TY - JOUR
T1 - A modified phasor approach for analyzing time-gated fluorescence lifetime images
AU - Fereidouni, F.
AU - Esposito, A.
AU - Blab, G.
AU - Gerritsen, H.C.
PY - 2011
Y1 - 2011
N2 - Fluorescence lifetime imaging is a versatile tool that permits
mapping the biochemical environment in the cell. Among
various fluorescence lifetime imaging techniques, timecorrelated
single photon counting and time-gating methods
have been demonstrated to be very efficient and robust for the
imaging of biological specimens.
Recently, the phasor representation of lifetime images became
popular because it provides an intuitive graphical view of
the fluorescence lifetime content of the images and, when
used for global analysis, significantly improves the overall
S/N of lifetime analysis. Compared to time-correlated single
photon counting, time gating methods can provide higher
count rates (∼10 MHz) but at the cost of truncating and
under sampling the decay curve due to the limited number
of gates commonly used. These limitations also complicate
the implementation of the phasor analysis for time-gated
data. In this work, we propose and validate a theoretical
framework that overcomes these problems. This modified
approach is tested on both simulated lifetime images and on
cells.We demonstrate that this method is able to retrieve two
lifetimes from time gating data that cannot be resolved using
standard (non-global) fitting techniques. The new approach
increases the information that can be obtained from typical
measurements and simplifies the analysis of fluorescence
lifetime imaging data.
AB - Fluorescence lifetime imaging is a versatile tool that permits
mapping the biochemical environment in the cell. Among
various fluorescence lifetime imaging techniques, timecorrelated
single photon counting and time-gating methods
have been demonstrated to be very efficient and robust for the
imaging of biological specimens.
Recently, the phasor representation of lifetime images became
popular because it provides an intuitive graphical view of
the fluorescence lifetime content of the images and, when
used for global analysis, significantly improves the overall
S/N of lifetime analysis. Compared to time-correlated single
photon counting, time gating methods can provide higher
count rates (∼10 MHz) but at the cost of truncating and
under sampling the decay curve due to the limited number
of gates commonly used. These limitations also complicate
the implementation of the phasor analysis for time-gated
data. In this work, we propose and validate a theoretical
framework that overcomes these problems. This modified
approach is tested on both simulated lifetime images and on
cells.We demonstrate that this method is able to retrieve two
lifetimes from time gating data that cannot be resolved using
standard (non-global) fitting techniques. The new approach
increases the information that can be obtained from typical
measurements and simplifies the analysis of fluorescence
lifetime imaging data.
U2 - 10.1111/j.1365-2818.2011.03533.x
DO - 10.1111/j.1365-2818.2011.03533.x
M3 - Article
SN - 0022-2720
VL - 244
SP - 248
EP - 258
JO - Journal of Microscopy
JF - Journal of Microscopy
IS - 3
ER -