(343f) Redox Dye-Mediated Fluorescence Energy Transfer of Carbon Nanotube-Based Nanosensors

This study presents the rational design of SWCNT-based nanosensors that leverages the unique properties of methylene blue (MB)-proximity mediated fluorescence quenching. MB-SWCNT based nanosensors exhibit 1- stability in redox environments and 2- analyte-specific displacement-driven fluorescence modulation. By designing hybridization-induced displacement of MB-conjugated ssDNA from the SWCNT surface, we calculate that SWCNT fluorescence modulation can occur within a 6.8 nm fluorescence resonance energy transfer distance from the SWCNT surface, and develop a robust and versatile platform to synthesize oligonucleotide nanosensors with tunable ΔF/F₀ of up to 150% [1]. Building upon this strategy, we developed four distinct nanosensors capable of selectively detecting tobacco mosaic virus (TMV) viral RNA fragments, which successfully differentiated TMV-infected plants from mock controls. Finally, we demonstrate the potential expansion of our design to target a wider scope of biomolecules using the biotin-avidin system as a model. Our work offers a generalizable platform for rational engineering of SWCNT NIR fluorescence intensity through MB distance-dependent fluorescence energy transfer, overcoming the intrinsic selectivity challenges of current SWCNT-based nanosensors.

References

[1] Nishitani et al., Proc. Natl. Acad. Sci. 2025, 122, e2419666122.