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principles of fluorescence techniques
april 4-7, 2016 | urbana-champaign, il
Basic Definitions and Principles of Fluorescence
Basic Spectral Properties
Jablonski Diagram and Stokes' shift
Excitation and Emission Spectra
Polarization/Anisotropy
Fluorescence Lifetime
FRET: FÓ§rster Resonance Energy Transfer
Instrumentation
Steady-State Fluorometer
Instrumentation for Time-Resolved Fluorescence
Light Sources for Time-Resolved Fluorometry (lamps, lasers, laser diodes, LEDs, synchrotron radiation)
Detectors (PMT, APD, MCP)
Time-dependent Phenomena (Part I)
Multi-Exponential Decays
Time-Domain Lifetime Measurements
Frequency-Domain Lifetime Measurements
Quenching, Static, Dynamic, Transients
Time-dependent Phenomena (Part II)
Anisotropy Decays
Energy Transfer-Distance Distributions
Time-Dependent Spectral Relaxation
Excited State Reactions
Data Manipulation and Data Analysis
Spectral Manipulation
Least-square Analysis
Global Analysis
Phasor Plots
Analytical Applications of Fluorescence
Advantages of Fluorescence in Chemical Analysis
Examples of Fluorescence Assays
Error Sources in Fluorescence Assays
Methods of Fluorescence Sensing
Lifetime-Based Sensing
Lifetime Sensing and Ratiometric Probes
Confocal Fluorescence Microscopy
Instrumentation
Light Sources: One-photon and Multi-photon Excitation
Applications in Cells
Lifetime Imaging
Fluorescence Fluctuations Spectroscopy (FFS)
FFS in Solutions
FFS in Cells
Single-Molecule Fluorescence
Super-resolution Microscopy
Practical Use of Instrumentation