362 8.4 Reaction, Diffusion, and Flow
slow slippage in a microscope stage, or thermal expansion effects, which are obviously then
simply experimental artifacts and need to be corrected prior to diffusion analysis.
In the case of inhomogeneous fluid environments, for example, the mean square displacement
of a particle after time interval τ as ~ τα (see Equation 4.18) where a is the anomalous diffusion
coefficient and 0 < α < 1, which depends on factors such as the crowding density of obstacles to
diffusion in the fluid environment. Confined diffusion has a typically asymptotic shape with τ.
In practice, however, real experimental tracking data of diffusing particles are intrinsically
stochastic in nature and also have additional source of measurement noise, which complicates
the problem of inferring the mode of diffusion from the shape of the mean square displace
ment relation with τ. Some experimental assays involve good sampling of the position of
tracked diffusing biological particles. An example of this is a protein labeled with a nanogold
particle in an in vitro assay involving a similar viscosity environment using a tissue mimic
such as collagen to that found in the living tissue. The position of the nanogold particle can
be monitored as a function of time using laser dark-field microscopy (see Chapter 3). The
scatter signal from the gold tag does not photobleach, and so they can be tracked for long
durations allowing a good proportion of the analytical mean square displacement relation to
be sampled thus facilitating inference of the type of underlying diffusion mode.
However, the issue of using such nanogold particles is that they are relatively large (tens of
nm diameter, an order of magnitude larger than typical proteins investigated) as a probe and
so potentially interfere sterically with the diffusion process, in addition to complications with
extending this assay into living cells and tissue due to problems of specific tagging of the right
protein and its efficient delivery into cells. A more common approach for live-cell assays is
to use fluorescence microscopy, but the primary issue here is that the associated tracks can
often be relatively truncated due to photobleaching of the dye tag and/or diffusing beyond
the focal plane resulting in tracked particles going out of focus.
Early methods of mean square displacement analysis relied simply on determining a
metric for linearity of the fit with respect to time interval, with deviations from this indi
cative of diffusion modes other than regular Brownian. To overcome issues associated with
noise on truncated tracks, however, improved analytical methods now often involve aspects
of Bayesian inference.
KEY POINT 8.8
The principle of Bayesian inference is to quantify the present state of knowledge and
refine this on the basis of new data, underpinned by Bayes’ theorem, emerging from the
definition of conditional probabilities. It is one of the most useful statistical theorems
in science.
In words, Bayes’ theorem is simply posterior = (likelihood × prior)/evidence.
The definitions of these terms are as follows, which utilizes statistical nomenclature of the
conditional probability “P(A|B)” meaning “the probability of A occurring given that B has
occurred.” The joint probability for both events A and B occurring is written as P(A∩B). This
can be written as the probability of A occurring given that B has occurred:
(8.93)
P A
B
P B
P A B
∩
(
) =
( )⋅(
| )
But similarly, this is the same as the probability of B occurring given that A has occurred:
(8.94)
P A
B
P A
P B A
∩
(
) =
( )⋅( |
)
Thus, we can arrive at a more mathematical description of Bayes’ theorem, which is
(8.95)
P A B
P B A P A
P B
(
| )
( |
)
=
⋅( )
( )