2014
DOI: 10.1021/jz501874f
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The Power of Two: Covalent Coupling of Photostabilizers for Fluorescence Applications

Abstract: Fluorescence is a versatile tool for spectroscopic investigations and imaging of dynamic processes and structures across various scientific disciplines. The photophysical performance, that is, signal stability and signal duration, of the employed fluorophores is a major limiting factor. In this Letter, we propose a general concept to covalently link molecules, which are known for their positive effect in photostabilization, to form a combined photostabilizer with new properties. The direct linkage of two (or m… Show more

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Cited by 39 publications
(74 citation statements)
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“…The GOX-buffer system in Figure 2 and 3 contains 200 µM TCEP, which was added for enzyme stability. In agreement with previously published results 15,16,19 , we found an improvement of photophysical parameters in the presence of solution additives or when comparing unmodified fluorophores with their NPA-or COT-conjugates as shown in Figure 3. This included increased photobleaching lifetimes, signal-to-noise ratio, count-rates and total number of collected photons, and can be attributed to the depopulation of the dark triplet-state (Figure 3a-c and Figure S1-S17).…”
Section: Resultssupporting
confidence: 93%
See 1 more Smart Citation
“…The GOX-buffer system in Figure 2 and 3 contains 200 µM TCEP, which was added for enzyme stability. In agreement with previously published results 15,16,19 , we found an improvement of photophysical parameters in the presence of solution additives or when comparing unmodified fluorophores with their NPA-or COT-conjugates as shown in Figure 3. This included increased photobleaching lifetimes, signal-to-noise ratio, count-rates and total number of collected photons, and can be attributed to the depopulation of the dark triplet-state (Figure 3a-c and Figure S1-S17).…”
Section: Resultssupporting
confidence: 93%
“…These are generated by either addition of the photostabilizer to the imaging buffer at millimolar concentrations 2,3,10,13 to allow diffusional intermolecular quenching (Figure 1a), or via covalent linkage, i.e., to create high local concentrations of the photostabilizer (Figure 1b). [14][15][16][17][18][19][20] Figure 1. Methods to create collisions between photostabilizer and reactive fluorophore state (here triplet-state T1) using intermolecular diffusional quenching (a) or intramolecular processes (b).…”
Section: Introductionmentioning
confidence: 99%
“…These triplet quenchers both reduce dark states and decrease the rate of photobleaching. 130,131 8C).…”
Section: Approaches To Circumvent Cyanine Photooxidationmentioning
confidence: 99%
“…Vogelsang et al [20] and others [22] carried out their experiments in aqueous solution using a fluorescence microscope. This study aims to apply their findings in DNA microarray experiments, where the cyanine dye is bound to the DNA which itself is fixated on a modified glass slide and is scanned using a microarray slide scanner.…”
Section: Introductionmentioning
confidence: 99%