Electrophilic cyclopropanes rearrangements

The reaction of electrophilic allyl halides with active methylene functions give a completely different course although intermediate electrophilic cyclopropanes (327) play a crucial role. Ring-opening of the cyclopropanes affords compounds 328 in which the electron-withdrawing groups are rearranged to the allylic position (equation 102) . This... 

Photochemical procedures for the preparation of electrophilic cyclopropanes are relatively important. Appropriately substituted electron-deficient olefins on photolysis undergo a di-7r-methane rearrangement to give the corresponding cyclopropane derivatives. For example, l,l-dicyano-2-methyl-3-arylpropenes (455) provide the dicyanocyclo-propanes (456), presumably via the mechanism of equation 154 . ... 

Electrophilic dienes 457 and 459 can also be converted into electrophilic cyclopropanes 458 and 460 via a di-Ti-methane rearrangement as illustrated by the examples of equation 155 . The rearrangement of the dienes follows a typical di-7c-methane... 

Photochemical rearrangement of dihydrofuran compounds 462 and 463 gives rise to the corresponding electrophilic cyclopropanes 414 and 464 . 1,1,2,2-Tetraacylcyclopropanes (466) have been prepared from the adducts of j5-diketones and aldehydes (465) (equation 157) ... 

A limited number of rearrangements of electrophilic cyclopropanes are known in the literature, but synthetic applications have not been encountered except for the vinylcyclo-propane (528)- yclopentene rearrangement . This phenomenon is due to the rather... 

In most cases, treatment of allylic halides containing one ASG with a nucleophile does not result in formation of electrophilic cyclopropanes (MIRC product) instead, other reaction pathways are followed, e.g. addition, substitution, rearrangement and elimination reactions.However, with certain alkenes or nucleophiles or under the appropriate conditions a conjugate addition-nucleophilic substitution pathway is favored, resulting in cyclopropanes substituted with one ASG. Representative examples are compiled in Tables 20 and 21 where organometallic compounds or active methylene compounds are used as the nucleophilic species in combination with allyl bromides containing an ester or a sulfone as ASG. 

Products of a so-called vinylogous Wolff rearrangement (see Sect. 9) rather than products of intramolecular cyclopropanation are generally obtained from P,y-unsaturated diazoketones I93), the formation of tricyclo[2,1.0.02 5]pentan-3-ones from 2-diazo-l-(cyclopropene-3-yl)-l-ethanones being a notable exception (see Table 10 and reference 12)). The use of Cu(OTf), does not change this situation for diazoketone 185 in the presence of an alcoholl93). With Cu(OTf)2 in nitromethane, on the other hand, A3-hydrinden-2-one 186 is formed 160). As 186 also results from the BF3 Et20-catalyzed reaction in similar yield, proton catalysis in the Cu(OTf)2-catalyzed reaction cannot be excluded, but electrophilic attack of the metal carbene on the double bond (Scheme 26) is also possible. That Rh2(OAc)4 is less efficient for the production of 186, would support the latter explanation, as the rhodium carbenes rank as less electrophilic than copper carbenes. 

C-H Insertions into vinylic C-H bonds are also a common reaction of electrophilic carbene complexes. Insertions into aromatic or heteroaromatic C-H bonds can proceed via cyclopropanation and rearrangement (Figure 4.6). 

Alkynes can be converted into cyclopropenes by inter- [587,1022,1052,1060-1062] or intramolecular [1070] cyclopropanation with electrophilic carbene complexes, Because of the high reactivity of cyclopropenes, however, in some of these reactions unexpected products can result from rearrangement or other transformations of the cyclopropenes initially formed (cf. Section 4,1,3),... 

The reaction of heteroatom-substituted alkenes with electrophilic carbene complexes can lead to the formation of highly reactive, donor-acceptor-substituted cyclopropanes. This type of cyclopropane usually undergoes ring fission and rearrangement reactions under milder conditions than do unsubstituted cyclopropanes (Figure 4.22). 

In qualitative terms, the rearrangement reaction is considerably more efficient for the oxime acetate 107b than for the oxime ether 107a. As a result, the photochemical reactivity of the oxime acetates 109 and 110 was probed. Irradiation of 109 for 3 hr, under the same conditions used for 107, affords the cyclopropane 111 (25%) as a 1 2 mixture of Z.E isomers. Likewise, DCA-sensitized irradiation of 110 for 1 hr yields the cyclopropane derivative 112 (16%) and the dihydroisoxazole 113 (18%). It is unclear at this point how 113 arises in the SET-sensitized reaction of 110. However, this cyclization process is similar to that observed in our studies of the DCA-sensitized reaction of the 7,8-unsaturated oximes 114, which affords the 5,6-dihydro-4//-l,2-oxazines 115 [68]. A possible mechanism to justify the formation of 113 could involve intramolecular electrophilic addition to the alkene unit in 116 of the oxygen from the oxime localized radical-cation, followed by transfer of an acyl cation to any of the radical-anions present in the reaction medium. 

This dominance of sulfur in the reactions with electrophiles is well brought out in the addition of carbenes to the-two monocycles. Tire allylic sulfide (5,6-dihydro-2jF/- thiopyran) only affords the products of reaction at sulfur, while the vinylic sulfide (3,4-dihydro-2f/-thiopyran), in which the alkene is a little more nucleophilic due to the small interaction with the heteroatom, shows dichotomous behaviour. Dichlorocarbene affords the cyclopropane product (78) in 70% yield, but the stabilized ylide (76) is produced from bismethoxycar-bonylmethylide and (75). In fact it is possible that the initial reaction with dichlorocarbene is reaction at sulfur and subsequent rearrangement of this less stabilized ylide. Schemes 6 and 7 illustrate the results and proposed mechanisms (77JOC3365,64JOC2211). 

One major advantage of the alkoxymercuration-demercuration approach to ethers over the acid-catalyzed process is the fact that carbon skeleton rearrangements are seldom observed. Only unsaturated cyclopropanes,42S>426 or aryl-substituted alkenes427 428 in the presence of highly electrophilic mercury salts afford rearranged products. 

Reviews have featured epoxidation, cyclopropanation, aziridination, olefination, and rearrangement reactions of asymmetric ylides 66 non-phosphorus stabilized carbanions in alkene synthesis 67 phosphorus ylides and related compounds 68 the Wittig reaction 69,70 and [2,3]-Wittig rearrangement of a-phosphonylated sulfonium and ammonium ylides.71 Reactions of carbanions with electrophilic reagents, including alkylation and Wittig-Homer olefination reactions, have been discussed with reference to Hammett per correlations.72... 

Such a mechanism obviously cannot account for all of the rearrangements for the isotopic scrambling observed when cyclopropanes are reacted with electrophiles and so cannot be the sole pathway operative. 

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