Homoallyl derivatives

The cyclobutyl to homoallyl rearrangement was studied above all for mechanistic reasons, especially to differentiate between different kinds of cationic intermediates.7 In general, mixtures of cyclopropylmethyl, cyclobutyl, and homoallyl derivatives are formed, depending on the type of substitution in the substrate and stability of the precursor ions. 

Vinyl, allyl and homoallyl derivatives of germanium and tin also form the corresponding cyclopropanes with dichlorocarbene generated by the chloroform/potassium /er/-butoxide or bromodichloromethyl(phenyl)mercury methods (Table 23). ... 

The solvolyses of cyclopropylcarbinyl and cyclobutyl derivatives often give exactly the same products, in close to the same ratios, as observed by Roberts in 1951. The reaction of certain homoallyl derivatives will also give these products, but homoallyl structures are also very susceptible to Sn2 reactions and will therefore sometimes deviate in the product ratios. A comparison where all three derivatives give the same products in similar ratios is shown in Eq. 11.42. The data indicate that there is likely a common intermediate in all three of these reactions. 

Furthermore, radiolabeling studies have revealed that the solvolysis of cyclopropylcarbinyl diazonium (the first reactant given in Eq. 11.42) results in partial scrambling of the carbon attached to the diazonium group into all of the carbons of all three products. Hence, there must be an intermediate where several of the carbons become equivalent. Another facet to this puzzle is that cyclopropylcarbinyl, cyclobutyl, and homoallyl derivatives all undergo solvolysis faster than analogous structures. For example, cyclopropylcarbinyl to-sylate undergoes solvolysis approximately 10 times faster than isobutyl tosylate. 

It is relevant to discuss briefly at this point the stereochemistry and mechanism of the cyclopropylcarbinyl-cyclobutyl-homoallyl rearrangements. Solvolysis of cyclopropylcarbinyl, cyclobutyl, and homoallyl derivatives bearing stereospecific labels or substituents lead to rearranged products in which the stereochemical relationships in the starting material are retained (74—76). The stereochemistry is illustrated below with the hydrolysis of specifically deuterated cyclopropylcarbinyl methanesulfonate... 

These are usually obtained from the isomeric conjugated ketone, and are sometimes useful as intermediates, offering an alternative to enol derivatives. They may also be formed as a result of double bond introduction or by oxidation of homoallylic alcohols if so the conditions must be mild because they generally represent a less stable isomer. 

All the rearranged products derived from (12) and (15) have been rationalized as arising by proton loss or reaction with fluoride ion of the respective homoallylic C-19 cations. The structures of the cations derived from (15) are represented by structures (20) to (24)." ... 

An elegant application of the Vilsmeier reaction is the synthesis of substituted biphenyls as reported by Rao and RaoJ Starting with homoallylic alcohol 8, the biphenyl derivative 9 was obtained from a one-pot reaction in 80% yield ... 

Two approaches for the synthesis of allyl(alkyl)- and allyl(aryl)tin halides are thermolysis of halo(alkyl)tin ethers derived from tertiary homoallylic alcohols, and transmetalation of other allylstannanes. For example, dibutyl(-2-propenyl)tin chloride has been prepared by healing dibutyl(di-2-propenyl)stannane with dibutyltin dichloride42, and by thermolysis of mixtures of 2,3-dimethyl-5-hexen-3-ol or 2-methyl-4-penten-2-ol and tetrabutyl-l,3-dichlorodistannox-ane39. Alternatively dibutyltin dichloride and (dibutyl)(dimethoxy)tin were mixed to provide (dibutyl)(methoxy)tin chloride which was heated with 2,2,3-trimethyl-5-hexen-3-ol40. 

It is also difficult to determine exactly the relative stabilities of vinyl cations and the analogous saturated carbonium ions. The relative rates of solvolysis of vinyl substrates and their analogous saturated derivatives have been estimated to be 10 to 10 (131, 134, 140, 154) in favor of the saturated substrates. These rate differences, however, do not accurately reflect the inherent differences in stability between vinyl cations and the analogous carbonium ions, for they include effects that result from the differences in ground states between reactants, as well as possible differences between the intermediate ions resulting from differences in solvation, counter-ion effects, etc. The same difficulties apply in the attempt to estimate relative ion stabilities from relative rates of electrophilic additions to acetylenes and olefins, (218), or from relative rates of homopropargylic and homoallylic solvolysis. 

A further improvement on the tetrahydropyranol formation was made by using the Amberlite IR-120 Plus resin—an acidic resin with a sulfonic acid moiety, in which a mixture of an aldehyde and homoallyl alcohol in water, in the presence of the resin and under sonication, yielded the desired tetrahydropyranol derivatives.111... 

A new chiral auxiliary based on a camphor-derived 8-lactol has been developed for the stereoselective alkylation of glycine enolate in order to give enantiomerically pure a-amino acid derivatives. As a key step for the synthesis of this useful auxiliary has served the rc-selective hydroformylation of a homoallylic alcohol employing the rhodium(I)/XANTPHOS catalyst (Scheme 11) [56]. 

Table 5 summarizes the reactions of isoprene with aromatic aldehydes and unsaturated aldehydes. Salicylaldehyde provides the expected product as a cyclic boric ester derivative and shows apparently lower stereoselectivity, giving a mixture of 1,3-anti and 1,3-syn isomers in a ratio of 6 1 (run 1, Table 5). 2-Furfural reacts as usual and provides a 1,3-anti isomer as a single diastereomer in good yield (run 2). Unsaturated aldehydes, irrespective of their substitution patterns, undergo homoallylation selectively with excellent 1,3-anti selectivity, the geometry of the double bond of the starting aldehydes remaining intact (runs 3-5). 1,2-Addition to unsaturated aldehyde takes place selectively and no 1,4-addition is observed.

Recently, a new multicomponent condensation strategy for the stereocontrolled synthesis of polysubstituted tetrahydropyran derivatives was re-published by the Marko group, employing an ene reaction combined with an intramolecular Sakurai cyclization (IMSC) (Scheme 1.14) [14]. The initial step is an Et2AlCl-promoted ene reaction between allylsilane 1-50 and an aldehyde to afford the (Z)-homoallylic alcohol 1-51, with good control of the geometry of the double bond. Subsequent Lewis acid-media ted condensation of 1-51 with another equivalent of an aldehyde provided the polysubstituted exo-methylene tetrahydropyran 1-53 stereoselectively and... 

Iridium-catalyzed transfer hydrogenation of aldehyde 73 in the presence of 1,1-dimethylallene promotes tert-prenylation [64] to form the secondary neopentyl alcohol 74. In this process, isopropanol serves as the hydrogen donor, and the isolated iridium complex prepared from [Ir(cod)Cl]2, allyl acetate, m-nitrobenzoic acid, and (S)-SEGPHOS is used as catalyst. Complete levels of catalyst-directed diastereoselectivity are observed. Exposure of neopentyl alcohol 74 to acetic anhydride followed by ozonolysis provides p-acetoxy aldehyde 75. Reductive coupling of aldehyde 75 with allyl acetate under transfer hydrogenation conditions results in the formation of homoallylic alcohol 76. As the stereochemistry of this addition is irrelevant, an achiral iridium complex derived from [Ir(cod)Cl]2, allyl acetate, m-nitrobenzoic acid, and BIPHEP was employed as catalyst (Scheme 5.9). 

The grem-dibromocyclopropanes 152 bearing a hydroxyalkyl group, prepared by the addition of dibromocarbene to allylic or homoallylic alcohols, undergo an intramolecular reductive carbonylation to the bicyclic lactones 153. bicyclic lactone derived from prenyl alcohol is an important precursor for the synthesis of ris-chrysanthemic acid. (Scheme 54)... 

The application of RCM to dihydropyran synthesis includes a route to 2,2-disubstituted derivatives from a-hydroxycarboxylic acids. In a one-pot reaction, the hydroxy esters undergo sequential O-allylation, a Wittig rearrangement and a second O-allylation to form allyl homoallyl ethers 8. A single RCM then yields the 3,6-dihydro-2//-pyran 9. The process is readily adapted not only to variably substituted dihydropyrans but also to 2-dihydrofuranyl and 2-tetrahydrooxepinyl derivatives and to spirocycles e.g. 10 through a double RCM (Scheme 4) <00JCS(P1)2916>. 

Fluorinated dihydropyrans 16 are readily derived from aldehydes via the homoallyl alcohols 15. A second allylation is a prelude to a RCM (Scheme 7) <00CC607>. 

The conversion of anomerically linked enol ethers 29 into either the cis- or trans-substituted pyranyl ketones with high diastereoselectivity and yield involves a Lewis acid-promoted O —> C rearrangement (Scheme 19) <00JCS(P1)2385>. Under similar conditions, homoallylic ethers 30 ring open and the oxonium ions then recyclise to new pyran derivatives 31. Whilst the product is a mixture of alkene isomers, catalytic hydrogenation occurs with excellent diastereoselectivity (Scheme 20) <00JCS(P1)1829>. 

Based on Watanabe s intermolecular hydroacylation of olefins with aldehydes,348 Kondo and Misudo developed the first ruthenium-catalyzed hydroacylation of 1,3-dienes with aldehydes (Scheme 71). Usually, palladium-mediated hydroacylations of 1,3-dienes with aldehydes give tetrahydropyran and/or open-chain homoallylic alcohol derivatives.350 However, in the present ruthenium-catalyzed transformations, the corresponding /3,7-unsaturated... 

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