In order to study
the emergence of homochirality during complex
molecular systems, most works mainly concentrated on the resolution
of a pair of enantiomers. However, the preference of homochiral over
heterochiral isomers has been overlooked, with very limited examples
focusing only on noncovalent interactions. We herein report on diastereomeric discrimination of twin-cavity cages (denoted
as diphanes) against heterochiral tris-(2-aminopropyl)amine
(TRPN) bearing triple stereocenters. This diastereomeric selectivity results from distinct spatial orientation of reactive secondary
amines on TRPN. Homochiral TRPNs with all reactive moieties rotating
in the same way facilitate the formation of homochiral and achiral meso diphanes with low strain energy, while heterochiral
TRPNs with uneven orientation of secondary amines preclude the formation
of cage-like entity, since the virtual diphanes exhibit
considerably high strain. Moreover, homochiral diphanes self-assemble into an acentric superstructure composed of single-handed
helices, which exhibits interesting nonlinear optical behavior. Such
a property is a unique occurrence for organic cages, which thus showcases
their potential to spawn novel materials with interesting properties
and functions.