Penam should not be confused with penem.
Penams are the primary skeleton structures that define the penicillin subclass of the broader β-lactam family of antibiotics and related compounds. They are bicyclic ring systems containing a β-lactam moiety fused with a five-member thiazolidine ring. [1] Due to ring strain and limitations on amide resonance, the structure is unstable and highly susceptible to catalytic cleavage at the amide bond. Benzylpenicillin (penicillin G) is the natural product parent that contains the penam structure.
Penams have inflexible structures. The structure is locked in a puckered (i.e. bent) shape due to the pyramidal geometry of the bridgehead nitrogen. The pyramidalization (χ = 54°) and twist of the C-N bond (τ = 18°) is caused by the strain from the lone pair's exclusion from planarity with the cyclic rings and electrostatic repulsion effects. As a result, the distorted C-N bond causes misalignment the orbitals of the carbonyl carbon and the nitrogen lone pair that allow for resonance overlap. The amide C-N bond length is 1.406Å and displays greater single bond character than in noncyclic tertiary amides. The C-O bond length is 1.205Å which is shorter than C-O bonds in noncyclic tertiary amides.[2]
Penams are strained due to the angle strain on the four-member β-lactam ring, whose internal bond angles are 90º.[3] Consequently, penams are susceptible to acid- and base-catalyzed hydrolysis.