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Time-resolved fluorescence (TRF) measurement is very similar to fluorescence intensity (FI) measurement. The only difference is the timing of the excitation / measurement process. When measuring FI, the excitation and emission processes are simultaneous: the light emitted by the sample is measured while excitation is taking place. Even though emission systems are very efficient at removing excitation light before it reaches the detector, the amount of excitation light compared to emission light is such that FI measurements always exhibit fairly elevated background signals. TRF offers a solution to this issue. It relies on the use of very specific fluorescent molecules, called [[lanthanides]], that have the unusual property of emitting over long periods of time (measured in milliseconds) after excitation, when most standard fluorescent dyes (e.g. fluorescein) emit within a few nanoseconds of being excited. As a result, it is possible to excite lanthanides using a pulsed light source (Xenon flash lamp or pulsed laser for example), and measure after the excitation pulse. This results in lower measurement backgrounds than in standard FI assays. The drawbacks are that the instrumentation and reagents are typically more expensive, and that the applications have to be compatible with the use of these very specific lanthanide dyes. The main use of TRF is found in drug screening applications, under a form called [https://dl.dropboxusercontent.com/u/38439599/Tech%20Sheets/Lanthanides/Introduction%20to%20TR-FRET%20assays.pdf TR-FRET (time-resolved fluorescence energy transfer)]. TR-[[Förster resonance energy transfer|FRET]] assays are very robust (limited sensitivity to several types of assay interference) and are easily miniaturized. Robustness, the ability to automate and miniaturize are features that are highly attractive in a screening laboratory.