Allyl ethers, chiral

The cyclic 2,4-dienoate 184, formed by the Pd-catalyzed cyclization of the 1,6-enyne 183, reacted with 154 to form the azulene derivative 185[118], The 3-methylenepyrrolidine 188 is formed by the reaction of the Zn reagent 186 with the chiral imine 187 with high diastereomeric excess. The structure of the allylic ethers is important for obtaining high diastereoselectivity[l 19],... 

An interesting feature of the synthesis is the use of allyl as a two-carbon extension unit. This has been used in the stereospecific synthesis of dicyclohexano-18-crown-6 (see Eq. 3.13) and by Cram for formation of an aldehyde unit (see Eq. 3.55). In the present case, mannitol bis-acetonide was converted into its allyl ether which was ozonized (reductive workup) to afford the bis-ethyleneoxy derivative. The latter two groups were tosylated and the derivative was allowed to react with its precursor to afford the chiral crown. The entire process is shown below in Eq. (3.59). 

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 scope of this methodology was extended to the enantioselective rearrangement of difluorovinyl allyl ethers by these authors, furnishing a novel powerful tool for the synthesis of chiral p-substituted a,a -difluorocarbonyl compounds. As shown in Scheme 10.36, moderate to good enantioselectivities... 

Kibayashi and coworkers have used enantiometrically pure allylic silyl ethers obtained from amino acids in cycloaddition with nitrones (Eq. 8.49).71 Cyclic nitrone reacts with a chiral allyl ether to give selectively the exo and erythro isomer (de 90%). Optically active alkaloids containing a piperidine ring such as (+)-monomorine,71c (+)-coniine,71a and (-)-oncinotine71b have been prepared from the addition product. 

The synthetic versatility and significance of the Zr-catalyzed kinetic resolution of exocyc-lic allylic ethers is demonstrated by the example provided in Scheme 6.9. The optically pure starting allylic ether, obtained by the aforementioned catalytic kinetic resolution, undergoes a facile Ru-catalyzed rearrangement to afford the desired chromene in >99% ee [20], Unlike the unsaturated pyrans discussed above, chiral 2-substituted chromenes are not readily resolved by the Zr-catalyzed protocol. Optically pure styrenyl ethers, such as that shown in Scheme 6.9, are obtained by means of the Zr-catalyzed kinetic resolution, allowing for the efficient and enantioselective preparation of these important chromene heterocycles by a sequential catalytic protocol. 

Enantioselective [2 + 2 cycloaddition.2 The chiral allylic ether (1), prepared from (lS,2R)-( + )-2-phenylcyclohexanol, undergoes enantioselective cycloaddition with dichloroketene to furnish, after one crystallization, optically pure (-)-2. This cyclobutanone after ring expansion and exposure to chromium(II) perchlorate gives... 

An irreversible consecutive reaction as a driving force to shift an unfavorable Cope rearrangement equilibria in the needed direction can be illustrated by the Cope-Claisen tandem process used for the synthesis of chiral natural compounds243. It was found that thermolysis of fraws-isomeric allyl ethers 484 or 485 at 255 °C leads to an equilibrium mixture of the two isomers in a 55 45 ratio without conversion into any other products (equation 184). Under the same conditions the isomer 487 rearranges to give the Cope-Claisen aldehyde 491 (equation 185). Presumably, the interconversion 484 485 proceeds via intermediate 486 whose structure is not favorable for Claisen rearrangement. In contrast, one of the two cyclodiene intermediates of process 487 488 (viz. 490 rather than 489) has a conformation appropriate for irreversible Claisen rearrangement243. 

We thus turned to alternative strategies for synthesizing aldehyde 3. Particularly attractive was the proposal that sugar-like materials could be constructed via the reaction of an allyl ether anion and an a-alkoxyaldehyde (Figure 5).10,11 For this approach to be successful, it would be necessary to control (i) the regioseiectivity of the reaction of the allyl ether anion, 0 (jj) the syn (threo) or anti (erythro) relationship generated in concert with the new C-C bond, and (iii) this new C(2)-C(3) relationship with respect to the chiral center (C(4)) already present in the aldehyde reaction partner. 

The oxygen atom has also been used to generate other functionalities, such as the aldehyde moiety in Kibayashi s syntheses of (—)-coniine (197) and its enantiomer (Scheme 1.43) (253). Here, reaction of tetrahydropyridine N-oxide 93 with a silylated chiral allyl ether dipolarophile 198 delivered the adduct 199 with the desired bridgehead stereochemistry via the inside alkoxy effect . Desilylation and hydrogenolytic N—O bond rupture with palladium(II) chloride provided the diol 200... 

The different reactivity of the two n faces observed with chiral allyl ethers has been rationalized in terms of the earlier model, with the large group positioned anti inside alkoxy model) (see Section 6.2.3.1). Increased hindrance by the 0-substituent s size and restricted approach/conformational mobility may account for the increasing difference of reactivity between the two faces for cases 2, 3, and 4 (see Section 6.2.3.1). With the allylic alcohol (easel), the reversed facial preference... 

Intramolecular Alkylation of Remote Double Bonds with Chiral Allylic Ethers... 

The model involving the minimization of the A-1,3 ally lie strain followed by an alkoxy-directed cyclopropanation is quite reliable to predict the sense of induction in the cyclopropanation of chiral acyclic allylic alcohols. However, the application of this model is not as straightforward in the case of allylic ethers. Indeed, it was shown that the cyclopropanation of benzyl ethers led to a major anti or syn isomer depending upon the nature of the substituents (equation 67). ... 

Stereospecific Wittig rearrangement.1 Wittig rearrangement of the optically active (Z)-allylic ether 1 (9, 475 for a related reaction) gives (R,E)-2 with complete chirality transfer. Rearrangement of (E)-l results in two products, again with complete chirality transfer.1... 

A variation on this asymmetric catalytic allylation scheme employed (3-diketones or (3-keto ester nucleophiles with allyl ethers and a palladium-DIOP catalyst.434 The chiral center generated is now one carbon removed from the allyl ligand. As a result, somewhat lower optical yields were observed (-10% equation 353). A variety of chiral phosphines were evaluated in the cyclization of (3-keto esters. Optical yields up to 48% were measured in these reactions435... 

The catalytic kinetic resolution of various dienes through ARCM can be carried out in an efficient manner at 22 °C in the presence of 5 mol %4a [10]. As the data in Scheme 1 illustrate, 1,6-dienes 5-7 are resolved with excellent levels of enan-tiocontrol (krei>20) [11]. Chiral complex 4a readily promotes the resolution of allylic ethers 8-10 as well [12]. 

The use of Lewis acids in controlling the stereoselective outcome of radical cyclization reactions has been explored, in particular the effect of aluminium-based Lewis acids using low temperature Et3B/Bu3SnH-initiated procedures.171,172 For example, cyclization of propargyl ether (78) or allyl ether (79) in the presence of Lewis acid (80) can completely reverse the normal selectivity (Scheme 34).171 The effect of aluminium Lewis acids on the diastereoselectivity of 6-exo cyclization of unsaturated chiral menthol esters has been studied.172 Cyclization at low temperature in the presence of the Lewis acid MAD modified the de of the reaction from 31 to 98%. 

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