Allylic derivatives carbon nucleophile reactions

Nucleophilic addition to a, -unsaturated sulfones has long been known. For example, treatment of divinyl sulfone with sodium hydroxide has been known to afford bis( -hydroxyethyl) sulfone "", while the reaction of a- and -naphthyl allyl sulfones and allyl benzyl sulfone " with alkali hydroxide or alkoxide gave -hydroxy or alkoxy derivatives. In the latter reaction, the allyl group underwent prototropy to the 1-propenyl group, which in a subsequent step underwent nucleophilic attack . Amines, alcohols and sulfides are known to add readily to a, -unsaturated sulfones, and these addition reactions have been studied widely. In this section, the addition of carbon nucleophiles to a, ji-unsaturated sulfones and the reactions of the resulting a-sulfonyl carbanions will be examined. 

Monoanions derived from nitroalkanes are more prone to alkylate on oxygen rather than on carbon in reactions with alkyl halides, as discussed in Section 5.1. Methods to circumvent O-alkylation of nitro compounds are presented in Sections 5.1 and 5.4, in which alkylation of the a.a-dianions of primary nitro compounds and radial reactions are described. Palladium-catalyzed alkylation of nitro compounds offers another useful method for C-alkylation of nitro compounds. Tsuj i and Trost have developed the carbon-carbon bond forming reactions using 7t-allyl Pd complexes. Various nucleophiles such as the anions derived from diethyl malonate or ethyl acetoacetate are employed for this transformation, as shown in Scheme 5.7. This process is now one of the most important tools for synthesis of complex compounds.6811-1 Nitro compounds can participate in palladium-catalyzed alkylation, both as alkylating agents (see Section 7.1.2) and nucleophiles. This section summarizes the C-alkylation of nitro compounds using transition metals. 

Reactions of allylic electrophiles with stabilized carbon nucleophiles were shown by Helmchen and coworkers to occur in the presence of iridium-phosphoramidite catalysts containing LI (Scheme 10) [66,69], but alkylations of linear allylic acetates with salts of dimethylmalonate occurred with variable yield, branched-to-linear selectivity, and enantioselectivity. Although selectivities were improved by the addition of lithium chloride, enantioselectivities still ranged from 82-94%, and branched selectivities from 55-91%. Reactions catalyzed by complexes of phosphoramidite ligands derived from primary amines resulted in the formation of alkylation products with higher branched-to-linear ratios but lower enantioselectivities. These selectivities were improved by the development of metalacyclic iridium catalysts discussed in the next section and salt-free reaction conditions described later in this chapter. 

Efforts to cause the carbon nucleophile available at C-2 (carbohydrate numbering) of the osulose derivative 66 to displace the methoxy group with allylic rearrangement and with consequent formation of a tricyclic product by use of Pd(0) catalysts [34] were unsuccessful, but the intended reaction proceeds "smoothly when tin(IV) chloride is used together with acetic anhydride in dichloromethane. Clearly, the Lewis acid activates the allylic ether group, and the C-2 nucleophile effects its displacement. Concurrently, acetolysis of the benzylidene ring occurs and the product isolated is the cu-decalin analogue 67 [33],... 

The vinylogous elimination to give alkenylcyclopropanes may also be effected via rt-allyl palladium complexes34,35. The palladium(0)-catalyzed substitution of allylic esters with stabilized carbon nucleophiles via 7i-allyl palladium derivatives stereospecifically proceeds with net retention (double inversion) of configuration. Thus, the chirality of an allylic substrate is transferred to resultant alkenylcyclopropanes in the intramolecular S J/ reaction via 7i-allyl palladiums (equation 21)36,3. ... 

Otherwise, unsaturation may be introduced by use of carbonyl-containing carbohydrate derivatives and carbon nucleophiles that contain alkene (or, if desired, alkyne) functionality, a notable illustration being the tin-or indium-mediated C-l allylation of unprotected sugars. As an illustration, D-arabinose, treated with allyl bromide in aqueous ethanol in the presence of tin gives, after acetylation, 278 in 85% yield.258 In this procedure aldoses react better than do ketoses, and pentoses better than hexoses. More usual is the use of Grignard reactions to give, for example, the octynes 279. 

Reaction of 3-fer/-butyl-substituted 2-benzoselenopyrylium and -benzotelluropyrylium salts 194 with allylstan-nanes afforded the corresponding substituted 1 -ally 1-1 //-isosclcnochrorucnes and l-allyl-l//-isotellurochromenes 199 in moderate to excellent yields (Equation 83) <2006H505>. It should be noted that the products are those derived from nucleophilic attack of the terminal carbon of the vinyl group on the heterocycle followed by loss of the tin substituent. In the case of the unsubstituted 2-benzoselenopyrylium and 2-benzotelluropyrylium salts 196, yields of the 1 -allyl-l//-isoselenochromenes and 1 al 1 y 11 //-isotcllurochromcncs 200 were considerably lower than those observed in the tert-butyl derivatives (Equation 84). 

A one-pot procedure for the palladium-catalyzed allylation/cyclization of o-alkynyltrifluoroacetanilides 57a [57] and o-alkynylphenols 57b [58] was developed by Cacchi et al. (Scheme 20). This method provides a valuable tool for the synthesis of 2-substituted-3-allylindoles 58a and 2-substituted-3-allylbenzofurans 58b. It was reported that reaction proceeded through the formation of X-allyl derivatives, which form 7r-allylpalladium species 59. A subsequent rearrangement of 59 would then lead to the 7r-allylpalladium species 60. Intramolecular nucleophilic attack of the hetero atom across the activated carbon-carbon triple bond in 60, followed by reductive elimination of Pd(0) gives the products 58. A similar reaction was reported by Balme et al. [59]. 

This methodology has been used to provide efficient protocols for the asymmetric allylic alkylation of p-keto esters, ketone enolates, barbituric acid derivatives, and nitroalkanes. Several natural products and analogs have been accessed using asymmetric desymmetrization of substrates with carbon nucleophiles. The palladium-catalyzed reaction of a dibenzoate with a sulfonylsuccinimide gave an advanced intermediate in the synthesis of L-showdomycin (eq 3). ... 

The various possibilities for the preparation of chiral allylic amines or a aryl substituted amines are outlined in Figure 1.9. Although the addition reaction of a carbon nucleophile to an imine derived from an aryl substituted aldehyde is very efficient (B), the related addition to an a,p unsaturated imine (A) can sometimes proceed via a 1,4 addition pathway. Similarly, the asymmetric C=N reduction reaction (C and D) is sometimes hampered by the possibility of either obtaining conjugate reduction (in the case of C) or low enantioselectivities (in D when R = aryl). The addition of sp hybridized carbanions to imines (E) is a particularly effective... 

Allyl carbonates are particularly useful allylic substrates. Thus, in addition to their high reactivity in oxidative addition, allyl carbonates have the advantage that the ally-lation reaction can be conducted under neutral conditions without an added base. The (7t-allyl)palladium intermediate (17) derived from an allylic carbonate has a carbonate anion that serves as a masked base to generate carbon nucleophiles (eq (112)) [143]. 

Metal-carbon (M—C) bonds are thermodynamically unstable with regard to their hydrolysis products. Water can attack M—C bonds either by proton transfer (H+, electrophilic reaction) or via the oxygen (OH2 or OH, nucleophilic reaction). Examples are shown in Scheme 1. Ligands such as carbon monoxide and ethylene are activated toward nucleophilic attack upon coordination to (low-valent) metals, e.g., Pd2+. A number of C—C-bond forming reactions derive from this activation. Allyl ligands are generated by proton attack to the terminal 1,3-diene carbon... 

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