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Scientists engineer fluorescent molecules that mimic multiphoton behavior

Researchers have created molecular structures that produce the imaging benefits of advanced multiphoton fluorescence using simpler, single-photon light—potentially opening cheaper pathways for high-resolution microscopy and medical imaging. The breakthrough sidesteps the expensive, high-intensity lasers currently required for multiphoton techniques, which could accelerate adoption in diagnostics and life sciences research.

Originaltitel: Molecular Engineering for Nonlinear Fluorescence: En Route to Three-Photon Absorption via Sequential One-Photon Excitation

Abstrakt

Multiphoton excitation (MPE) processes enable three-dimensionally confined fluorescence with reduced background as well as improved image contrast and signal-to-noise ratio. However, MPE finds major technological limitations derived from the need for high light intensities at long excitation wavelengths. To circumvent these challenges, we herein propose a molecular strategy that reproduces multiphoton-like nonlinear responses using only sequential one-photon excitations (1PE). A dyad (2for1), consisting of the acedan fluorophore covalently connected to a spironaphthopyran photoswitch, shows a quadratic dependence of the emission intensity on the excitation intensity, thus emulating a two-photon absorption behavior. The incorporation of a BODIPY photocage to this construct yields a triad (3for1) that results in an even stronger nonlinear fluorescence response. These findings pave the way for sequential 1PE as a practical approach to capitalize on the benefits of nonlinear fluorescence while avoiding the inherent limitations of simultaneous MPE.

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