Allylic Ether Substrates

Allyl ether substrate 8e was also examined and found to undergo efficient conversion to cyclooctanone lie (Scheme 18.6). In this case there was some ambiguity as to whether the reaction occurs via a stepwise [1,2]- or concerted [2,3]-shift Examination of... 

Subsequently, the same group demonstrated an asymmetric synthesis of 3-amino aldehydes via catalytic double-bond isomerization/enantioselective aza-Petasis-Ferrier rearrangement reaction (Scheme 2.93) [128]. Similarly, the hemiaminal allyl ether substrates 346 were first isomerized by Ni(II) complexes to stereoselectively form Z-configured vinyl ethers 347, which then underwent a phosphoric acid-catalyzed... 

This chiral modifier provides one of the only methods for selective cyclopropa-nation of substrates which are not simple, allylic alcohols. In contrast to the catalytic methods which will be discussed in the following section, the dioxaborolane has been shown to be effective in the cyclopropanation of a number of allylic ethers [67]. This method has also been extended to systems where the double... 

The rearrangement of an ether 1 when treated with a strong base, e.g. an organo-lithium compound RLi, to give an alcohol 3 via the intermediate a-metallated ether 2, is called the Wittig rearrangement. The product obtained is a secondary or tertiary alcohol. R R can be alkyl, aryl and vinyl. Especially suitable substrates are ethers where the intermediate carbanion can be stabilized by one of the substituents R R e.g. benzyl or allyl ethers. 

Alternative conditions for reductive decyanations can be used. The allylic ether in compound 26, an intermediate in a total synthesis of (-)-roxaticin, was prone to reduction when treated with lithium in liquid ammonia. Addition of the substrate to an excess of lithium di-ferf-butylbiphenylide in THF at -78°C, and protonation of the alkyllithium intermediate provided the reduced product 27 in 63% yield, as a single diastereomer (Eq. 7). a-Alkoxylithium intermediates generated in this manner are configurationally stable at low temperature, and can serve as versatile synthons for carbon-carbon bond forming processes (see Sect. 4). 

Michael addition to give the azaheterocycles 7-39 through a favorable 6-exo-trig ring closure (Scheme 7.13). Even highly sensible substrates such as aryl-allyl ethers and amines could be transformed to the desired products in excellent yields. 

Allyl acetals154). Allyl ethers give no or only trace amounts of ylide-derived products in the Rh2(OAc)4-catalyzed reaction with ethyl diazoacetate, thus paralleling the reactivity of allyl chloride. In contrast, cyclopropanation must give way to the ylide route when allyl acetals are the substrates and ethyl diazoacetate or dimethyl diazomalonate the carbenoid precursors. 

Trost et al 1 have observed product distribution to be dependent in part on the steric and electronic properties of the substrate. For example, linear enyne 48 (Equation (30)) cyclized exclusively to the Alder-ene product 49, whereas branching at the allylic position led to the formation of 1,3-diene 50 (Equation (31)) under similar conditions. Allylic ethers also give 1,3-dienes this effect was determined not to be the result of chelation, as methyl ethers and tert-butyldimethylsilyl ethers both gave dialkylidene cyclopentanes despite the large difference in coordinating ability. 

Alternatively, as shown in Scheme 8, we envisioned that styrenyl allylic ethers, in the presence of an appropriate catalyst, might undergo a net skeletal rearrangement to yield the desired isomeric heterocyclic products [14]. Rearrangement substrates would be synthesized in the non-racemic form by the Zr-catalyzed kinetic resolution [5c]. 

Zr-catalyzed enantio-selective intramolecular diene cyclizations with allylic alcohol and ether substrates afford carbocycles bearing quaternary carbon stereogenic centers the unexpected formation of the aldehyde product 19 is noteworthy. 

Related catalytic enantioselective processes It is worthy of note that the powerful Ti-catalyzed asymmetric epoxidation procedure of Sharpless [27] is often used in the preparation of optically pure acyclic allylic alcohols through the catalytic kinetic resolution of easily accessible racemic mixtures [28]. When the catalytic epoxidation is applied to cyclic allylic substrates, reaction rates are retarded and lower levels of enantioselectivity are observed. Ru-catalyzed asymmetric hydrogenation has been employed by Noyori to effect the resolution of five- and six-membered allylic carbinols [29] in this instance, as with the Ti-catalyzed procedure, the presence of an unprotected hydroxyl function is required. Perhaps the most efficient general procedure for the enantioselective synthesis of this class of cyclic allylic ethers is that recently developed by Trost and co-workers, involving Pd-catalyzed asymmetric additions of alkoxides to allylic esters [30]. 

Tab. 10.7 summarizes the results of the application of rhodium-catalyzed allylic etherification to a series of ortho-substituted phenols. The etherification tolerates alkyls, including branched alkanes (entries 1 and 2), aryl substituents (entry 3), heteroatoms (entries 4 and 5), and halogens (entry 6). These results prompted the examination of ortho-disubstituted phenols, which were expected to be more challenging substrates for this type of reaction. Remarkably, the ortho-disubstituted phenols furnished the secondary aryl allyl ethers with similar selectivity (entries 7-12). The ability to employ halogen-bearing ortho-disubstituted phenols should facilitate substitutions that would have proven extremely challenging with conventional cross-coupling protocols. 

A series of pyrido[2,3-rf pyrimidine-2,4-diones bearing substituents at C-5 and/or C-6 were synthesized using palladium-catalyzed coupling of uracil derivative 417 with vinyl substrates or allyl ethers to give the regioisomeric mixtures of 418/419 and 420/421, respectively. The ratio of the isomeric structures was dependent on the substituent R. In the case of the reaction with -butyl vinyl ether, only the product 419 was obtained. However, the reactions with acrylonitrile, ethyl acrylate, 2-trifluoromethylstyrene, and 3-nitrostyrene afforded only 418. Also, reaction with allyl phenyl ether gave only 420. The key intermediate 417 was prepared by the reaction of 6-amino-l-methyluracil with DMF-DMA (DMA = dimethylacetamide), followed by N-benzylation with benzyl chloride and vinyl iodination with iV-iodosuccinimide (NIS) (Scheme 15) <2001BML611>. 

The slow carbozincation, attributed to the presence of TMEDA, was more problematic when substrate-induced diastereoselection was also involved. Thus, addition of zincated allyl ethyl ether to the alkenyllithium derived from the secondary y-iodo allylic ether 209 afforded a 65/35 mixture of the diastereomers 228 and 229 in low yield after hydrolysis. The erosion of diastereoselectivity was not a consequence of a less efficient substrate-induced diastereoselection but rather of the fact that both the (E) and (Z) isomers of the zincated allyl ethyl ether had reacted. Although the use of a catalytic amount of TMEDA (10 mol%) in the metallation step substantially improved the yield, the diastereoselectivity remained low (equation 111)151. 

A number of organoselenium reagents have been used as efficient initiators of ring closure, leading from unsaturated substrates to the lactones and cyclic ethers (81T4097). The reaction is termed phenylselenoetherification. The phenyl selenoethers obtained are subject to a selection of transformations, e.g. their conversion to allylic ethers (Scheme 50) and their... 

The kinetic optical resolution [32] of a racemic substrate might be considered as an intermo-lecular version of desymmetrization. In principle, the kinetic resolution of a racemic allylic ether... 

Solutions of these metals in liquid ammonia effect (i) the reduction of a range of functional groups such as carbonyl and acetylenic and also conjugated and aromatic systems, and (ii) cleavage of benzyl and allyl ethers and thioethers. These reactions are usually carried out by the general procedure of adding the metal to a solution of the substrate in liquid ammonia to which dry methanol or ethanol or t-butanol has been added to provide a ready proton source (alcohols are more acidic than ammonia).34... 

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