A Chiral [2+3] Covalent Organic Cage Based on 1,1'-Bi-2-naphthol (BINOL) Units.
Midhun MohanDavid-Jérôme PhamAudrey FluckSimon ChapuisAlain ChaumontBrice KauffmannLaurent BarloyPierre MobianPublished in: Chemistry (Weinheim an der Bergstrasse, Germany) (2024)
A [2+3] chiral covalent organic cage is produced through a dynamic covalent chemistry approach by mixing two readily available building units, viz. an enantiopure 3,3'-diformyl 2,2'-BINOL compound (A) with a triamino spacer (B). The two enantiomeric (R,R,R) and (S,S,S) forms of the cage C are formed nearly quantitatively thanks to the reversibility of the imine linkage. The X-ray diffraction analysis of cage (S,S,S)-C highlights that the six OH functions of the BINOL fragments are positioned inside the cage cavity. Upon reduction of the imine bonds of cage C, the amine cage D is obtained. The ability of the cage D to host the 1-phenylethylammonium cation (EH + ) as a guest is evaluated through UV, CD and DOSY NMR studies. A higher binding constant for (R)-EH + cation (Ka=1.7 10 6 ±10 % M -1 ) related to (S)-EH + (Ka=0.9 10 6 ±10 % M -1 ) is determined in the presence of the (R,R,R)-D cage. This enantiopreference is in close agreement with molecular dynamics simulation.