The Staudinger Synthesis, also called the Staudinger Ketene-Imine Cycloaddition, is a chemical synthesis in which an imine1 reacts with a ketene2 through a non-photochemical 2+2 cycloaddition to produce a β-lactam 3. The reaction carries particular importance in the synthesis of β-Lactam antibiotics. The Staudinger Synthesis should not be confused with the Staudinger Reaction, a phosphine or phosphite reaction used to reduce azides to amines. Reviews on the mechanism, stereochemistry, and applications of the reaction have been published.
The first step is a nucleophilic attack by the imine nitrogen on the carbonylcarbon to generate a zwitterionic intermediate. Electron donating groups on the imine facilitate this step, while electron-withdrawing groups impede the attack. The second step is either an intramolecular nucleophilicring closure or a conrotatory electrocyclic ring closure. The second step is different from typical electrocyclic ring closures as predicted by the Woodward–Hoffmann rules. Under photochemical and microwave conditions the intermediate's 4π-electron system cannot undergo a disrotatory ring closure to form the β-lactam, possibly because the two double bonds are not coplanar. Some products of the Staudinger Synthesis differ from those predicted by the torquoelectronic model. In addition, the electronic structure of the transition state differs from that of other conrotary ring closures. There is evidence from computational studies on model systems that in the gas phase the mechanism is concerted.
Stereochemistry
The stereochemistry of the Staudinger Synthesis can be difficult to predict because either step can be rate-determining. If the ring closure step is rate-determining, stereochemical predictions based on torquoselectivity are reliable. Other factors that affect the stereochemistry include the initial regiochemistry of the imine. Generally, -imines form cis β-lactams while -imines form trans β-lactams. Other substituents affect the stereochemistry as well. Ketenes with strong electron-donating substituents mainly produce cis β-lactams, while ketenes with strong electron-withdrawing substituents generally produce trans β-lactams. The ketene substituent affects the transition state by either speeding up or slowing down the progress towards the β-lactam. A slower reaction allows for the isomerization of the imine, which generally results in a trans product.
Variations
Reviews on asymmetric induction of the Staudinger Synthesis, including the use of organic and organometallic catalysts, have been published. The imine can be replaced by adding olefin to produce a cyclobutanone, carbonyl to produce a β-lactone, or carbodiimides to produce 4-imino β-lactams. The Staudinger Synthesis and variations are all ketene cycloadditions. In 2014, Doyle and coworkers reported a one-pot, multicomponent Staudinger synthesis of β-lactams from azides and two diazo compounds. The reaction occurs by a rhodium acetate-catalyzed reaction between the aryldiazoacetate and the organic azide to form an imine. A Wolff Rearrangement of the diazoacetoacetate enone forms a stable ketene, which reacts with the imine to form a stable β-lactam compound. The solvent used for this reaction is dichloromethane and the solution needs to rest for 3 hours at room temperature. The yield of the reaction is about 99%. The reaction with sulfenes instead of ketenes leading to β-sultams is called Sulfa-Staudinger cycloaddition. The following illustration shows an example of the Sulfa-Staudinger cycloaddition. Benzylidenemethylamine reacts with ethanesulfonyl chloride to a β-sultam. For this reaction was tetrahydrofuran used as a solvent and the solution needed to rest for 24 hours.
