Imaging protein molecules using FRET and FLIM microscopy
H Wallrabe, A Periasamy - Current opinion in biotechnology, 2005 - Elsevier
Current opinion in biotechnology, 2005•Elsevier
Förster (or fluorescence) resonance energy transfer (FRET) and fluorescence lifetime
imaging (FLIM) have moved center stage and are increasingly forming part of multifaceted
imaging approaches. They are complementary methodologies that can be applied to
advanced quantitative analyses. The widening application of FRET and FLIM has been
driven by the availability of suitable fluorophores, increasingly sophisticated microscopy
systems, methodologies to correct spectral bleed-through, and the ease with which FRET …
imaging (FLIM) have moved center stage and are increasingly forming part of multifaceted
imaging approaches. They are complementary methodologies that can be applied to
advanced quantitative analyses. The widening application of FRET and FLIM has been
driven by the availability of suitable fluorophores, increasingly sophisticated microscopy
systems, methodologies to correct spectral bleed-through, and the ease with which FRET …
Förster (or fluorescence) resonance energy transfer (FRET) and fluorescence lifetime imaging (FLIM) have moved center stage and are increasingly forming part of multifaceted imaging approaches. They are complementary methodologies that can be applied to advanced quantitative analyses. The widening application of FRET and FLIM has been driven by the availability of suitable fluorophores, increasingly sophisticated microscopy systems, methodologies to correct spectral bleed-through, and the ease with which FRET can be combined with other techniques. FRET and FLIM have recently found use in several applications: in the analysis of protein–protein interactions with high spatial and temporal specificity (e.g. clustering), in the study of conformational changes, in the analysis of binding sequences, and in applications such as high-throughput screening.
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