Of cyclopropane 1,1-diesters

The Lewis-acid-promoted formal intramolecular 3 + 2-cycloaddition of cyclopropane 1,1-diesters with allenes (25) produced [4.3.0]nonanes (26) and [3.2.1]octanes (27) by parallel-cycloaddition and cross-cycloaddition, respectively (Scheme 8). Similarly, the Lewis-acid-catalysed formal intramolecular 3 + 2-cycloaddition reactions of cyclopropane 1,1-diesters with alkenes produced bridged[n.2.1]carbocyclic compounds with excellent stereo- and regio-selectivity under mild conditions. This reaction has been successfully applied to the total synthesis of tetracyclic diterpenoids phallocladanol and phallocladene. ... 

The application of d5-2,3-disubstituted cyclopropane 1,1-diesters to [3 + 2]-annulations with aldehydes under the promotion of AICI3 can result in the formation of the desired polysubstituted tetrahydrofuran products... 

One significant limitations of both methods described above is that some types of donor-acceptor cyclopropanes such as the extensively studied 2-substituted cyclopropane-1,1-diesters are unable to produce the desired azides under then-conditions. In this regard, in 2015, Trushkov et al. developed a general and efficient method for ring-opening of various donor-acceptor cyclopropanes with NaN3 to synthesize a variety of polyfunctional azides (Scheme 6.27) [82]. The process proceeds with excellent regioselectivity and provides the products in moderate to... 

Previously cyclopropane-1,1-dicarboxylic acid had been prepared2-4 by hydrolysis of the corresponding diester. The preparation of 1,1-dicarboalkoxycyclopropanes by a conventional double alkylation of diethyl malonate with 1,2-dibromoethane was severely complicated by the recovery of unreacted diethylmalonate. This required a rather difficult distillation to separate starting material and product. In fact, many commercially offered lots of cyclopropane diester contain extensive amounts of diethyl malonate. Furthermore, preparation of the diacid required a separate and relatively slow saponification of the diester.5... 

Reaction of the cyclopropane-1,1-dicarboxylate (410) with the enamine (552) followed by extraction with dilute hydrochloric acid gives rise to the ketodiester (564) presumably via the intermediacy of 563 (equation 197). This difference in reactivity of the diester... 

This reaction was first reported by Perkin in 1883. It is the nucleophilic alkylation between malonic ester and Q, o)-alkyl dihalide to form cyclic aliphatic 1,1-diester or acid and is known as the Perkin reaction or Perkin synthesis. Although it was once referred to as the Perkin condensation, this name should not be used for this type of reaction. Using this protocol, Perkin successfully prepared cyclopropane-, cyclobutane-, cyclopentane-, cyclohexane-, and cycloheptane-1,1-dicarboxylie acids. However, this reaction is often complicated by the side reaction that forms Q, o, a ,a -tetracarboxylic ester from the Sn2 reaction between malonic ester and o, a -alkyl dihalide, this side reaction can be depressed if alcoholic sodium malonic ester is added slowly to the o, a -alkyl dihalide with vigorous stirring. It is interesting that the K2CO3 promoted a reaction between dimethyl 1,3-acetonedicarboxylate and tran5 -l,4-dibromobutene yields vinyldihydrofuran. ... 

Dehydrohalogenation sometimes leads to cyclization which gives cycloalkanes or heterocycles. The fluorinated diester 1 has proved to be a convenient source of polyfluoroalkylated cyclopropanes. Reaction of 1 with aqueous potassium hydroxide gives 2- HA //-hepta-fluorobutyl)cyclopropane-l, 1 -dicarboxylic acid (2) in quantitative yield.120 The diethyl ester 3 ot this acid is obtained in a yield of 87% by the reaction of 1 with sodium ethoxide in anhydrous ethanol.120... 

Scandium triflate catalyses a highly diastereoselective addition of imines to 1,1-cyclopropane diesters to give multi-substituted pyrrolidines.77... 

In a preliminary study toward the total synthesis of the kopsane alkaloid 140, which may exhibit cholinergic activity, the formal [3 + 2] annulation reaction of 3-alkylindoles with 1,1-cyclopropane diesters was studied in the presence of Yb(OTf)3 either at elevated temperature or at high pressure. For example, N-methyltetrahydrocarbazole (141) with styryl-substituted cyclopropane 142 produced a mixture of diastereomeric adducts 143a and 143b (3 1) in 49% yield at 1.3 GPa for 7 days (Scheme 39) [89]. 

Spiroacylal 2 was designed under the rationale that the constraint of the carbonyl groups into a conformation in which overlap of their 7r-orbitals with the bent bonds of the cyclopropane is assured should dramatically increase the vulnerability of the cyclopropane toward nucleophilic attack.8 Experimental support for this notion is abundant.8 Spiroacylal 2 is considerably more reactive than 1,1-dicarbethoxycyclopropane in such reactions. For instance, reaction of 2 with piperidine occurs at room temperature. The corresponding reaction in the case of the diester is conducted at 110°C.5 Reactions with enolates also occur under mild conditions.8 Compound 2 reacts with the weak nucleophile pyridine at room temperature to give a betaine.8 An illustrative mechanism for the reaction of the acylal 2 with aniline to afford 2-oxo-l-phenyl-3-pyrrolidinecarboxylic acid (3) is... 

Danishefsky and co-workers have continued their investigations on the nucleophilic cleavage of activated cyclopropanes. Alkyl-substituted cyclopropane diesters (210) show a preferance for cleavage of the C-1—C-2 bond, with the alkyl... 

A tandem ring opening-cyclization reaction of 2-substituted 1,1-cyclopropane-diesters with N-benzyl imines in the presence of 5 mol% of Sc(OTf)3 was developed [149]. The 2,3,5-substituted pyrrolidines were obtained in moderate to high yields (42-98%) with high diaster eoselectivities (cis/trans = 8/1-30/1). 

The cobalt complexed cyclopropane diester 4 was then reacted with a variety of aldehydes in the presence of boron trifluoride etherate in dichloromethane to afford the desired tetrahydrofurans 5 in high yields with poor diastereoselective control (Scheme 10.6). The cycloaddition reaction was limited to electron deflcient aromatic, aliphatic, and functionalized aldehydes, where no reaction was observed with electron rich aromatic aldehydes. The tetrahydrofurans were obtained as a 1 1 mixture of cis- and fran -isomers, where the best diastereomeric ratio obtained was 2 1 (5d) in favor of the fran -isomer. Modifying the temperature of the reaction had little effect on the diastereoselectivity. Confirmation of the stereochemistry was achieved by X-ray and NMR analysis of the separated diastereoisomers, including... 

Substitution of the VCP is tolerated both on and adjacent to the cyclopropane ring. Diester-substituted and heteroatom (O, NTs) tethers are well tolerated. Reactions were conducted with 2-10 mol% catalyst at up to 0.20 M, as illustrated. Most importantly, reactions with the naphthalene catalyst were found to be more rapid than those with other catalysts. For example substrate 54 is readily converted in >99% yield to cycloadduct 55 in only 15 min at room temperature (entry 1). Complex 93 efficiently catalyzes the reactions of both alkynes and alkenes with VCPs, offering greater generahty than thus far observed with non-rhodium catalysts. This catalyst is particularly advantageous in the cases of substrates 100 and 102, for which the desired product is not formed cleanly with Wilkinson s catalyst due to product isomerization. 

The intermediacy of >/2-cyclopropene complexes of nickel has been proposed in catalyzed 2+1 reactions of free cyclopropene with electron-poor olefins, to give vinylcyclo-propanes. For example, the reaction of fumarate esters with 3,3-disubstituted cyclopropenes in the presence of Ni(COD)2 catalyst gave vinyl-substituted trans-2,3-cyclopropane dicarboxylate esters (equation 235)72 302. However, when maleic esters were used instead, a mixture of both cis and trans vinylcyclopropane diesters is obtained. 

The procedure described here for compound 1 is a scaleup of a published method.6 Phase-transfer catalysis7 and concentrated alkali are used to effect a one-pot conversion of diethyl malonate to the cyclopropane diacid, which is easily obtained by crystallization. Apparently alkylation of the malonate system occurs either at the diester or monocarboxylate, monoester stage since the method fails when malonic acid itself is used as the starting material. This method of synthesizing doubly activated cyclopropanes has been extended to the preparation of 1-cyanocyclopropanecar-boxylic acid (86%) by the use of ethyl cyanoacetate and 1-acetyl-cyclopropanecarboxylic acid (69%) by use of ethyl acetoacetate.6... 

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