Before fluorescence sensing techniques can be applied to media as delicate and complicated as human tissue, an adequate interpretation of the measured observables is required, i.e., an inverse problem needs to be solved. Recently we have solved the inverse problem relating to the kinetics of fluorescence resonance energy transfer ~FRET!, which clears the way for the determination of the donor–a...

Nanocommunications via Förster Resonance Energy Transfer (FRET) is a promising means of realising collaboration between photoactive nanomachines to implement advanced nanotechnology applications. The method is based on exchange of energy levels between fluorescent molecules by the FRET phenomenon which intrinsically provides a virtual nanocommunication link. In this work, further to the extensi...

Fluorescent resonance energy transfer (FRET) is a powerful technique for studying conformational distribution and dynamics of biological molecules. Some conformational changes are difficult to synchronize or too rare to detect using ensemble FRET. FRET, detected at the single-molecule level, opens up new opportunities to probe the detailed kinetics of structural changes without the need for syn...

extensive small molecule libraries has led to the demand for an increase in both the sensitivity and speed of assays. Increasingly, fluorescence-based assays are becoming the method of choice for high-throughput screening. Here, we describe the properties of a number of reagents developed by Amersham Biosciences for use in timeresolved fluorescence assays based on fluorescence resonance energy ...

Förster resonance energy transfer (FRET) has become an important tool for analyzing different aspects of interactions among biological macromolecules in their native environments. FRET analysis has also been successfully applied to study the spatiotemporal regulation of various cellular processes using genetically encoded FRET-based biosensors. A variety of procedures have been described for me...

The process of radiationless energy transfer from a chromophore in an excited electronic state (the "donor") to another chromophore (an "acceptor"), in which the energy released by the donor effects an electronic transition, is known as "Förster Resonance Energy Transfer" (FRET). The rate of energy transfer is dependent on the sixth power of the distance between donor and acceptor. Determining ...

Among biosensors, genetically-encoded FRET biosensors raised hope to dissect signaling pathways by monitoring enzymatic activities or second messengers levels in living cells and even in living and developing organisms. FRET (Froster resonance Energy Transfer) is a radiationless energy transfer from donor to acceptor fluorophore. For most genetically encoded donor/acceptor pair, this transfer c...

BACKGROUND Time-correlated Förster resonance energy transfer (FRET) probes molecular distances with greater accuracy than intensity-based calculation of FRET efficiency and provides a powerful tool to study biomolecular structure and dynamics. Moreover, time-correlated photon count measurements bear additional information on the variety of donor surroundings allowing more detailed differentiati...

The ability of cells to sense and respond to mechanical forces is central to a wide range of biological processes and plays an important role in numerous pathologies. The molecular mechanisms underlying cellular mechanotransduction, however, have remained largely elusive because suitable methods to investigate subcellular force propagation were missing. Here, we review recent advances in the de...

The development of intravital Förster Resonance Energy Transfer (FRET) is required to probe cellular and tissue function in the natural context: the living organism. Only in this way can biomedicine truly comprehend pathogenesis and develop effective therapeutic strategies. Here we demonstrate and discuss the advantages and pitfalls of two strategies to quantify FRET in vivo-ratiometrically and...