Acetoacetic ester synthesis

A strong base deprotonates the dicarbonyl α-carbon. This carbon is preferred over the methyl carbon because the formed enolate is conjugated and thus resonance stabilized. The carbon then undergoes nucleophilic substitution. When heated with aqueous acid, the newly alkylated ester is hydrolyzed to a β-keto acid, which is decarboxylated to form a methyl ketone.Smith, Janice Gorzynski. Organic Chemistry: Second Ed. 2008. pp 905–906[http://pharmaxchange.info/press/2011/02/acetoacetic-ester-synthesis-alkylation-of-enolates/ Acetoacetic Ester Synthesis – Alkylation of Enolates | PharmaXChange.info] The alkylated ester can undergo a second substitution to produce the dialkylated product.

Image:Acetoacetic ester synthesis.png

The classical acetoacetatic ester synthesis utilizes the 1:1 conjugate base. Ethyl acetoacetate is however diprotic:

:CH₃C(O)CH₂CO₂Et + NaH → CH₃C(O)CH(Na)CO₂Et + H₂

:CH₃C(O)CH(Na)CO₂Et + BuLi → LiCH₂C(O)CH(Na)CO₂Et + BuH

The dianion (i.e., LiCH₂C(O)CH(Na)CO₂Et) adds electrophile to the terminal carbon as depicted in the following simplified form:{{cite journal |doi=10.15227/orgsyn.084.0043|title=Stereoselective Isoprenoid Chain Extension with Acetoacetate Dianion: [(E, E, E)-Geranylgeraniol from (E, E)-Farnesol|journal=Organic Syntheses|year=2007|volume=84|page=43|first1=Yinghua|last1=Jin|first2=Frank G.|last2=Roberts|first3=Robert M.|last3=Coates}}

:LiCH₂C(O)CH(Na)CO₂Et + RX → RCH₂C(O)CH(Na)CO₂Et + LiX

• Malonic ester synthesis

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Category:Carbon-carbon bond forming reactions