Force-Induced Shuttling of Rotaxanes Controls Fluorescence Resonance Energy Transfer in Polymer Hydrogels.
Tatsuya MuramatsuShohei ShimizuJessica M CloughChristoph WederYoshimitsu SagaraPublished in: ACS applied materials & interfaces (2023)
The molecular shuttling function of rotaxanes can be exploited to design mechanoresponsive reporter molecules. Here, we report a new approach to such rotaxane-based mechanophores, in which the fluorescence resonance energy transfer (FRET) between a donor-acceptor pair is mechanically controlled. A cyclic molecule containing a green-light-emitting FRET donor connected to a red-light-emitting FRET acceptor was threaded onto an axle equipped with a quencher at its center and two stoppers in the peripheral positions. In the force-free state, the green emitter is located near the quencher so that charge transfer interactions or photo-induced electron transfer between the two moieties suppress green emission and prevent the FRET from the green to the red emitter. The mechanophore was covalently incorporated into a linear polyurethane-urea (PUU), and stretchable hydrogels were prepared by swelling this polymer with water. Upon deformation of the PUU hydrogels and under an excitation light that selectively excites the donor, the intensity of the red fluorescence increases, as a result of a force-induced separation of the green emitter from the quencher, which enables the FRET. The switching contrast is much more pronounced in the gels than in dry films, which is due to increased molecular mobility and hydrophobic effects in the hydrogel, which both promote the formation of inclusion complexes between the ring containing the green emitter and the quencher.
Keyphrases
- energy transfer
- light emitting
- single molecule
- quantum dots
- high glucose
- drug delivery
- diabetic rats
- hyaluronic acid
- electron transfer
- tissue engineering
- wound healing
- endothelial cells
- drug release
- drug induced
- extracellular matrix
- magnetic resonance
- crispr cas
- computed tomography
- ionic liquid
- stress induced
- neural network
- contrast enhanced