefin 100, which was subsequently converted to dihydropyran 101 by the newly formed isomerization catalyst. In addition to the tandem reaction shown in Eq. 12.40, another method for obtaining cydic enol ethers from allyl ethers has also been demonstrated [46b]. This method induded addition of the hydride donor, such as NaBH4, to the reaction solution after the metathesis reaction had been completed. Although attempts to observe an active species for olefin isomerization in the presence H2 failed, these results suggested participation of hydride species in the olefin isomerization. 

Formation of cydic enol ethers by carbonyl methylenation— olefin metathesis. 

Analogous treatment of the unsaturated ester 207 using 1,1-dibromoethane in this case cleanly produced the dihydropyran 208 in high yield on a gram scale (Scheme 2.73) [41bj. Cydic enol ether 208 was then efficiently advanced to a spiroacetal, which corresponds to the core structure of the bioactive polyketide spirofungin A. 

Nitradon of the potassium enolates of cycloalkanones with pentyl n silyl enol ethers with nitroniiim tetraflnoroborate " provides a method for the preparadon of cydic ct-nitro ketones. Tnflnoroacetyl nitrate generated from tnflnoroacedc anhydnde and ammonium nitrate is a mild and effecdve nitradug reagent for enol acetates fEq. 2.411. ... 

Silyl enol ethers, 23, 77, 99-117,128 Silyl enolates, 77 Silyl peroxides, 57 Silyl triflate, 94 Silyl vinyl lithium, 11 (E)-l -Silylalk-1 -enes, 8 Silylalumimum, 8 Silylation, 94 reductive, 26 a-C-Silylation, 113 O-Silylation.99,100 / -SilyIketone, 54 non-cydic, 55 Silylmagnesium, 8 Silyloxydienes, 112 Sodium hexamethyldisilazide, 89 Sodium thiosulphate pentahydrate, 59 Stannylation, see Hydrostannylation Stannylethene, 11 (Z)-Stilbene, 70 (E)-Stilbene oxide, 70 /3-Styryltrimethylsilane, 141 Swern oxidation. 84,88... 

Tandem carbonyl olefmation—olefin metathesis utilizing the Tebbe reagent or dimethyl-titanocene is employed for the direct conversion of olefinic esters to six- and seven-mem-bered cyclic enol ethers. Titanocene-methylidene initially reacts with the ester carbonyl of 11 to form the vinyl ether 12. The ensuing productive olefin metathesis between titano-cene methylidene and the ris-l,2-disubstituted double bond in the same molecule produces the alkylidene-titanocene 13. Ring-closing olefin metathesis (RCM) of the latter affords the cydic vinyl ether 14 (Scheme 14.8) [18]. This sequence of reactions is useful for the construction of the complex cyclic polyether frameworks of maitotoxin [19]. 

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