Chapter 3 – Making Light Work in Biology 95
muscle-based molecular motors. Here, F-actin filaments of several microns in length are
conjugated with the fluorescent dye rhodamine and can be observed using TIRF in excep
tional detail to undergo active diffusion on a microscope coverslip surface coated with the
protein myosin in the presence of ATP due to the interaction between the molecular motor
region of the myosin head domain with its F-actin track, as occurs in vivo in muscle, fueled
by chemical energy from the hydrolysis of ATP (the theoretical model of this motor trans
location behavior is discussed in Chapter 8).
KEY POINT 3.3
TIRF is one of the most widely utilized biophysical tools for studying dynamic bio
logical processes on, or near to, surfaces. It offers exceptional contrast for single-
molecule detection and can be combined with a variety of different biophysical
techniques, such as electrical measurements.
Delimitation of light excitation volumes can also be achieved through the use of waveguides.
Here, light can be guided through a fabricated optically transparent material, such as glass, to
generate a supercritical angle of incidence between the waveguide surface and a physiological
buffer containing a fluorescently labeled biological sample. This type of approach can be used
to generate an evanescent field at the tip of an optical fiber, thus allowing fluorescence detec
tion from the end of the fiber. This approach is used in nanophotonics, which enables com
plex shaped evanescent fields to be generated from fabricated waveguides, and has relevance
toward enhancing the contrast of fluorescence detection in microfluidics-based biosensing
devices (see Chapter 7).
3.6.3 �FLUORESCENCE POLARIZATION MICROSCOPY
Fluorescence polarization measurements can be performed by adapting a standard fluor
escence microscope to split the orthogonal emission polarization onto either two separate
cameras, or potentially onto two halves of the same camera pixel array in a similar manner
to splitting the fluorescence emissions on the basis of wavelength except using a polarization
splitter optic instead of a dichroic mirror. Typically, the incident E-field polarization is fixed
and linear, but as discussed in the previous section, standard epifluorescence illumination is
suitable since it results in excitation polarization parallel to the microscope coverslip or slide.
It is also possible to apply polarization microscopy using TIRF illumination. If the incident
light onto the glass–water interface is purely s-polarized, then the polarization orientation
will be conserved in the evanescent excitation. However, as discussed, useful information
can also be obtained by using p-polarized excitation light for TIRF, that is, p-TIRF. Here, the
polarization vector is predominantly normal to the glass–water interface, and so has applica
tion in monitoring fluorophores whose electric dipoles axes are constrained to be normal to a
microscope coverslip; an example of such is for voltage-sensitive membrane-integrated dyes.
The cartwheeling polarization vector of the p component of the evanescent excitation
field in the general case of supercritical angle TIRF results in a well-characterized spatial
periodicity of a few hundred nanometers. This is a comparable length scale to some localized
invaginations in the cell membrane called “caveolae” that may be involved in several different
biological processes, such as environment signal detection, and how large particles enter
eukaryotic cells including food particles through the process of endocytosis, how certain
viruses infect cells, as well as how particles are secreted from eukaryotes through the pro
cess of exocytosis (see Chapter 2). Using specialized membrane-permeable fluorescent dyes
that orient their electric dipole axis perpendicular to the phospholipid bilayer plane of the
cell membrane, p-polarization excitation TIRF microscopy can be used to image the spa
tial architecture of such localized membrane invaginations (Hinterdorfer et al., 1994; Sund
et al., 1999).