Hydrazones reaction with organolithium

The N-N bond of polystyrene-bound hydrazines, which are prepared by reaction of organolithium compounds with resin-bound hydrazones [457], can be cleaved by treatment with borane to yield a-branched, primary amines (Entry 9, Table 3.23). An additional example of reductive cleavage to yield amines is shown in Entry 10 (Table 3.23), in which a resin-bound a,a-disubstituted nitroacetic ester undergoes decarboxylation and reduction to the primary amine upon treatment with lithium aluminum hydride. 

The reactions of organolithium, -magnesium, -zinc, -copper, and -titanium reagents with aldehydes, ketones, acetals, imines and hydrazones will be described in this section. The reactions of enolates and enamines will be subsequently examined ( 6.8 to 6.10). 

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. 

Ort/io-substituted benzaldehyde complexes have been prepared in high enantiomeric purity (97% ee), and in a one-pot sequence, from an optically pure hydrazone derivative, readily available from -q -benzaldehyde chromium tricarbonyl and SAMP [(S)-l-amino-2-(methoxymethyl)pyrrolidine]. The novelty derives from the combined use of a diastereoselective orthoaddition reaction of an organolithium nucleophile and a hydride abstraction with a triphenylmethyl cation. The subsequent acid hydrolysis serves to remove the hydrazone group, thus liberating the aldehyde functionality (Scheme 6.13). 

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