Selective detection of catecholamines by synthetic receptors embedded in chromatic polydiacetylene vesicles.

A new detection scheme for catecholamines was constructed through embedding synthetic receptors within vesicles comprising phospholipids and polydiacetylene. Fluorescence emission of the polydiacetylene was induced through specific interactions between the soluble ligands and the vesicle-incorporated hosts. The system demonstrated remarkable selectivity among structurally similar ligands and achieved much lower detection thresholds compared to that of other reported catecholamine sensors.

Towards synthetic adrenaline receptors--shape-selective adrenaline recognition in water.

In spite of their key role in signal transduction, the mechanism of action of adrenergic receptors is still poorly understood. We have imitated the postulated binding pattern of the large membrane protein with a small, rationally designed synthetic host molecule. Experimental evidence is presented for the simultaneous operation of electrostatic attraction, hydrogen bonds, pi stacking, and hydrophobic interactions.

Towards Synthetic Adrenaline Receptors-Shape-Selective Adrenaline Recognition in Water.

A new rationally designed receptor molecule binds adrenaline derivatives in water. Its binding pattern imitates the interplay of noncovalent interactions operating in the natural receptor. High shape selectivity is achieved for the slim dopamine skeleton, and leads to rejection of substrates with an α-substituent, such as amino acid derivatives.