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Light-controlled micron-scale molecular motion

2021; Nature Portfolio; Volume: 13; Issue: 12 Linguagem: Inglês

10.1038/s41557-021-00791-2

1755-4349

Mario Samperi, Bilel Bdiri, Charlotte D. Sleet, Róbert Márkus, Ajith R. Mallia, Lluïsa Pérez‐García, David B. Amabilino,

Lipid Membrane Structure and Behavior

The micron-scale movement of biomolecules along supramolecular pathways, mastered by nature, is a remarkable system requiring strong yet reversible interactions between components under the action of a suitable stimulus. Responsive microscopic systems using a variety of stimuli have demonstrated impressive relative molecular motion. However, locating the position of a movable object that travels along self-assembled fibres under an irresistible force has yet to be achieved. Here, we describe a purely supramolecular system where a molecular ‘traveller’ moves along a ‘path’ over several microns when irradiated with visible light. Real-time imaging of the motion in the solvated state using total internal reflection fluorescence microscopy shows that anionic porphyrin molecules move along the fibres of a bis-imidazolium gel upon irradiation. Slight solvent changes mean movement and restructuring of the fibres giving microtoroids, indicating control of motion by fibre mechanics with solvent composition. The insight provided here may lead to the development of artificial travellers that can perform catalytic and other functions. In biological systems, controlled molecular motion along a particular path is realized by protein motors that travel along microtubule filaments. Now, control of motion with light has been achieved in a synthetic supramolecular system, in which anionic porphyrin molecules move along the fibres of a bis-imidazolium gel upon irradiation.