Allyl ethers enol ether preparation

Ketals are converted to allyl vinyl ethers after Wittig olefination [14]. Wittig reactions permit the incorporation of various substituents into the allyhc terminal of the ether. Enol ethers have been conveniently prepared by cleavage of acetals with various Lewis acids. Cleavage of the ketals with the Lewis acid, for example, triethylsilyl triflate, in the presence of diisopropylethylamine in refluxing 1,2-di-chloroethane afforded the enol ethers (Eq. 3.1.9). The resulting enol ethers were then heated to effect the Claisen rearrangement without isolation. 

Begue JP, Bonnet-Delpon D, Wu SW, M Bida A, Shintani T, Nakai T. Claisen rearrangement of a-(E -aIkyl)enol ethers prepared via Wittig olefination of allyl perfluorolkanoates. Tetrahedron Lett. 1994 35 2907-2910. 

Another preparative method for the enone 554 is the reaction of the enol acetate 553 with allyl methyl carbonate using a bimetallic catalyst of Pd and Tin methoxide[354,358]. The enone formation is competitive with the allylation reaction (see Section 2.4.1). MeCN as a solvent and a low Pd to ligand ratio favor enone formation. Two regioisomeric steroidal dienones, 558 and 559, are prepared regioselectively from the respective dienol acetates 556 and 557 formed from the steroidal a, /3-unsaturated ketone 555. Enone formation from both silyl enol ethers and enol acetates proceeds via 7r-allylpalladium enolates as common intermediates. 

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]. 

Some representative Claisen rearrangements are shown in Scheme 6.14. Entry 1 illustrates the application of the Claisen rearrangement in the introduction of a substituent at the junction of two six-membered rings. Introduction of a substituent at this type of position is frequently necessary in the synthesis of steroids and terpenes. In Entry 2, formation and rearrangement of a 2-propenyl ether leads to formation of a methyl ketone. Entry 3 illustrates the use of 3-methoxyisoprene to form the allylic ether. The rearrangement of this type of ether leads to introduction of isoprene structural units into the reaction product. Entry 4 involves an allylic ether prepared by O-alkylation of a (3-keto enolate. Entry 5 was used in the course of synthesis of a diterpene lactone. Entry 6 is a case in which PdCl2 catalyzes both the formation and rearrangement of the reactant. 

Titanium tetrachloride-catalysed Michael additions of trimethylsilyl enol ethers to artemisitene afforded a neat route to 14-substituted artemisinin derivatives of type 125 (eg. R = allyl) and to 9-epiartemisinin derivatives 126 some of these compounds were more active against Plasmodium falciparum than artemisinin <00BMCL1601>. A series of 11-azaartemisinins also have better activity than artemisinin <00BMC1111>. On the other hand, epiartemisinin, prepared by base-catalysed epimerisation of artemisinin, has been shown to have poor antimalarial activity <00HCA1239>. 

The stereoselective isomerization of allyl silyl ethers to (E)- or (Z)-silyl enol ethers was carried out in the presence of a cationic iridium(i) catalyst. The complex, prepared in situ by treating [Ir(cod)2]PFf,/2PPi3 with hydrogen was... 

Dehydrobromination of bromotrifluoropropene affords the more expensive trifluoropropyne [237], which was metallated in situ and trapped with an aldehyde in the TIT group s [238]synthesis of 2,6-dideoxy-6,6,6-trifluorosugars (Eq. 77). Allylic alcohols derived from adducts of this type have been transformed into trifluoromethyl lactones via [3,3] -Claisen rearrangements and subsequent iodolactonisation [239]. Relatively weak bases such as hydroxide anion can be used to perform the dehydrobromination and when the alkyne is generated in the presence of nucleophilic species, addition usually follows. Trifluoromethyl enol ethers were prepared (stereoselectively) in this way (Eq. 78) the key intermediate is presumably a transient vinyl carbanion which protonates before defluorination can occur [240]. Palladium(II)-catalysed alkenylation or aryla-tion then proceeds [241]. 

Transsilylation. Several reagents have been recommended for preparation of /-butyldimethylsilyl ethers by transsilylation. These include allyl-r-butyldimethyl-silane and /-butyldimethylsilyl enol ethers of pentane-2,4-dione and methyl aceto-ucelate,2 both prepared with r-butyldimethylchlorosilane and imidazole. Unlike the reaction of r-butyldimethylchlorosilane with alcohols, which requires a base catalyst, these new reagents convert alcohols to silyl ethers under slightly acidic conditions (TsOH) in good yield. The trimethylsilyl ethers of pentane-2,4-dione and methyl acetoacetate convert alcohols to trimethylsilyl ethers at room temperature even with no catalyst. The former reagent is also useful for silylation of nucleotides.3... 

Sulfonamides can also be alkylated by support-bound electrophiles (Table 8.10). Polystyrene-bound allylic alcohols have been used to N-alkylate sulfonamides under the conditions of the Mitsunobu reaction. Oxidative iodosulfonylamidation of support-bound enol ethers (e.g. glycals Entry 3, Table 8.10) has been used to prepare /V-sulfonyl aminals. Jung and co-workers have reported an interesting variant of the Baylis-Hillman reaction, in which tosylamide and an aromatic aldehyde were condensed with polystyrene-bound acrylic acid to yield 2-(sulfonamidomethyl)acrylates (Entry 4, Table 8.10). 

Allylic strain is employed in the Patemo-Biichi reaction of a silyl enol ether and benzaldehyde.79 Using a bulky or polar substituent y to the ether as stereogenic locus, diastereomerically pure oxetanes with four contiguous chiral centres have been prepared. 

Allyl cyanides can be added across alkynes in the presence of a nickel catalyst prepared from (COD)2Ni and (4-CF3CeH4)3P in situ to give functionalized di- or tri-substituted acrylonitriles in a highly stereoselective manner, presumably via n-allylnickel intermediates. a-Siloxyallyl cyanides also react at the y -position of a cyano group with both internal and terminal alkynes to give silyl enol ethers, which can be converted into the corresponding aldehydes or ketones upon hydrolysis.70... 

When this type of reaction was applied to the preparation of the ester 2, phosphorus trichloride was used as the phosphorus (III) halide. Treatment of this with one mole equivalent of 3,3-dimethoxyprop-l-ene yields mainly the enol ether 4, with smaller amounts of the isomeric a-chloroallyl methyl ether 5. This mixture is not very stable and has to be treated with trimethyl phosphite rapidly, in order to provide 2 in good yield, as shown in Scheme 1. The significance of this sequence is that it reveals that since 2 is the only product, the reactions leading to 2 via 4 must proceed by two allylic inversions, whilst those via 5 involve direct substitution twice at the original acetal carbon. 

Not only an aryl group—as in Figure 14.46—but also an alkenyl group can participate in the Claisen rearrangement of allyl ethers (Figure 14.47). Allyl enol ethers are the substrates in this case. Figure 14.47 shows how this kind of allyl alkenyl ether (D) can be prepared from an... 

The preparation involves an oxymercuration (Section 3.5.3) of the C=C double bond of the ethyl vinyl ether. The Hg(OAc) ion is the electrophile as expected, but it forms an open-chain cation A as an intermediate rather than a cyclic mercurinium ion. The open-chain cation A is more stable than the mercurinium ion because it can be stabilized by way of oxocarbe-nium ion resonance. Next, cation A reacts with the allyl alcohol, and a protonated mixed acetal B is formed. Compound B eliminates EtOH and Hg(OAc) in an El process, and the desired enol ether D results. The enol ether D is in equilibrium with the substrate alcohol and ethyl vinyl ether. The equilibrium constant is about 1. However, the use of a large excess of the ethyl vinyl ether shifts the equilibrium to the side of the enol ether D so that the latter can be isolated in high yield. 

Fig. 11.42. Preparation of an allyl enol ether, D, from allyl alcohol and a large excess of ethyl vinyl ether. Subsequent Claisen rearrangement D —> C proceeding with chirality transfer.

Allyl silanes react with a wide variety of electrophiles, rather like the ones that react with silyl enol ethers, provided they are activated, usually by a Lewis acid. Titanium tetrachloride is widely used but other successful Lewis acids include boron trifluoride, aluminium chloride, and trim ethyls ilyl tri-flate. Electrophiles include the humble proton generated from acetic add. The regiocontrol is complete. No reaction is observed at the other end of the allylic system. All our examples are on the allyl silane we prepared earlier in the chapter. 

Other known methods for preparing O-alkyl enol ethers include, most notably, alcohol elimination from acetals, double bond isomeri2ation in allylic ethers, reduction of alkoxy enol phosphates, and phosphorane-based condensation approaches.5 These methods, however, suffer from poor stereoselectivity, low yields, or lack of generality, if not a combination of these drawbacks. 

Dioxene can be used to prepare trisubstituted annulated furans in a three-step sequence. By lithiation of 1,4-dioxene, followed by carbonyl addition, an allylic alcohol 13 is obtained, which can be reacted with silyl enol ethers in the presence of a Lewis acid to furnish disubstituted dioxanes of type 14. These compounds rearrange to furans under mild conditions upon treatment with camphorsulfonic acid (Scheme 16) <1999TL2521>. 

Lithium naphthalenide (prepared from lithium and 1.33 equivalents of naphthalene) also reductively cleaves benzyl ethers [Scheme 4.143],262 Some functionalities survive the reaction conditions like carbon-carbon double bonds, benzene rings, THP ethers, stlyl ethers and methoxymethyl ethers. A ketone group can be present but its prior conversion to an enolate is necessary. A similar transformation, but with a catalytic amount of naphthalene, has been reported.263 Although allyl ethers are also cleaved by the procedure, the selective deprotec-... 

Allylic azides, e.g., 1, were produced by treatment of the triisopropylsilyl enol ethers of cyclic ketones with azidotrimethylsilane and iodosobenzene78, but by lowering the temperature and in the presence of the stable radical 2,2,6,6-tetramethylpiperidine-/V-oxyl (TEMPO), 1-triso-propylsilyloxy-l,2-diazides, e.g., 2, became the predominant product79. The radical mechanism of the reaction was demonstrated. A number of 1,2-diazides (Table 4) were produced in the determined optimum conditions (Method B 16h). The simple diastereoselectivity (trans addition) was complete only with the enol ethers of unsubstituted cycloalkanones or 4-tert-butylcy-clohexanone. This 1,2-bis-azidonation procedure has not been exploited to prepare a-azide ketones, which should be available by simple hydrolysis of the adducts. Instead, the cis-l-triiso-propylsilyloxy-1,2-diazides were applied to the preparation of cw-2-azido tertiary cyclohexanols by selective substitution of the C-l azide group by nucleophiles in the presence of Lewis acids. 

The Claisen rearrangement of allyl vinyl ethers 480 is a fairly general method for the preparation of y, -unsaturated carbonyl compounds of the general formula 481 from simple precursors (Scheme 2.154). ° Synthetically, this transformation is equivalent to the well-known a-allylation of enolates, which gives ultimately the same product. However, the mechanisms and conditions of these two reactions differ and their synthetic potentials are complementary to each other. 

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