Download Luminiscence

Fluorescence
and
Chemiluminescence
Richard Vytášek 2008
Luminescence
Emission of radiation, which occurs during returning of excitated
molecules to ground state
Fluorescence, phosphorescence – excitation is caused by
absorption of radiation
Chemiluminiscence – excitation is caused by chemical reaction
Other type of luminiscence – e.g. triboluminiscence,
catodoluminiscence, radioluminiscence
Singlet state - spins of two
electrons are paired
E
Triplet state - spins of two
electrons are unpaired
S0
S1
T1
Fluorescence and fosforescence
Energy level diagram for photoluminescent molecules
Radiationless transitions:
VR –vibrational relaxation
IC- internal conversion
ISC –intersystem crossing
E
Radiation transitions:
Fluorescence - transition to the ground state with the same multiplicity S1S0
probability of fluorescence is higher than phosphorescence
Phosphorescence – transition between states with different multiplcity T1S0
Stokes´ shift
Wavelength difference between absorption
(excitation) and fluorescence (emission)
maximum
Wavelength of emitted radiation
is longer because its energy is
lower
E = h . c/
Stokes´ shift

http://psych.lf1.cuni.cz/fluorescence/soubory/principy.htm
Quantitative fluorescent measurement
I0
sample
If
It
f =
Ia = I0 - It
intensity of fluorescence
If
intensity of absorption
Ia
=
Fluorescence efficiency (f ) is the fraction of the incident
radiation which is emitted as fluorescence f < 1
If = f .Ia = f (I0 - It)
If = f .I0(1- 10
It = I0 .10-ecd
-ecd
)
ecd < 0,01  10-ecd  ln10.(1- ecd)
If = 2,3.f.e.d.c = .c
The dependence of intensity of fluorescence
to concentration of fluorophore
Fluorescence measurement
Filter fluorimeters
Spectrofluorometers
Fluorescent microscopes
Fluorescent scanners
Flow cytometry
source
excitation
monochromator
sample
emission
monochromator
detector
Read-out
Sources of interference
Inner filter effect
intensity of excitation light isn´t constant because each
layer of the sample absorbs some of the incident
radiation (intensity of exciting light is higher in the
front part of cuvette and lower in the rear part of
cuvette
Quenching
excited molecule returns to the ground state by
radiationless transition (without emitting light) as a
result of a collision with quenching molecule
Quenching agents: O2, halogens (Br, I),
nitrocompounds
Methods of fluorescence
determination
Direct methods - natural fluorescence of the
fluorecent sample is measured
Indirect (derivatisation) methods - the
nonfluorescent compound is converted into a
fluorescent derivative by specific reaction or
marked with fluorescent dye by attaching dye to
the studied substance
Quenching methods - analytical signal is the
reduction in the intensity of some fluorescent dye
due to the quenching action of the measured
sample
Natural fluorophores
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Lanthanides
Polyaromatic hydrocarbons
Vitamin A, E
Coenzymes (FAD, FMN, NADH)
Carotenes
Quinine
Steroids
Aromatic aminoacids
Nucleotides
Fluorescent proteins –GFP (green fluorescent protein)
Nobel prize in chemistry in 2008
Osamu Shimomura discovered green fluorescent protein (GFP) in the small
glowing jellyfish Aequorea victoria
Martin Chalfie introduced using of green fluorescent protein as a marker for
gene expression
Roger Y. Tsien engineered different mutants of GFP with new optical
properties (increased fluorescence, photostability and a shift of the major
excitation peak ) and contributed to the explanation of mechanismus of GFP
fluorescence
Fluorescent probes
Compounds whose fluorescence doesn´t change after their
interaction with biological material
acridine orange (DNA)
fluorescein (proteins)
rhodamine (proteins)
GFP
Compounds whose fluorescence change according to their
environment
ANS (1-anilinonaftalen-8- sulphonate) - polarity
Fura-2 - tracking the movement of calcium within cells
Some applications of fluorescence
detection
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Protein conformation
Membrane potential
Membrane transport
Membrane viscosity
Enzymatic reactions
DNA analysis
Genetic engineering (manipulations)
Immunochemical methods
Cell proliferation and apoptosis
Chemiluminiscence
Luminol and
peroxidase before
adding H2O2
Chemiluminiscence
after addition H2O2
Chemiluminescence
• Excitation of electrons is caused by chemical
reaction
• Return to ground state is accompanied by light
emission
Bioluminescence
firefly
Noctiluca scintillans
ATP + luciferin + O2
luciferase
AMP + PPi + CO2 + H2O + oxyluciferin + light
Application of
chemiluminescence detection
• NO assay
NO + O3  NO2* + O2
NO2*  NO2 + light
• H2O2 assay, peroxidase activity assay, immunochemical
assays
Luminol + H2O2
peroxidase
3-aminoftalate + light
Thank you for your attention