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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B5. Istanbul 2004
subcellular location, e.g. VELLISTE & MURPIHY (2002) have
previously described automated systems recognizing all major
subcellular structures in 2D fluorescence microscopic images.
They have shown that pattern recognition accuracy is dependent
on the choice of the vertical position of the 2D slice through the
cell and that classification of protein localization patterns in 3D
images results in higher accuracy than in 2D. Automated
analysis of 3D images provides excellent distinction between
two golgi proteins whose patterns are indistinguishable by
visual examination. ROQUES & MURPHY (2002) describe the
application of pattern analysis methods to the comparison of
sets of fluorescence microscope images. MURPHY et al. (2002)
report improved numeric features for pattern descriptions which
are fairly robust to image intensity changes and different spatial
resolutions. They validate their conclusions using neural
networks. DANCKAERT et al. (2002) describe development and
test of a classification system based on a modular neural
network trained with sets of confocal focus series. The system
performed well in spite of the variability of patterns between
individual cells.
3. FEATURE EXTRACTION
In this work, to recognize proteins being active in a cell means
to visually differentiate between their appearances in images.
The latter depends on whether there are features which allow
making a difference between them. This is valid for visual
judgment by a human observer as well as for a pattern
recognition algorithm. The criteria used by a human usually are
directly related to known cell structure. For a pattern
recognition algorithm, among the multitude of features which
are present or can be defined in imagery, those have to be
identified which help to separate different phenotypes of cells
from each other in feature space. l.e., the pattern characterizing
a protein has to be parameterized. In general, the parameters to
be used have to describe the spatial distribution of the protein
inside of the cell.
Prior to feature extraction from imagery, a laboratory procedure
including chemical treatments of probes and microscopic image
acquisition had to be established. First, antibodies had to be
found allowing to stain the proteins making them — or the
organelles as the locations of their activity — visible in the
imagery. In addition to the protein investigated some organelles
had to be stained to allow recognition of the most characteristic
parts cell and, thereby, reference to the cell as such. Lamin was
chosen as the marker of the membrane of the nucleus of the cell
allowing separation of the nucleus form the cytoplasm, and
Golgin97 was used to stain the golgi apparatus.
On the basis of the membrane of a cell’s nucleus and golgi
apparatus a reference system allowing translation and rotation
invariant definition of features describing the proteins was
defined. The centre of the nucleus is used as central reference
point in the sense of the origin of a coordinate system. The cell
is subdivided into sectors inside and outside the nucleus (Fig.
1). In the system of sectors the direction to the centre of the
golgi apparatus is used as reference.
Fig. 1: Subdivision of the cell into sectors inside and
outside the cell nucleus.
Ten proteins and corresponding antibodies were selected for the
investigation. It was taken care to choose visually very different
as well as rather similar proteins. Figs. 2 and 3 show Huntingtin
and GIT as examples of visually similar proteins statistically
varying.
Fig. 2: Huntingtin
