ones appear
o a), d) and
ification of
yetween the
k specimen
layer a loss
| a standard
rge number
ited fraction
o for a stack
ally for fine
numb it is
) and e) are
b), but are
20pm and
ve, (20% for
ss than 5%
umes under
caning at all
almost none,
: magnitude,
anged. This
ion behavior
legrade the
unted for, if
A general
udo-coded as
n mean &
ngth)
itation)
)6
(scatter, attenuation, bleach, excitation);
UpDateCounters
(scatter, attenuation, bleach, excitation);
AmplifyImageDataBy
(scatter, attenuation, bleach, excitation);
Adjust
(PSF)
END
This reconstruction algorithm fails due to the
unavailability of the required data and due to
the enormous computational effort which is
needed for each UpDateCounters operation.
Each update step comsumes computations
proportional to the number of voxels in the
image data set.
Consequently QUASIA3D solves the
reconstruction problem with two different
approaches. The first one implements efficient
models and simplifications for the various
effects in order to complete the restoration
process in an acceptable amount of time.
The second task is to measure the missing
parameters needed for the restoration.
QUASIA3D implements a 3 stage model to
gather these data sets:
1) The parameters of the confocal microscope
such as wavelength sensitivity, focal spot
geometry, PSF and objective features like
distortion and local brightness response are
collected via the sampling of phantom
specimens.
2) Dye properties are measured with the help of
pure solutions. Excitation attenuation and
bleaching sensitivity are estimated. To gauge
the bleaching sensitivity as a function of
temperature and pH (environmental
influence), the specimens have to be
prepared accordingly. In a standard setup,
the temperature is kept constant and
therefore no temperature dependency has to
be known.
317
3) Specimen properties are very difficult to
separate in a microscope. If no external
devices can be applied to distinguish
between scattering — and attenuation,
experiments with fluorescent microspheres
of precisely known shape have to be
performed. The scattering effect shows
frequency proportional strength. Thus
scanning with different wavelength allows to
differentiate between spherical aberration
and the scattering effects. Attenuation
versus scattering and aberration can be
discriminated through the use of different
aperture sizes. With high apertures
attenuation becomes a more dominant effect.
For a standard setup, no discrimination at all
is required. The mixture of aberration,
scattering and attenuation may be unified in
an absorption term, which is typical for one
excitation wavelength and one tissue type.
QUASIA3D uses this approach to build up
its specimen database. Various image
segmentation algorithms support the user in
identifying the different tissues and gather
absorption data for these in a semi-automatic
way.
Obviously QUASIA3D is neither interactive
nor thoroughly automated. The calibration
procedures are semi-interactive in the sense that
the operator must identify a set of representative
specimen samples for the 3rd stage, but the
reconstruction process runs without interaction
solely based on the acquired data. This is very
desirable, since the execution time for a
reconstruction of an extended image stack takes
up to 15 minutes - despite of all speed-up
algorithms.
6. RESULTS
Worst case mathematical simulations which
take all discussed effects (including cover
glasses related) into account predict a 34% error
bound for the acctual dye concentration
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B5. Vienna 1996
