Hydration of neurotransmitters: a computational and spectroscopic study of a noradrenaline analogue, 2-amino-1-phenyl-ethanol

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Singly and multiply hydrated clusters of the noradrenaline analogue, 2-amino-I-phenyl-ethanol (APE) have been studied using a combination of resonant two-photon ionization time of flight spectroscopy (R2PI-TOF), infrared ion-dip spectroscopy and ab initio quantum chemical calculation. Singly hydrated clusters populate two distinct structures: the water molecule either hydrogen-bonds to the ethanol group in the extended AG conformer (leaving the intramolecular OH → N hydrogen bond intact) or inserts into the intramolecular hydrogen bond in the (distorted) ethanolamine side chain (promoting a weak NH → O bond). The observed doubly and triply hydrated clusters both display insertion structures only, with the water molecules arrayed as linear chains, hydrogen bonded to the functional groups of the side-chain and again promoting a weak NH → O bond along the distorted ethanolamine side-chain. The infrared spectrum of the 1:4 cluster of APE, which is very similar to that of the corresponding cluster of ephedrine, includes new features in the ‘window region’ (3500–3700 cm−1), indicating the onset of a three-dimensional assembly. Comparisons with ab initio computed spectra favour a structure that incorporates a cyclic water tetramer linked to the two functional groups on the ethanolamine side-chain.