Cyclopropanation enantiomers

The trans .cis (or E/Z) ratios of cyclopropane products are higher than those obtained with styrene, and the diastereomer ratio or enantiomer ratio for the trans( ) isomer is generally >90 10. Although these reactions are usually performed with 1.0 mol % of catalyst, Evans has optimized the cyclopropanation of isobutylene to a 0.25 mol scale [40], by using only 0.1 mol % of catalyst, and obtained a 91 % yield of the (S)-cyclopropane enantiomer whose enantiopurity... 

List all the symmetry elements of the following molecules, assign each to a point group, and state whether they form enantiomers (a) lactic acid, (b) trans-[Co(ethylenediamine)2Cl2], (c) c -[Co(ethylenediamine)2Cl2], (d) cyclopropane,... 

Incorporation of stereogenic centers into cyclic structures produces special stereochemical circumstances. Except in the case of cyclopropane, the lowest-eneigy conformation of the tings is not planar. Most cyclohexane derivatives adopt a chair conformation. For example, the two conformers of cis-l,2-dimethylcyclohexane are both chiral. However, the two conformers are enantiomeric so the conformational change leads to racemization. Because the barrier to this conformational change is low (lOkcal/mol), the two enantiomers arc rapidly interconverted. 

Another problem that required solving was the moderate yield obtained in the cyclopropanation reaction when only one equivalent of styrene was used. By increasing the amount of styrene up to its use as the reaction solvent, a noticeable effect on the selectivities was observed when laponite was used as the support [58]. The active role of the clay support was definitely estabhshed when the results in homogeneous and heterogeneous phases were compared (Table 9). These effects involved the reversal of the trans preference in solution to the cis preference with the laponite-supported catalyst in styrene, and also a reversal in the absolute configuration of the major cis enantiomer ob-... 

In the case of the reaction between N-acryloyloxazolidin-2-one and cy-clopentadiene, both catalysts showed activities and enantioselectivities similar to those observed in homogeneous phase. However, a reversal of the major endo enantiomer obtained with the immobilized 6a-Cu(OTf)2 catalyst, with regard to the homogeneous phase reaction, was noted. Although this support effect on the enantioselectivity remains unexplained, it resembles the surface effect on enantioselectivity of cyclopropanation reaction with clay supports [58]. 

In another reaction dendritic pyridine derivatives such as 82 or 83 were tested as co-catalysts for enantioselective cyclopropanation of styrene with ethyl diazoacetate [102]. Using catalyst 82, enantiomer ratios of up to 55 45 were obtained. However, with catalyst 83 bearing larger branches yields and selectivities did not increase. The relatively low selectivities were rationalized by the presence of a large number of different conformations that this non-rigid system may adopt. 

Baldwin et al. have used the same catalyst/diazo ester combination for the synthesis of optically active deuterated phenylcyclopropanes (Scheme 28) 197). From cis-1,2-dideuteriostyrene, d/-menthyl a-deuteriodiazoacetate and (+)-195d, the cis- and mnw-cyclopropanes 196 were obtained, both with 90% optical purity. The dominant enantiomer of trans-196 had (+)-(15, IS, 35) configuration. Analogously, the cyclopropanes c -198 and trans-198, obtained from styrene, d/-menthyl a-deuteriodiazoacetate and (+)-195d with subsequent transesterification of cisjtrans-197, had optical purities of 86 and 89%, respectively. The major optical isomer of cis-198 had (IS, 2R) configuration, that of trans-198 (IS, 2S) configuration. 

As Table 13 shows, the opposite enantiomers of both cis- and frans-cyclopropanes are accessible if 207b or 207c are used instead of 207a 88). An analogous result was found for cyclopropanation of 1,1 -diphenylethylene with ethyl diazoacetate (Table 14). 

It has already been mentioned that prochirality of the olefin is not necessary for successful enantioselective cyclopropanation with an alkyl diazoacetate in the presence of catalysts 207. What happens if a prochiral olefin and a non-prochiral diazo compound are combined Only one result provides an answer to date The cyclopropane derived from styrene and dicyanodiazomethane shows only very low optical induction (4.6 % e.e. of the (25) enantiomer, catalyst 207a) 9S). Thus, it can be concluded that with the cobalt chelate catalysts 207, enantioface selectivity at the olefin is generally unimportant and that a prochiral diazo compound is needed for efficient optical induction. As the results with chiral copper 1,3-diketonates 205 and 2-diazodi-medone show, such a statement can not be generalized, of course. 

Recent advances in gas chromatographic separations of enantiomers allow precise determination of the enantiomeric purity of the algal pheromones. The czs-disubstituted cyclopentenes, such as multifidene, viridiene, and caudoxirene, are of high optical purity [ 95% enantiomeric excess (e.e.)] whenever they have been found (32,33). The situation is different with the cyclopropanes and the cycloheptadienes, as shown in Table 2 and Figure 1. Hormosirene from female gametes or thalli of... 

The stereoselectivities in this reaction are governed by steric interactions in the formation of metallacyclobutane 60 (35). Of two possible intermediates (Fig. 5), 61 suffers from steric interactions between the ligand and the ester functionality. Avoidance of these interactions and minimization of 1,2-interaction in the metallacyclobutane leads to the formation of the observed major enantiomer and dias-tereomer (trans). The model suggests that increased diastereoselectivity should be observed with increasing steric bulk of the diazoester, a relationship that has already been established as discussed (cf. Eqs. 24 and 26). It is interesting to note that this model loosely corresponds to the stereochemical model proposed by Aratani for the Sumitomo cyclopropanation with one important difference the Aratani model is based on a tetrahedral metal while the Evans-Woerpel model is predicated on square-planar copper. Applying the Aratani model to the Evans ligand would predict formation of the opposite enantiomer as the major product (35). 

In a study aimed at examining both the electronic influence of attaching a phenyl ring to the cyclopropyl ring of ciprofloxacin and the tolerance to this added steric bulk, the enantiomeric fraiu-disubstituted cyclopropane analogues (60) and (61) were prepared [94]. In general, the (1 S,2R)-enantiomer (61) is... 

Now, let us examine the case where all three carbon atoms of cyclopropane become asymmetric and satisfied by different groups. In such a case because the molecule contains three different chiral centres, therefore, there will be 23 = 8 optically active forms (four pairs of enantiomers) and there will be four geometrical isomers. The different forms are (xxv) a-d). 

It is interesting to note that the reaction of trans-henzal-acetophenone with ylide 162a affords (15, 25 )-phenylcyclopropane with 35.3% optical purity, whereas its enantiomer having the (li ,2/ )-configuration is formed when tranj-benzalacetophenone is reacted with ylide 162b. Studies on the relationship between the steric requirements of the substituents attached to the chiral ylide sulfur atom and the optical purity of the cyclopropane rings formed have shown that increases in the steric size of the iV,iV-dialkylamino... 

The inter- or intramolecular cyclopropanation of achiral alkenes with enantiome-rically pure diazoacetic esters [1016,1363,1364] or amides [1365,1366] does not usually proceed with high diastereoselectivity. A chiral auxiliary which occasionally gives good results is pantolactone (3-hydroxy-4,4-dimethyltetrahydro-2-furanone) [1016,1367,1368]. 

The same stereochemical principles are going to apply to both acyclic and cyclic compounds. With simple cyclic compounds that have little or no conformational mobility, it is easier to follow what is going on. Consider a disubstituted cyclopropane system. As in the acyclic examples, there are four different configurational stereoisomers possible, comprising two pairs of enantiomers. No conformational mobility is possible here. 

The cyclopropane aldehyde 156 was identified as a versatile chiral building block for the enantioselective synthesis of 4,5 disubstituted y-butyrolactones of type 158 or 159. Both enantiomers of 156 can be easily obtained in a highly diastereo- and enantioselective manner from fixran-2-carboxylic ester 154 using an asymmetric copper-catalyzed cyclopropanation as the key step followed by an ozonolysis of the remaining double bond (Scheme 25) [63]. Addition of... 

Kinetic resolution (enantiomer differentiation) of cycloalkenyl diazoacetates has been achieved (for example, according to Eq. 3) [34]. In these cases one enantiomer of the racemic reactant matches with the catalyst configuration to produce the intramolecular cyclopropanation product in high enantiomeric excess, whereas the mismatched enantiomer preferentially undergoes hydride abstraction from the allylic position [35] to yield the corresponding cycloalkenone. With acyclic secondary allylic diazoacetates the hydride abstraction pathway is relatively unimportant, and diastereoselection becomes the means for enantiomer differentiation [31]. 

Figure 13.5 Bisadducts of Cy obtained from twofold cyclopropanation reactions. Both addends with chiral and achiral substituents have been used. Adducts 2 and 3 exhibit an inherently chiral addition pattern and are formed together with the corresponding enantiomer or diastereomer involving the mirror image addition pattern.

We have examined the above-described series of trans- and c/s-2-fluoro-2-phenylcyclopropylamine analogues (60a-d, 61a-d) as inhibitors of recombinant human liver MAO A and B [134]. The presence of fluorine attached to a cyclopropane ring, especially for frans-isomer 8a, was found to result in an increase in inhibitory activity toward both MAO A and B (Table 4). In addition, p-substitution of electron-withdrawing groups, such as Cl and F, in the aromatic ring of the frans-isomers (60b-d) increased the inhibition of both enzymes. On the other hand, the introduction of fluorine at 2-position of c/s-isomer 8b resulted in loss of inhibitory activity for both MAO A and B, and no further p-aromatic substitution for c/s-isomer greatly affected on the inhibitory activity with either enzymes. In addition, both MAO A and B were selectively inhibited by the (1S,2S)-enantiomer of 60a, while no inhibition was observed with the (1f ,2f )-enantiomer [134]. As already described in the former section, several questions on the mechanistic pathway for MAO inhibition by cyclopropylamines still remain. However,... 

The (ri" -diene tricarbonyliron)-substituted diazocarbonyl compounds 25 have been found to undergo 1,3-dipolar cycloaddition with methyl acrylate in high yield, but with little or no diastereoselectivity (56). Nevertheless, the facile chromatographic separation of the diastereomeric products 26a,b and 27a,b (Scheme 8.8), permits the synthesis of pure enantiomers when optically active diazo compounds (25) [enantiomeric excess (ee) >96%] are employed. When the reaction of 25 (R = C02Et) with methyl acrylate was carried out at 70 °C, cyclopropanes instead of A -pyrazolines were formed. The enantiomerically pure... 

Recently, the cyclopropanation of (Z)-4-benzyIidene-2-phenyl-5(4//)-oxazolone 621 with phenyldiazomethane was reported to give the spirocyclopropane, rac- 21 in very high yield. Subsequent ring opening and hydrolysis of rac- 21 generated frani-l-amino-2,3-diphenyl-l-cyclopropanecarboxylic acid, rac-828 (cadiPhe) (Scheme 7.256). This new, constrained phenylalanine analogue induces a y-tum in the sohd state when incorporated into model dipeptides. The enantiomers of the Al-Boc (Boc = tert-butyloxycarbonyl) methyl ester of 828 have been resolved by HPLC. 

A diene system with unsymmetrical 1,4-disubstitution is converted to the iron carbonyl complex 1 which is resolved into its enantiomers. The aldehyde function is conformationally locked in the transoid position and is diastereofacially shielded from the bottom face. Nucleophiles attack from the top face with high selectivity. Alternatively, chain elongation leads to the triene 2 which is reacted with diazomethane. Cerium(IV) oxidation removes the metal and furnishes the substituted cyclopropane 3. 

A case of matched and mismatched pairs was observed in the reagent-controlled cyclopropanation of chiral allylic alcohols. When the chiral, nonracemic allylic alcohol was treated with one enantiomer of the dioxaborolane ligand, the anti diastereomer was... 

When a substituted cyclopropane is heated, it may isomerize to one or another geometrical isomer or to its enantiomer. These thermal stereomutation reactions have attracted extensive experimental and theoretical efforts directed toward understanding in detail just how such reactions occur. 

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