Cyclobutane ring enamines

Olefins conjugated with electron-withdrawing groups other than a carbonyl group undergo reactions with enamines in a manner similar to the carbonyl-conjugated electrophilic alkenes described above. Namely, they condense with an enamine to form a zwitterion intermediate from which either 1,2 cycloaddition to form a cyclobutane ring or simple alkylation can take place. 

A key step in the synthesis in Scheme 13.11 was a cycloaddition between an electron-rich ynamine and the electron-poor enone. The cyclobutane ring was then opened in a process that corresponds to retrosynthetic step 10-IIa 10-IIIa in Scheme 13.10. The crucial step for stereochemical control occurs in Step B. The stereoselectivity of this step results from preferential protonation of the enamine from the less hindered side of the bicyclic intermediate. 

The cyclobutane ring was then cleaved by hydrolysis of the enamine and ring opening of the resulting (3-diketone. The relative configuration of the chiral centers is unaffected by subsequent transformations, so the overall sequence is stereoselective. Another key step in this synthesis is Step D, which corresponds to the transformation 10-IIa => 10-la in the retrosynthesis. A protected cyanohydrin was used as a nucleophilic acyl anion equivalent in this step. The final steps of the synthesis in Scheme 13.11 employed the C(2) carbonyl group to introduce the carboxy group and the C(l)-C(2) double bond. 

The first stereocontrolled syntheses of juvabione are described in Schemes 13.11 and 13.12. Scheme 13.10 is a retrosynthetic analysis corresponding to these syntheses. These syntheses have certain similarities. Both start with cyclohexenone. There is a general similarity in the fragments that were utilized, but the order of construction differs. In the synthesis shown in Scheme 13.11, the crucial step for stereochemical control is step B. The first intermediate is constructed by a [2 + 2] cycloaddition between reagents of complementary polarity, the electron-rich enamine and the electron-poor enone. The cyclobutane ring is then opened in a process which corresponds to retrosynthetic step Ha => Ilia in... 

Enamines (e.g. 377) have been shown to react with conjugated nitroolefins 378 to give mainly dihydro-l,2-oxazine A -oxide derivatives 379 as products of kinetic control (sometimes a cyclobutane ring is formed in these reactions see Section II.B). The stability of these heterocycles is largely dependent on the parent enamine and the type of substituent used on the nitro olefin as has been extensively studied by Valentin and coworkers " . Usually they open into the corresponding nitroalkylated enamines 380 (equation 82), in particular in a solution of methanol or deuteriated chloro-and often an equilibrium between the two forms is established. Stable 1,2-oxazine A -oxides have been obtained in the reaction of 2-nitro-l,3-dienes with cyclic enamines . 

The majority of the intramolecular (2 + 2)-cycloreversions of hetero-bicyclic compounds proceed via ring opening of an annulated cyclobutene or azetine ring. Only in one instance has the same reaction of a cyclobutane ring been proposed as an intermediate step, viz., in the reaction of a thiirene 1,1-dioxide with enamines (Section II,B).33... 

The route employed to prepare indanone 51 involved the cycloaddition-hydrolysis-aldol sequence shown in Scheme 3.9. Accordingly, condensation of cyclopentenone 52 with ynamine 53 (84) afforded the bicyclic enamine 54 which was converted to indanones 51 and 55 by hydrolytic cyclobutane ring opening followed by intramolecular aldol condensation. Interestingly, treatment of 54 with aqueous formic acid yielded indanone 51 which has stereochemistry complementary to that at C(15) and C(20) in reserpine. In contrast, hydrolysis of this substance with aqueous hydrochloric acid afforded the trans-fused indanone 55. Subsequent to this work, the Ficini group found that esterification of 51 followed by photochemically induced addition of methanol afforded adduct 56 which has four of the reserpine stereocenters in place (23). While no further work on this problem has been reported, these preliminary investigations demonstrate a novel use of [2 -h 2] photocycloaddition chemistry in potential approaches to yohimbane alkaloid synthesis. 

The types of cycloadditions discovered for enamines range through a regular sequence starting with divalent addition to form a cyclopropane ring, followed by 1,2 addition (i) of an alkene or an alkyne to form a cyclo-cyclobutane or a cyclobutene, then 1,3-dipolar addition with the enamine the dipolarophile 4), and finally a Diels-Alder type of reaction (5) with the enamine the dienophile. 

Other olefinic substrates known to dimerize through photo-induced electron transfer sensitization include enamines (72), diarylethylenes (73-75), vinyl ethers (76), styrenes (77,78), and phenyl acetylenes (79). Alternate ring closures (besides cyclobutanes) are sometimes observed, probably via 1,4-radical cationic intermediates. For example, a tetrahydronaphthalene is formed from the radical cation of 1,1-diphenylethylene, eq. 

Tetracyanoethylene is unusual in that it reacts with cyclohexanone enamines to give a five-membered ring instead of a cyclobutane adduct. Reaction occurs at the y-position of the enamine and an initial one-electron transfer between the two reactants is... 

The addition of enamines to cyclopropenes in a [2 + 2] process to give a cyclobutane has been applied in a number of natural product syntheses however, in many cases, a second product was a ring-opened ketone. 

Cycloaddition of diphenylthiiren 1,1-dioxide to enamines affords breakdown products of the initially formed sulphone, arising from ring-opening and loss of sulphur dioxide. Only in the case of the enamine (214) was a cyclobutane derivative obtained. ... 

A particularly good route to four-membered rings is via a (2-i-2]-cycloaddition. With a suitably functionalized precursor, this is a good method for preparing amino-cyclobutane amino acids. Reaction of enamine 7319 (derived from isobutyraldehyde)... 

The use of diarylprolinol trimethylsilylethers proved to be very interesting in the enantio-controlled ring closure of tri-substituted cyclobutanes 105 after enamine-iminium activation of an enal 13 in the presence of vinylpyrrolidines (Scheme 5.38) [113]. These whole sequences look like [2 + 2] cycloadditions. 

An unusual ring-chain tautomerism in bicyclo[4.2.0]octane derivatives 7 has heen reported [19]. The reversible transformation of the cyclobutane derivative into a tris-substituted enamine was studied by NMR spectroscopy (Scheme 5.5). 

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