Analyzing the Distribution of Decay Constants in Pulse-Fluorimetry Using the Maximum Entropy Method

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Analyzing the Distribution of Decay Constants in Pulse-Fluorimetry Using the Maximum Entropy Method

A. K. Livesey and J. C. Brochon

ABSTRACT

The maximum entropy method (MEM) is used to analyze time-resolvedpulse-fluorescence spectrometry. The central problem in suchanalyses is the recovery of the distribution of exponentialsdescribing the decay of the fluorescence (i.e., inverting theLaplace transform) which is, in turn, convolved by the shapeof the excitation flash. MEM is shown to give high quality resultsfrom both computer-generated "noisy" data and experimental datafrom chemical and biological molecules.

The use of the Shannon-Jaynes entropy function is justifiedand both the theoretical and practical advantages of MEM arepresented. The MEM results are easy to interpret and can helpto overcome some experimental limitations. In particular MEMcould be a powerful tool to analyze the heterogeneity of fluorescentemission of biological macromolecules which can be correlatedwith their conformational dynamics in solution.

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