A dynamic covalent approach to [PtnL2n]2n+ cages.

A dynamic covalent approach was exploited to generate a family of homometallic [PtnL2n]2n+ cage (predominantly [Pt2L4]4+ systems) architectures. The family of platinum(II) architectures were characterized using 1H nuclear magnetic resonance (NMR) and diffusion ordered spectroscopy (DOSY), electrospray ionization mass spectrometry (ESI-MS) and the molecular structures of two cages were determined by X-ray crystallography.

Exploiting reduced-symmetry ligands with pyridyl and imidazole donors to construct a second-generation stimuli-responsive heterobimetallic [PdPtL4]4+ cage.

A new sequential metalation strategy that enables the assembly of a new more robust reduced symmetry heterobimetallic [PdPtL4]4+ cage C is reported. By exploiting a low-symmetry ditopic ligand (L) that features imidazole and pyridine donor units we were able to selectively form a [Pt(L)4]2+ "open-cage" complex. When this was treated with Pd(ii) ions the cage C assembled. 1H and DOSY nuclear magnetic resonance (NMR) spectroscopy and electrospray ionisation mass spectrometry (ESIMS) data were consistent with the quantitative formation of the cage and the heterobimetallic structure was confirmed by single crystal X-ray crystallography. The cage C was shown to bind anionic guest molecules. NMR studies suggested that these guests interacted with the cavity of the cage in a specific orientation and this was confirmed for the mesylate ion (MsO-) : C host-guest adduct using X-ray crystallography. In addition, the system was shown to be stimulus-responsive and could be opened and closed on demand when treated with appropriate stimuli. If a guest molecule was bound within the cage, the opening and closing was accompanied by the release and re-uptake of the guest molecule.

The Biologically Inspired Abilities of Metallosupramolecular Architectures.

Natural machinery such as proteins and enzymes can bind substrates and perform intricate functions on these molecules. This behaviour is mediated by highly ordered but conformationally flexible structures dictated through favourable intra- and intermolecular interactions. Metallosupramolecular architectures (MSAs) function as synthetic machinery that are responsive to their environment, and display similar, but less impressive, abilities to their biological counterparts. Natural and synthetic systems share the properties of molecular recognition and catalysis facilitated through the often complex structures of these architectures. This article outlines efforts to use metallosupramolecular structures to mimic the properties of biological enzymes and machines using important recent examples from the field.