Cyclopropanations allyl esters

The allylic esters 189 and 191 conjugated with cyclopropane undergo regio-selective reactions without opening the cyclopropane ring. The soft carbon nucleophiles are introduced at the terminal carbon to give 190, and phenylation with phenylzinc chloride takes place on the cyclopropane ring to form 192[120]. 

Allylic acetates react with ketene silyl acetals. In this reaction, in addition to the allylated ester 468, the cyclopropane derivative 469. which is formed by the use of bidentate ligands, is obtained[303]. Formation of a cyclopropane derivative 471 has been observed by the stoichiometric reaction of the 7r-allylpal-... 

Other terminal olefins were transformed to the corresponding cyclopropane esters with Z-menthyl and d-menthyl diazoacetates with high stereoselectivity up to 98% ee (Scheme 3). Intramolecular reaction of the phenyl-allyl ester 9 was carried out to give the bicyclic compound 10 with 86% ee and 93% yield. The enantioselectivity for intramolecular cyclopropanation of the 3-methylbutenyl ester 11 was compared with chiral Cu(I), Rh(II), and Ru Pybox catalysts Rh>Ru>Cu [26]. 

A variation on this sequence used malonate or Meldrum s acid to form cyclopropanes and lactones, respectively. Scheme 42 [127]. An important observation in this sequence was that the second reaction was very poor in the presence of the chiral Hgand since the allylic ester that remained was mismatched to the chirality of the Hgand so ionization was very slow. The best way to overcome this problem in the cyclopropane series was to use a paUadium catalyst with an achiral ligand for the second step. The choice of base was crucial to the eventual mode of cycHzation with CS2CO3 being most effective for the cyclopropane forming reaction and K2CO3 the best base for the lactone formation. 

Intramolecular cyclopropanation Malonic esters of certain allylic alcohols form bicyclic lactones by way of iodination and generation of carbene intermediates. Thus when the system containing the malonic ester, iodine, solid K2CO3 and tri-caprylmethylammonium chloride in toluene is heated, the reaction occurs. 

The allyl ester of acetylene carboxylate 341 was employed as a good precursor for the preparation of cyclopropane-fused 7-butyrolactones 342 (Scheme 1.165) [235]. The reaction progressed in the presence of catalytic amounts of Pd(0Ac>2 and stoichiometric amounts of an oxidant such as PhI(OAc>2. Palladium(ll) and palladium(lV) were presumed to be a catalytic cycle of the reaction. Amide derivative 343, which was readily prepared by the Ugi reaction, gave corresponding cyclopropane-fused 7-butyrolactam 344 in moderate yields (Scheme 1.166) [236]. 

The directive effect of allylic hydroxy groups can be used in conjunction with chiral catalysts to achieve enantioselective cyclopropanation. The chiral ligand used is a boronate ester derived from the (VjA jA N -tetramethyl amide of tartaric acid.186 Similar results are obtained using the potassium alkoxide, again indicating the Lewis base character of the directive effect. 

It has been pointed out earlier that the anti/syn ratio of ethyl bicyclo[4.1,0]heptane-7-carboxylate, which arises from cyclohexene and ethyl diazoacetate, in the presence of Cul P(OMe)3 depends on the concentration of the catalyst57). Doyle reported, however, that for most combinations of alkene and catalyst (see Tables 2 and 7) neither concentration of the catalyst (G.5-4.0 mol- %) nor the rate of addition of the diazo ester nor the molar ratio of olefin to diazo ester affected the stereoselectivity. Thus, cyclopropanation of cyclohexene in the presence of copper catalysts seems to be a particular case, and it has been stated that the most appreciable variations of the anti/syn ratio occur in the presence of air, when allylic oxidation of cyclohexene becomes a competing process S9). As the yields for cyclohexene cyclopropanation with copper catalysts [except Cu(OTf)2] are low (Table 2), such variations in stereoselectivity are not very significant in terms of absolute yields anyway. 

Artemisyl, Santolinyl, Lavandulyl, and Chrysanthemyl Derivatives.— The presence of (41) in lavender oil has been reported earlier. Poulter has published the full details of his work (Vol. 5, p. 14) on synthetic and stereochemical aspects of chrysanthemyl ester and alkoxypyridinium salt solvolyses (Vol. 3, pp. 20—22) and discussed its biosynthetic implications. Over 98% of the solvolysis products are now reported to be artemisyl derivatives which are formed from the primary cyclopropylcarbinyl ion (93) which results from predominant (86%) ionization of the antiperiplanar conformation of (21)-)V-methyl-4-pyridinium iodide the tail-to-tail product (96 0.01%) may then result from the suprafacial migration of the cyclopropane ring bond as shown stereochemically in Scheme 3. This is consistent with earlier work (Vol. 7, p. 20, ref, 214) reporting the efficient rearrangement of the cyclobutyl cation (94) to (96) and its allylic isomer, via the tertiary cyclopropylcarbinyl cation (95). ... 

Cyclopropane esters of sterically demanding alcohols can also be a-alkylated. Thus tert-butyl cyclopropanecarboxylate (6) reacted with LDA63 and subsequently with allyl or benzyl bromide to give the products 16A in 79% and 82% yield. 

Acyloin-type reactions of esters provide the simplest route to 1-siloxy-l-alkoxycyclopropane [21,22] Eq. (6). The reaction of commercial 3-halopropionate with sodium (or lithium) in refluxing ether in the presence of Me3SiCl can easily be carried out on a one mole scale [21]. Cyclization of optically pure methyl 3-bromo-2-methylpropionate [23], available in both R and S form, gives a cyclopropane, which is enantiomerically pure at C-2, yet is a 1 1 diastereo-meric mixture with respect to its relative configuration at C-l Eq. (7). Reductive silylation of allyl 3-iodopropionate with zinc/copper couple provides a milder alternative to the alkali metal reduction [24] Eq. (8). 

Treatment of ethacrylate esters 1 with nitronium tetrafluoroborate in acetonitrile has been shown to give cyclopropanes 2 and the products of allylic nitration 3. Formation of 2 was postulated to proceed via an a-carbonyl cation. In an attempt to obtain evidence for the possible intermediacy of a-carbonyl cations in these reactions in terms of Wagner-Meerwein derived products, the more highly substituted substrates 4a, b were subjected to the same reaction conditions of NC>2BF4/MeCN followed by aqueous work-up. This gave 5a, b and 6a, b as shown. 

Cyclopentammes.2 2-Carboalkoxycyclopentanones can be obtained by cycliza-tion of a-diazo-/0-keto esters catalyzed by Rh2(OAc)4. Allylic C—H insertion can be favored over cyclopropanation. 

Dirhodium(II) tetrakis(carboxamides), constructed with chiral 2-pyrroli-done-5-carboxylate esters so that the two nitrogen donor atoms on each rhodium are in a cis arrangement, represent a new class of chiral catalysts with broad applicability to enantioselective metal carbene transformations. Enantiomeric excesses greater than 90% have been achieved in intramolecular cyclopropanation reactions of allyl diazoacetates. In intermolecular cyclopropanation reactions with monosubsti-tuted olefins, the cis-disubstituted cyclopropane is formed with a higher enantiomeric excess than the trans isomer, and for cyclopropenation of 1-alkynes extraordinary selectivity has been achieved. Carbon-hydro-gen insertion reactions of diazoacetate esters that result in substituted y-butyrolactones occur in high yield and with enantiomeric excess as high as 90% with the use of these catalysts. Their design affords stabilization of the intermediate metal carbene and orientation of the carbene substituents for selectivity enhancement. 

Corey exploited the remarkable configurational stability of cyclopropyllithiums in his synthesis of hybridalactone. The stannane 28 was made by Simmons-Smith cyclopropanation of the allylic alcohol 27 and resolved by formation of an O-methyl mandelate ester. Transmetallation of 29 with 2 equiv. BuLi gave an organolithium which retained its stereochemistry even in THF over a period of 3 h at 0 °C, finally adding to 31 to give 32. 

The stereoselectivity of this reaction rises when more bulky nucleophiles are employed (compare entries 7, 3,1, and 5). This is most impressively demonstrated by comparison of the y-lactol reduction with its allylation leading to 205 or 206, respectively (Scheme 10). Formation of tetrahydrofuran derivative 208, dihydrofuran 209, or unsaturated a-methylen-y-butyrolactone 207 illustrate that various modes of straightforward work-up procedures provide two different five membered heterocycles 93 b-96). A second example without the geminal dialkyl substitution at C-3 of the siloxy-cyclopropane depicted in Eq. 86 making available the annulated tetrahydrofuran-3-carboxylate 210 underlines the generality of the C-C-bond forming hydroxyalkylation reaction via ester enolates. 

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