论文信息 - Use of steady-state fluorescence anisotropy with pebble nanosensors for chemical analysis

Use of steady-state fluorescence anisotropy with pebble nanosensors for chemical analysis

In this study we show that steady-state fluorescence anisotorpy within PEBBLEs can be used for the optochemical sensing of analytes such as Zn2+, O2, and Ca2+. Steady-state fluorescence anisotropy is a non- time resolved method that measures a combination of rotational and fluorescence lifetimes. This eliminates the need for reference dyes and ratiometic techniques to obtain quantitative results, even when using intensity-based sensor dyes. An advantage to working with PEBBLE nanosensors is that the encapsulated dye is localized in a constant rotational environment. This is in contrast to the use of free dyes, which can be affected by interferents such as protein binding.

Eric Monson | Raoul Kopelman | Thomas Horvath | James S. Sumner | Hao Xu

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