Nucleophilic additions, facial selectivity

Stereochemical Control by the Aldehyde. A chiral center in an aldehyde can influence the direction of approach by an enolate or other nucleophile. This facial selectivity is in addition to the simple syn, anti diastereoselectivity so that if either the aldehyde or enolate contains a stereocenter, four stereoisomers are possible. There are four possible chairlike TSs, of which two lead to syn product from the Z-enolate and two to anti product from the A-enolate. The two members of each pair differ in the facial approach to the aldehyde and give products of opposite configuration at both of the newly formed stereocenters. If the substituted aldehyde is racemic, the enantiomeric products will be formed, making a total of eight stereoisomers possible. 

Facial selectivities in the nucleophilic addition of bicyclic ketones have recently been examined comprehensively [71, 72]. Mehta and his colleagues studied the facial selectivities of 2,3-exo,exo-disubstituted 7-norbomanones 14a and 14b [73-75]. In the reduction of 14a and 14b with sodium borohydride, lithium aluminum hydride. 

The exo reactivity of 2-norbomanone 25 in nucleophilic addition (such as reduction with hydride) is a classical example of the facial selectivity of carbonyl groups in bicyclic systems [80]. 

Stereochemical Control by the Enolate or Enolate Equivalent. The facial selectivity of aldol addition reactions can also be controlled by stereogenic centers in the nucleophile. A stereocenter can be located at any of the adjacent positions on an enolate or enolate equivalent. The configuration of the substituent can influence the direction of approach of the aldehyde. 

Substituted snoutan-9-ones (61a) undergo nucleophilic additions with the same facial selectivity as the corresponding norsnoutanones (61b). However, the selectivity is markedly reduced, apparently owing to electrostatic effects in (61a), and hyperconjugative interactions in (61b). ... 

Considerable effort has been devoted to finding Lewis acid or other catalysts that could induce high enantioselectivity in the Mukaiyama reaction. As with aldol addition reactions involving enolates, high diastereoselectivity and enantioselectivity requires involvement of a transition state with substantial facial selectivity with respect to the electrophilic reactant and a preferred orientation of the nucleophile. Scheme 2.4 shows some examples of enantioselective catalysts. 

Electronic and conformational effects on jt-facial stereoselectivity in nucleophilic additions to carbonyl compounds have been studied by the use of RHF/3-21G and RHF/6-31G methods ". Figure 10 shows a comparison of predicted and experimental selectivities for methyl Grignard additions. Satisfactory agreement of the ratios of anti and equatorial attacks of MeMgX on the carbonyl carbon atoms was reported. 

Substituted norsnoutanes (61) have been introduced as substrates with sterically unbiased re-faces, which allow electronic effects in re-facial selectivity of nucleophilic additions to be evaluated.96 Examples indicate how this system allows separation of long-range electronic effects into orbital and electrostatic contributions. 

The effect of a remote substituent on the facial selectivities in a nucleophilic conjugate addition has been investigated for the reaction of EtSH with a series of dibenzobicyclo[2.2.2]octatrienes (84). Syn-addition proved to be favoured for nitro substituent and polar solvents increased the selectivity (Table 5).19... 

Hyperconjugation appears to be the dominant factor governing the diastereoselectivity of the hydrochlorination of 5-substituted 2-methyleneadamantanes 3 (Table 2)36. However, the product distribution for epoxidation suggests that the stereochemical course of electrophilic additions not mediated by carbocations is most likely regulated by direct field effects36. Note that, unlike in the previous reactions, the facial selectivity in this case reflects the preference for the nucleophilic attack on the corresponding carbocation. 

A strictly nucleophilic approach can also be used for an [(N) + (C=C)] protocol Thus the chiral iodo-unsaturated bicyclic lactam 89 undergoes stereoselective conjugate addition with primary amines to give the tricyclic aziridine 90, which can be subsequently transformed into the chiral 3,4-aziridinopyrrolidine 91 by reductive cleavage. Yields of up to 90% can be achieved and facial selectivity is greater than 98 2 [95TL3491],... 

P selectivity. Crich and coworkers proposed that, under preactivation conditions, the oxocarbenium ion is trapped by a triflate anion to form the more stable a-triflate 65. After addition of the acceptor, the a-triflate intermediate can then be displaced in an SN2-like manner to afford a p-mannoside product (68). The formation of a-glycosyl triflates was confirmed by II, 13C, and 19F NMR analyses of the activated mannosyl donor recorded at low temperature [37], The experimentally determined KIE is approximately 1.12, which is consistent with an oxocarbenium-like TS [38], It was hypothesized that the a-triflate converts into the contact ion pair 66 in which the triflate anion remains at the a face or that an exploded TS is formed where the nucleophile is loosely associated with the oxocarbenium ion as the triflate departs [39,40], The a product 69 can be explained by the formation of the solvent-separated ion pair 67 where the counterion is solvated and facial selectivity is lost. 

The use of substituted pyridines in organic synthesis has broad application. The activation of the pyridine ring toward nucleophilic attack is well known in the literature. The products of such reactions are often dihydropyridines which can serve as intermediates in more complex synthetic strategies. Rudler and co-workers have reported on the nucleophilic addition of bis(trimethylsilyl)ketene acetals to pyridine (26). The 1,4-addition product 27 was then cyclized with iodine to afford bicycle 28 in 90% overall yield <02CC940>. Yamada has elegantly shown that facial selectivity can be achieved and chiral 1,4-dihydropyridines accessed in high yield and de (29—>30) <02JA8184>. 

Dihydroisoxazoles can be formed by stereoselective 1,3-dipolar cycloaddition of nitrile oxides, for example, to enantiopure allylic alcohols, and these products can be converted into -amino acids 510 by a characteristic nucleophilic addition to the C=N bond in 509 followed by reductive cleavage of the N—O bond and oxidative cleavage of the diol moiety. The facial selectivity in the nucleophilic addition is dictated by the C(5) substituent (Scheme 109), e.g., <2003JA6846, 2004SL1409, 2005JA5376>. 

In this fourth part we outline some aspects of the reaction of lithium enolates with electrophilic reagents and their nucleophilic addition onto saturated carbonyl groups. Two significant problems associated with these reactions are (i) the site (C/O) selectivity due to the ambident character of enolates, and (ii) the facial discrimination which controls the stereochemistry of the overall process. 

In connection with the total synthesis of grandisol, an asymmetric addition of ethylene on chiral heterocyclic aminals and ketals was examined (Scheme 23). The selectivity can be high, with a preferred approach of ethylene from the less hindered side, especially when chiral pyrrolidone 97 or furanones 100 were used in place of cyclic enones [70]. The diastereoisomeric excess of 101 or 102 remains modest with 5-menthyloxy furanone, even if the dark addition of nucleophiles or radicals on 100 occurs with a total facial selectivity. From a detailed analysis of the dependence of the product ratio with temperature and substituents, it was proposed that a pyramidalization of the (3-carbon in the relaxed of the... 

Nucleophilic addition to less reactive ketone carbonyls by Lewis acid activation is also possible. Evans and co-workers have reported enol silane addition to pyruvate esters mediated by chiral copper Lewis acids (Sch. 36) [72]. The aldol reactions proceed with high facial selectivity to provide the tertiary alcohol products 153. The chemical efficiency is, however, reduced when a bulky alkyl group is present at the ketone carbonyl. Addition of more functionalized enol silanes (155) to keto esters enables the establishment of two contiguous chiral centers, a substitution pattern present in a variety of natural products. The stereochemistry of the major product is syn, irrespective of the enol silane geometry. Once again, bidentate coordination of the substrate to the Lewis acid was essential for obtaining high selectivity. 

For spiro 1,3-oxothiolane species such as 167-169, a study of the influence of the S and O atoms on the facial selectivity of nucleophilic addition to the carbonyl group has been undertaken. Under normal conditions, the addition to C=0 takes place anti to S and syn to O. However, the use of a chelating reagent such as NaBH4 or t -Pr2AlH for a hydride reduction reversed this facial preference <1998TL2527, 1998TL2531>. 

On p. 1023, it was mentioned that electronic effects can play a part in determining which face of a carbon-carbon double bond is attacked. The same applies to additions to carbonyl groups. For example, in 5-substituted adamantanones (2) electron-withdrawing (-/) groups W cause the attack to come from the syn face, while electron-donating groups cause it to come from the anti face. In 5,6-disubstituted norborn-2-en-7-one systems, the carbonyl appears to tilt away from the 7i-bond, with reduction occurring from the more hindered face. An ab initio study of nucleophilic addition to 4-ferf-butylcyclohexanones attempted to predict 7i-facial selectivity in that system. ... 

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