Chapter 7 – Complementary Experimental Tools 299
7.6.4 �“SMART” SAMPLE MANIPULATION
Several biophysical techniques are facilitated significantly by a variety of automated sample
manipulation tools, which not only increase the throughput of sample analysis but can also
enable high-precision measurements, which would be challenging using other more manual
methods.
Several systems enable robotized manipulation of samples. At the small length scale,
these include automated microplate readers. These are designed to measure typically optical
absorption and/or fluorescence emissions over a range of different wavelengths centered on
the visible light range, but extending into the UV and IR for spectroscopic quantification
similar to traditional methods (see Chapter 3), but here on microliter sample volumes in
each specific microplate well. Several microplate well arrays can be loaded into a machine
and analyzed. In addition, automation also includes incubation and washing steps for the
microplates. At the higher end of the length scale, there are robotic sample processors. These
cover a range of automated fluid pipetting tasks and manipulation of larger-scale sample
vessels such as microfuge tubes, flasks, and agar plates for growing cells. They also include
crystallization robots mentioned in the previous section.
Light microscopy techniques include several tiers of smart automation. These often com
prise user-friendly software interfaces to control multiple hardware such as the power output
of bright-field illumination and lasers for fluorescence excitation. These also include a range
of optomechanical components including shutters, flipper mounts for mirrors and lenses,
stepper motors for optical alignment, and various optical filters and dichroic mirrors.
At the high precision end of automation in light microscopy are automated methods for
controlling sample flow though a microfluidics flow cell, for example, involving switching
rapidly between different fluid environments. Similarly, light microscope stages can be con
trolled using software interfaces. At a coarse level, this can be achieved by attaching stepper
motors to a mechanical stage unit to control lateral and axial (i.e., focusing) movement to
micron precision. For ultrasensitive light microscope applications, nanostages are attached
to the coarse stage. These are usually based on piezoelectric technology (see Chapter 6)
and can offer sub-nanometer precision movements over full-scale deflections up to sev
eral hundred microns laterally and axially. Both coarse mechanical stages and piezoelectric
nanostages can be utilized to feedback on imaging data in real time. For example, pattern
recognition software (see Chapter 8) can be used to identify specific cell types from their
morphology in a low-magnification field of view that can then move the stages automatically
to align individual cells to the center of the field of view for subsequent higher-magnification
investigation.
Long time series acquisitions (e.g., data acquired on cell samples over several minutes,
hours, or even days) in light microscopy are often impaired by sample drift, due either
to mechanical slippage in the stage due to its own weight or to small changes in external
temperatures, resulting in differential thermal expansion/contraction of optomechanical
components, and these benefit from stage automation. Pattern recognition software is suit
able for correcting small changes due to lateral drift (e.g., to identify the same cell, or group
of cells, which have been laterally translated in a large field of view). Axial drift, or focal
drift, is easier to correct by using a method that relies on total internal reflection. Several
commercial “perfect focusing” systems are available in this regard, but the physics of their
application is relatively simple: if a laser beam is directed at a supercritical angle through
the light microscope’s objective lens, then total internal reflection will occur, as is the case
for TIRF (see Chapter 3). However, instead of blocking the emergent reflected beam using
an appropriate fluorescence emission filter, as is the case for TIRF, this can be directed
onto a split photodiode (Figure 7.7). Changes in height of the sample relative to the focal
plane are then manifested in a different voltage response from the split photodiode; these
can feedback via software control into the nanostage to then move the sample back into
the focal plane.
KEY BIOLOGICAL
APPLICATIONS: HIGH-
THROUGHPUT TOOLS
Biosensing; Molecular separation;
High-throughput microscopy.