Isomers cyclopropanes

Interestingly, cyclopropane and benzene have the same number of isomers for a given number of identical substituents ignoring optical isomers, cyclopropane and benzene have one type of monosubstituted derivative, three types of disubstituted, three types of trisubstituted, three types of tetrasubstituted and one type apiece of penta- and hexasubstitution. But does this seemingly accidental counting equivalence have any thermochemical consequences ... 

The three-component reaction of lithiated [bis(phenylsulfanyl)methyl]trimethylsilane, phenyloxirane, and an alkene takes an interesting reaction pathway. Obviously the oxirane serves as a trapping reagent for lithium benzenethiolate, which results from a-elimination of the initially formed organolithium compound. The generated phenylsulfanyl(trimethylsilyl) carbene (4) adds stereoselectively to various alkenes. In all cases the sterically less crowded Z-isomer cyclopropane 5 is formed. 

The application of these principles to the C H2 s is shown in Table 8. Ethylene is the C2H4 stabilomer and has a strain energy of 22 kcal mole". The C3 stabilomer of this family, propene, is more stable than its saturated isomer cyclopropane, by 7.85 kcal mole" in accord with the thermodynamic rules of stability. 2-Methylpropene is the most stable C4H8 ( 10 kcal mole" more stable... 

BUTENE. As shown in Figure 38, a group attached to C-1 can migrate from position 1 to 3 (1,3 shift) to produce an isomer. If it is a methyl group, we recover a 1-butene. If it is a hydrogen atom, 2-butene is obtained. A third possible product is the cyclopropane derivative. The photochemical rearrangement of 1-butene was studied extensively both experimentally [88]... 

FIGURE 1.15 Isomers of cyclopropane-1,2-dicarboxyUc acid, (a) Trans isomer b) meso isomer. 

The fundamental subject of this section is the transformation of A -pyrazolines into cyclopropanes (Buchner-Curtius and Kishner cyclopropane syntheses). The cyclopropane is often accompanied by alkenes (67HC(22)l). When applied to A -pyrazolines the reaction occurs via the A isomers (Scheme 37). 

In decoupling the methyl protons, the NOE difference spectrum shows a nuclear Overhauser enhancement on the cyclopropane proton at = 1.60 and on the terminal vinyl proton with trans coupling at <5// = 5.05 and, because of the geminal coupling, a negative NOE on the other terminal proton at Sh= 4.87. This confirms the trans configuration G. In the cis isomer H no NOE would be expected for the cyclopropane proton, but one would be expected for the alkenyl-// in the a-position indicated by arrows in H. 

Thus the unsaturated ketones carvone, eucarvone and 1-acetyl-cyclohexane formed the cyclopropyl ketones (6), (7) and (8) while benzalaceto-phenone (9) affords l-benzyl-2-pheny 1-cyclopropane as a mixture of as and irons isomers (10) and (H) 233,234... 

The behavior of strained,/Zuorimiret/ methylenecyelopropanes depends upon the position and level of fluorination [34], l-(Difluoromethylene)cyclopropane is much like tetrafluoroethylene in its preference for [2+2] cycloaddition (equation 37), but Its 2,2-difluoro isomer favors [4+2] cycloadditions (equation 38). Perfluoromethylenecyclopropane is an exceptionally reactive dienophile but does not undergo [2+2] cycloadditions, possibly because of stenc reasons [34, 45] Cycloadditions involving most possible combinations of simple fluoroalkenes and alkenes or alkynes have been tried [85], but kinetic activation enthalpies (A/f j for only the dimerizations of tetrafluoroethylene (22 6-23 5 kcal/mol), chlorotri-fluoroethylene (23 6 kcal/mol), and perfluoropropene (31.6 kcal/mol) and the cycloaddition between chlorotnfluoroethylene and perfluoropropene (25.5 kcal/mol) have been determined accurately [97, 98] Some cycloadditions involving more functionalized alkenes are listed in Table 5 [99. 100, 101, 102, 103]... 

Interestingly, the reaction of tricyclenone (100) with morpholine also led to the exo isomer of the saturated ketone (101), involving the cleavage of the cyclopropane ring. 

In 1963, Dauben and Berezin published the first systematic study of this syn directing effect (Scheme 3.15) [37]. They found that the cyclopropanation of 2-cyclohexen-l-ol 32 proceed in 63% yield to give the syn isomer 33 as the sole product. They observed the same high syn diastereoselectivity in a variety of cyclic allylic alcohols and methyl ethers. On the basis of these results, they reasonably conclude that there must be some type of coordinative interaction between the zinc carbenoid and the substrate. 

Incorporation of the phenethyl moiety into a carbocyclic ring was at first sight compatible with amphetamine-like activity. Clinical experience with one of these agents, tranylcypromine (79), revealed the interesting fact that this drug in fact possessed considerable activity as a monamine oxidase inhibitor and as such was useful in the treatment of depression. Decomposition of ethyl diazoacetate in the presence of styrene affords a mixture of cyclopropanes in which the trans isomer predominates. Saponification gives acid 77. Conversion to the acid chloride followed by treatment with sodium azide leads to the isocyanate, 78, via Curtius rearrangement. Saponification of 78 affords tranylcypromine (79). 

A solution of the above ester (207.8 grams) and 64.5 grams of sodium hydroxide in 80 cc of water and 600 cc of ethanol is refluxed for 9 hours. The carboxylic acid of 2-phenyl-cyclopropane is liberated with 200 cc of concentrated hydrochloric acid. The 2-phenyl-cyclopropanecarboxylic acid contains 3 to 4 parts of the trans isomer to 1 part of the cis isomer. The acid is recrystallized from hot water. The pure trans isomer comes out as crystalline material (solid) while the cis isomer stays in solution. 

The three groups discussed in Sec. 56 arc fundamental for the understanding of the isomers of the derivatives of cyclopropane, CjHg, where the six H atoms are replaced by radicals of valence 1. 

Because of their cyclic structures, cycloalkanes have two faces as viewed edge-on, a "top" face and a "bottom" face. As a result, isomerism is possible in substituted cycloalkanes. For example, there are two different 1,2-dimethyl-cyclopropane isomers, one with the two methyl groups on the same face of the ring and one with the methyls on opposite faces (Figure 4.2). Both isomers are stable compounds, and neither can be converted into the other without breaking and reforming chemical bonds. Make molecular models to prove this to yourself. 

Unlike the constitutional isomers butane and isobutane (Section 3.2), which have their atoms connected in a different order, the two 1,2-dimethyl-cyclopropanes have the same order of connections but differ in the spatial orientation of the atoms. Such compounds, which have their atoms connected in the same order but differ in three-dimensional orientation, are called stereochemical isomers, or stereoisomers. 

The cis and tram isomers of 2-butene give different cyclopropane products in the Simmons-Smitli reaction. Show the structure of each, and explain the difference. 

Chrysanthemumic acid may exist in four stereoisomers, because of the two asymmetric carbon atoms in the cyclopropane ring. The natural acid has the D-trans configuration and this has been shown to be more insecticidally active than any of the other isomers or the racemic form. Harper et al, (4,18) have synthesized, separated, and optically resolved all of the isomers of this acid. 

Chrysanthemum dicarboxylic acid or pyrethric acid may exist in eight stereoisomers, owing to the trans or cis configuration on the side chain of the double bond as well as that of the cyclopropane. The natural acid has been shown to be the trans-trans acid. As in the case of the chrysanthemum monocarboxylic acid, the naturally occurring configuration is more insecticidally active than the racemic form or any of the three isomers synthesized. 

Both (cis- and trans-) isomers rearrange stereospecifically to the cis-rearranged cyclopropane product (i.e. 257), the processes being apparently controlled by the same cis-anion intermediate (i.e. 256)... 

Self-Test 13.5B Calculate the concentration of cyclopropane, C H6 (1), remaining after the first-order conversion into its isomer propene (2) ... 

When cyclopropane (C3H , see 1) is heated to 500.°C (773 K), it changes into an isomer, propene (see 2). The following data show the concentration of cyclopropane at a series of times after the start of the reaction. Confirm that the reaction is first order in C3H6 and calculate the rate constant. 

The formation of alkyl shifted products H and 14 can be explained in terms of the formation of endo-intermediate 21 formed by endo attack of bromine to 2 (Scheme 4). The determined endo-configuration of the bromine atom at the bridge carbon is also in agreement with endo-attack. Endo-Intermediate 21 is probably also responsible for the formation of cyclopropane products 12 and 15. The existence of cyclopropane ring in 12 and 15 has been determined by and 13c NMR chemical shifts and especially by analysis of cyclopropane J cH coupling constants (168 and 181 Hz). On the basis of the symmetry in the molecule 12 we have distinguished easily between isomers 12 and 15. Aryl and alkyl shift products IQ, H, and 14 contain benzylic and allylic bromine atoms which can be hydrolized easily on column material. 

Woodworth, based on the common reaction of addition of carbenes to double bonds to form cyclopropane derivatives (15-50). If the singlet species adds to cis-2-butene, the resulting cyclopropane should be the cis isomer since the movements of the two pairs of... 

The aza-bis(oxazoline) 14, bearing sterically hindering groups, led to very good results in terms of activity and selectivity, comparable to those obtained from corresponding aza-semicorins or bis(oxazolines). For the enantioselec-tive cyclopropanation of styrene, the trans isomer was obtained in 92% ee... 

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