Dynamics of organophosphate guest encapsulation in heteroleptic coordination cages.

Heteroleptic coordination cages allow the design of different host structures that can bind guest molecules within their cavities. In a previous work, the energetics of organophosphate encapsulation in palladium(II)-based heteroleptic coordination cages that differ in terms of their ability to form hydrogen bonds have been investigated [Platzek et al. , Endohedrally Functionalized Heteroleptic Coordination Cages for Phosphate Ester Binding, Angew. Chem., Int. Ed. 2022, 61 , e2022093]. The present work focuses on the dynamics of this system. Dynamic information is obtained through the application of a Markov state model (MSM) to unbiased multi-microsecond atomistic molecular dynamics simulations of guest binding and release. The MSM reveals that both the bound state and the binding/unbinding pathways are highly dynamic, with different types of interactions mediating the binding of the diphenylphosphate guest. Thus, the simulations highlight the dynamic nature of the nanoconfinement in the host-guest systems, with possible implications for the use of such coordination cages as catalysts.