Chapter 4 – Making Light Work Harder in Biology 121
(to this day, the ability to resolve single-microtubule filaments of a few tens of nanometer
width in a tightly packed filament is treated as a benchmark of the technique), they have also
now developed into powerful cellular imaging tools.
In STED, this reduction in laser excitation volume is achieved using a second stimulated
emission laser beam in addition to an excitation beam, which is shaped like a donut in the focal
plane with a central intensity minimum of width ~200 nm. This annulus intensity function
can be generated using two offset beams or by phase modulation optics (Figure 4.2a).
This beam has a longer wavelength than the laser excitation beam and stimulates emission
from the fluorescence excited state (Figure 4.2b), resulting in the depletion of the excited state
in the high-intensity region of the donut, but a nondepleted central region whose volume is
much smaller than the original PSF. In STED, it is now standard to reduce the width w of
the excitation volume in the sample plane to <100 nm, which, assuming an objective lens of
numerical aperture NA, is given by
(4.6)
w
NA
I Is
=
+
λ
2
1
/
FIGURE 4.2 Stimulated-emission depletion microscopy (STED) and Förster resonance energy transfer (FRET). (a) Relative
sizes and shapes of STED depletion beam and original PSF of a fluorophore; the donut-shaped depletion beam stimulates
emission depletion from the fluorophore to generate a much smaller point spread function intensity volume, with (b) the
associated Jablonski energy level diagram indicated. (c) Schematic depiction of FRET, here, indicated between a donor
and acceptor fluorescent protein, which are excited by short and long light wavelengths respectively, with (d) associated
Jablonski energy level diagram and (e) schematic indicating the relative orientation of the donor–acceptor fluorophore
electric dipole moment axes; each respective electric dipole axis lies in a one of two planes separated by angle θT, and
these two planes intersect at a line defined by arrow indicated that makes angles θA and θD with the acceptor and donor
electric dipole axes, respectively.