Dye-zeolite nanomaterials are promising candidates for neurotransmitter detection, however, their sensing mechanism has remained speculative. Using ab initio molecular dynamics (AIMD) simulations, we demonstrate that water molecules play a critical role in stabilizing complexes formed between the dicationic dye and cationic neurotransmitters within the zeolite framework. This interaction exhibits binding motifs akin to those in protein-ligand complexes rather than conventional host-guest systems. Furthermore, the presence of water significantly modulates the spectroscopic properties of the nanosensor.
Mechanistic insights into water-stabilized dye-neurotransmitter intermolecular complexes in zeolite channels
Invernizzi C.;Fois E.;Tabacchi G.
Ultimo
2025-01-01
Abstract
Dye-zeolite nanomaterials are promising candidates for neurotransmitter detection, however, their sensing mechanism has remained speculative. Using ab initio molecular dynamics (AIMD) simulations, we demonstrate that water molecules play a critical role in stabilizing complexes formed between the dicationic dye and cationic neurotransmitters within the zeolite framework. This interaction exhibits binding motifs akin to those in protein-ligand complexes rather than conventional host-guest systems. Furthermore, the presence of water significantly modulates the spectroscopic properties of the nanosensor.
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