Carbanions reaction with tosylates

Preparation of Aryl Azides. Aryl azides may be prepared by reaction of aryl carbanions with tosyl azide followed by treatment of the triazene salt with sodium pyrophosphate (Eq. 67)305 or aqueous base (Eq. 72).315... 

Bicyclic pyrazolidine derivatives (213) and (215) can be converted into diazo compounds (214) and (216), respectively, on treatment with tosyl azide in the presence of triethylamine in dichloro-methane or acetonitrile <87JCS(P1)885>. This diazo transfer reaction is initiated by an electrophilic attack of tosyl azide on the carbanion generated from the respective bicyclic compounds (Scheme 33). 

A) and used in organic synthesis. a-Lithio sulfides give useful carbanion reactions and sulfur ylids can be formed (secs. 8.6, 8.8.B). The difficulties in preparing primary and secondary amines by traditional methods (from halides or tosylates via reaction with imides or azides, sec. 2.7) make the hydroboration-amination sequence a mild and useful alternative for the synthesis of amines. 

Various [l- C]carboxylic acids have been prepared by carboxylation of carbanions stabilized by -I or -M substituents. The examples in Figure 5.7 have been selected here as prototypes, since they are of strategic interest. Deprotonation of diethyl methylphos-phonate (18 with n-BuLi followed by [ CJcarboxylation and esterification with diazoethane provided triethyl phosphonoll- Clacetate (19) in an overall radiochemical yield of 62%. Compound 19 has been widely exploited for chain extensions by a labeled two-carbon unit via its alkenylation reaction with carbonyl compounds (Homer-Wadsworth-Emmons reaction). Similarly, reaction of alkyl halides, tosylates or carbonyl compounds with LiC = CH or LiC=CH H2NCH2CH2NH2 followed by deprotonation and [ C]carboxylation of the resulting terminal alkynes has been used as a strategic tool for the incorporation of a labeled three-carbon unit, as exemphfied in a steroid platform (20 to 21). This chemistry provides outcomes complementary to those using [ C2]acetylene (Chapter 8, Section 5.1). Finally, the [ CJcarboxylation of lithiated dimethylsulfide provided an alkylthio[l- C]acetic acid 22 and thence a functionalized 2-alkylthio[l- C]ethyl derivative 23 useful, in this case, for elaboration into e.p. 

The most important reactions of alkyl substituents a and y to the ring heteroatom are those which proceed via base-catalyzed deprotonation. Treatment of 2- and 4-alkyl heterocycles with strong bases such as sodamide and liquid ammonia, alkyllithiums, LDA, etc., results in an essentially quantitative deprotonation and formation of the corresponding carbanions. These then react normally with a wide range of electrophiles such as alkyl halides and tosylates, acyl halides, carbon dioxide, aldehydes, ketones, formal-dehyde/dimethylamine, etc., to give the expected condensation products. Typical examples of these transformations are shown in Scheme 17. Deprotonation of alkyl groups by the use of either aqueous or alcoholic bases can also be readily demonstrated by NMR spectroscopy, and while the amount of deprotonation under these conditions is normally very small, under the appropriate conditions condensations with electrophiles proceed normally (Scheme 18). 

Thus polystyryl carbanions and polyacrylonitrile carbanions prepared by anionic polymerization were reacted with cellulose acetate or tosylated cellulose acetate in tetrahydrofuran under homogenous reaction conditions. The carbanions displaced the acetate groups or the tosylate groups in a S v2-type nucleophilic displacement reaction to give CA-g-PS and CA-g-PAN. Mild hydrolysis to remove the acetate/tosylate groups furnishes the pure cellulose-g-polystyrene (Figure 3). 

The reaction of alkyllithium reagents with acyclic and cyclic tosylhydrazones can lead to mixtures of elimination (route A) and addition (route B) products (Scheme 22). The predominant formation of the less-substituted alkene product in the former reaction (Shapiro Reaction) is a result of the strong preference for deprotonation syn to the N-tosyl group. Nucleophilic addition to the carbon-nitrogen tosyl-hydrazone double bond competes effectively wiA a-deprotonation (and alkene formation) if abstraction of the a-hydrogens is slow and excess organolithium reagent is employed. Nucleophilic substitution is consistent with an Su2 addition of alkyllithium followed by electrophilic capture of the resultant carbanion. 

The one-pot reaction similarly starts by the intermolecular reaction of the oxirane with a stabilized (e.g. by sulfur) carbanion, but then is followed by in situ tosylation of the resulting alkoxides with subsequent deprotonation to give the cyclopropanes by an SnI process. 

The intermolecular reaction of oxiranes with stabilized disulfanyl-substituted carbanions, followed by in situ tosylation or mesylation of the resulting alkoxides and subsequent deprotonation, yields cyclopropanes by an S i process (one-pot reaction). 

The few examples indicate that sulfone-stabilized carbanions should react normally with electrophilic animating reagents (Eqs. 145158 and 146465) with the caveat that free a-amino sulfones are unstable.158,465 The (3,y-unsaturated sulfone 74 is animated at the y-position (Eq. 147),250 presumably by an ene reaction. The preparation of a-tosyl azides from nitronates was shown above in Eq. 144. The scope of this reaction does not seem to have been determined. Reaction of the anions of nitrobenzyl aryl sulfones with l-oxa-2-azaspiro[2.5]octane (13a) gives nitrobenzaldehydes by cleavage of the initially formed amination products.466 Similarly, reaction of the lithium salt of benzyl phenyl sulfone with phenyl azide gives benzilydeneaniline and phenyl sulfinate.467 No reports on animations of sulfoxide-stabilized carbanions were found. 

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