120 4.2 Super-Resolution Microscopy
membrane-localized protein to generate super-resolution cell membrane features in a tech
nique described as super-resolution by power-dependent active intermittency and points
accumulation for imaging in nanoscale topography (SPRAIPAINT) (Lew et al., 2011).
Dye blinking of organic dyes has also been utilized in a technique called “blinking assisted
localization microscopy” (Burnette et al., 2011). This should not be confused with binding-
activated localization microscopy, which utilizes a fluorescence enhancement of a dye when
bound to certain cellular structures such as nucleic acids compared to being free in solution,
which can be optimized such that the typical nearest-neighbor distance is greater than the
optical resolution limit (Schoen et al., 2011). Potential advantages over PALM/STORM of
blinking localization microscopy are that the sampling time scales are faster and also that
there is less photodamage to living cells in avoiding the more damaging shorter wavelength
used in UV-based activation.
Improvements to localization microscopy precision can be made using prior information
concerning the photophysics of the dyes, resulting in a hybrid technique of analytical infer
ence with standard localization tools such as PALM/STORM. Bayesian analysis is an ideal
approach in this regard (discussed fully in Chapter 8). This can be applied to photoblinking
and photobleaching observations trained on prior knowledge of both. Bayesian blinking and
bleaching microscopy (3B microscopy) analyzes data in which many overlapping fluorophores
undergo both bleaching and blinking events to generate spatial localization information at
enhanced resolution. It uses a hidden Markov model (HMM). An HMM assumes that the
underlying process is a Markov process (meaning future states in the system depend only on
the present state and not on the sequence of events that preceded it, i.e., there is no memory
effect) but with unobserved (hidden) states and is often used in Bayesian statistical analysis
(see Chapter 8). It enables information to be obtained that would be impossible to extract
with standard localization microscopy methods.
The general issue of photodamage with fluorescence imaging techniques should be viewed
in the following context:
1 All imaging of live cells with fluorescence (and many other modalities) is potentially
damaging, for example, fast confocal scanners often kill a muscle cell in seconds. That
is, however, acceptable, for certain experiments where we are looking at fast biological
processes (e.g., a few milliseconds) and the mindful biologist builds in careful control
experiments to make sure they can put limits on these effects.
2 The degree of damage seen is likely closely connected to the amount of information
derived but can be reduced if light dosage is reduced using hybrid approaches such as
3B microscopy. Some spatial resolution is inevitably sacrificed for time resolution and
damage reduction—nothing is for free.
3 Many dark molecules in photoactivating super-resolution methods greatly reduce
absorption in the sample, and the UV exposure to photoactivate is generally very low.