Fluorescence changes in carbon nanotube sensors correlate with THz absorption of hydration

Nalige, Sanjana S.; Galonska, Phillip; Kelich, Payam; Sistemich, Linda; Herrmann, Christian; Vukovic, Lela; Kruss, Sebastian; Havenith, Martina

Fluorescence changes in carbon nanotube sensors correlate with THz absorption of hydration

Sanjana S. Nalige, Phillip Galonska, Payam Kelich, Linda Sistemich, Christian Herrmann, Lela Vukovic, Sebastian Kruss () and Martina Havenith ()
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Sanjana S. Nalige: Ruhr University Bochum
Phillip Galonska: Ruhr University Bochum
Payam Kelich: University of Texas at El Paso
Linda Sistemich: Ruhr University Bochum
Christian Herrmann: Ruhr University Bochum
Lela Vukovic: University of Texas at El Paso
Sebastian Kruss: Ruhr University Bochum
Martina Havenith: Ruhr University Bochum

Nature Communications, 2024, vol. 15, issue 1, 1-8

Abstract: Abstract Single wall carbon nanotubes (SWCNTs) functionalized with (bio-)polymers such as DNA are soluble in water and sense analytes by analyte-specific changes of their intrinsic fluorescence. Such SWCNT-based (bio-)sensors translate the binding of a molecule (molecular recognition) into a measurable optical signal. This signal transduction is crucial for all types of molecular sensors to achieve high sensitivities. Although there is an increasing number of SWCNT-based sensors, there is yet no molecular understanding of the observed changes in the SWCNT’s fluorescence. Here, we report THz experiments that map changes in the local hydration of the solvated SWCNT upon binding of analytes such as the neurotransmitter dopamine or the vitamin riboflavin. The THz amplitude signal serves as a measure of the coupling of charge fluctuations in the SWCNTs to the charge density fluctuations in the hydration layer. We find a linear (inverse) correlation between changes in THz amplitude and the intensity of the change in fluorescence induced by the analytes. Simulations show that the organic corona shapes the local water, which determines the exciton dynamics. Thus, THz signals are a quantitative predictor for signal transduction strength and can be used as a guiding chemical design principle for optimizing fluorescent biosensors.

Date: 2024
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DOI: 10.1038/s41467-024-50968-9

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