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Biophys J, September 2001, p. 1265-1274, Vol. 81, No. 3
and
*Department of Physics, Imperial College of Science, Technology,
and Medicine, London SW7 2BW, and Department of
Biological and Medical Systems, Imperial College of Science,
Technology, and Medicine, London SW7 2BY, United Kingdom
Conventional analyses of fluorescence lifetime
measurements resolve the fluorescence decay profile in terms of
discrete exponential components with distinct lifetimes. In complex,
heterogeneous biological samples such as tissue, multi-exponential
decay functions can appear to provide a better fit to fluorescence
decay data than the assumption of a mono-exponential decay, but the
assumption of multiple discrete components is essentially arbitrary and
is often erroneous. Moreover, interactions, both between fluorophores and with their environment, can result in complex fluorescence decay
profiles that represent a continuous distribution of lifetimes. Such
continuous distributions have been reported for tryptophan, which is
one of the main fluorophores in tissue. This situation is better
represented by the stretched-exponential function (StrEF). In this
work, we have applied, for the first time to our knowledge, the StrEF
to time-domain whole-field fluorescence lifetime imaging (FLIM),
yielding both excellent tissue contrast and goodness of fit using data
from rat tissue. We note that for many biological samples for which
there is no a priori knowledge of multiple discrete exponential
fluorescence decay profiles, the StrEF is likely to provide a truer
representation of the underlying fluorescence dynamics. Furthermore,
fitting to a StrEF significantly decreases the required processing
time, compared with a multi-exponential component fit and typically
provides improved contrast and signal/noise in the resulting FLIM
images. In addition, the stretched-exponential decay model can provide
a direct measure of the heterogeneity of the sample, and the resulting
heterogeneity map can reveal subtle tissue differences that other
models fail to show.
Biophys J, September 2001, p. 1265-1274, Vol. 81, No. 3
© 2001 by the Biophysical Society 0006-3495/01/09/1265/10 $2.00
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