phospholipid molecules can be calculated. Similarly, membrane proteins such as receptors
or even proteins in a cell can be conjugated to fluorescence labels and their diffusion
coefficients can be determined.Fluorescence polarisation
A light source usually consists of a collection of randomly oriented emitters, and the
emitted light is a collection of waves with all possible orientations of theEvectors
(non-polarised light). Linearly polarised light is obtained by passing light through a
polariser that transmits light with only a single plane ofpolarisation; i.e. it passes
only those components of theEvector that are parallel to the axis of the polariser
(Fig. 12.14). The intensity of transmitted light depends on the orientation of the
polariser. Maximum transmission is achieved when the plane of polarisation is
parallel to the axis of the polariser; the transmission is zero when the orientation is
perpendicular. The polarisationPis defined asP¼IlI$
IlþI$ð 12 : 7 ÞIlandI$are the intensities observed parallel and perpendicular to an arbitrary axis.
The polarisation can vary between1 andþ1; it is zero when the light is unpolarised.
Light with 0<|P|<0.5 is called partially polarised.(b)O 2 N
CH 3
OOO
OOO O–
OPO
NNNH+Observation
area under
microscope(a)
Initial situation
restoredBleach dye with
focussed
laser beamMore and more
labelled PLs diffuse
into observation areaDye irreversibly
damaged, no
fluorescence
emissionDetermination of diffusion coefficients
between 10–6and 10–12cm^2 s–1It 0 t1/2 tFluorescence
emission
monitored with
‘weak’ incident
beamFig. 12.13(a) Schematic of a FRAP experiment. Time-based monitoring of fluorescence emission intensity
enables determination of diffusion coefficients in membranes. (b) A commonly used fluorescence label in membrane
FRAP experiments: chemical structure of phosphatidylethanolamine conjugated to the fluorophore NBD.504 Spectroscopic techniques: I Photometric techniques