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@INPROCEEDINGS{Huysegoms:1033599,
author = {Huysegoms, Marcel and Bludau, Sebastian and Upschulte, Eric
and Dickscheid, Timo and Amunts, Katrin},
title = {{C}ellular level 3{D} reconstructed volumes at 1µm
resolution within the {B}ig{B}rain},
reportid = {FZJ-2024-06479},
year = {2024},
abstract = {<b>Background $\&$ Summary</b><br>Analyzing cells and their
distributions in histological sections is the basis for
computing cytoarchitectonic maps of the human brain (Amunts
and Zilles, 2015). While cell distributions are inherently
3-dimensional, microscopic analysis in cell-body stained
tissue sections is usually performed in individual 2D
sections. The first 3D reconstruction of an entire human
brain from histology was generated at 20µm isotropic
resolution and shared as ‘BigBrain’ (Amunts et al.,
2013). However, investigating the distribution of individual
cells in 3D requires even higher resolution and
precision.<br><br>While previous work has exploited
trajectories of vessels for cross-section alignment
(Dickscheid et al., 2019), bisected cells provide
significantly more alignment constraints and overall better
coverage of tissue, thus allowing improved precision of
image registration and correction of 3D cell distributions
with respect to redundant detections (Huysegoms et al.,
2019). Based on this strategy, we processed 300 histological
sections from the occipital cortex of the BigBrain dataset,
which were scanned at 1µm isotropic resolution. We
reconstructed two 6x6x6 mm3 volumes of interest in 3D; one
in V1 (h0c1) and the other in V2 (h0c2). Both volumes were
subsequently anchored into the 20µm 3D BigBrain space using
an affine transformation based on manually selected
landmarks defined with VoluBA
(https://ebrains.eu/service/voluba). The provided resources
benefit evaluation of workflows that analyze 3D cell
distributions.<br><br><b>Data acquisition</b><br>300
coronal, cell-body stained histological sections (20µm
thickness) of the BigBrain were imaged with a
high-throughput scanning system (Tissue Scope, Huron
Technologies, Inc.) at 20 different focal planes, each with
an inplane resolution of 1µm. A nearly isotropic image
stack was thus obtained within the occipital cortex, ranging
from section number 429 to 728 of the BigBrain dataset. As
described in detail in (Amunts et al., 2013), sections were
embedded in paraffin and stained using a modified silver
staining. Consequently, the images show cell bodies with a
strong dark contrast.Each section was visually inspected for
histological artifacts. Eight sections were excluded from
volume 1 and nine sections were excluded from volume
2.<br><br><b>Detection and matching of
microstructures</b><br>The workflow used for reconstructing
the stack of histological images is based on the detection
and matching of corresponding microstructures between
consecutive sections. Specifically, we trained a Support
Vector Machine to detect blood vessels and developed a cell
segmentation algorithm based on Deep Learning that is robust
to staining inhomogeneities and overlapping cells (Upschulte
et al., 2022). Separating touching and overlapping cells
poses an especially challenging problem in segmentation
tasks but is resolved in the present work by incorporating
a-priori knowledge of cellular contours.We were subsequently
able to identify corresponding pairs of bisected cells
between adjacent sections using their centroid positions.
The matching task is challenged by the limited
distinctiveness of cell shapes, as well as the relatively
low prevalence of bisected cells $(20-40\%$ of cells at
20µm tissue thickness). To overcome these issues, our
workflow computes the Largest Common Pointset (LCP) between
cell centroids of adjacent sections, using purely geometric
constraints under locally affine transforms. The approach is
based on the 4-Points Congruent Sets strategy (Aiger, Mitra
and Cohen-Or, 2008), which repeatedly selects 4 random
points in one pointset and finds approximately congruent
point constellations in the other, effectively identifying
valid pairs of bisected cells. To deal with large human
brain sections, we extended the algorithm to operate
hierarchically across multiple scales and incorporated a
sliding window approach to handle non-linear tissue
deformations (Huysegoms et al., 2019).<br><br><b>Linear 3D
reconstruction</b><br>Based on the extracted cell matches,
an optimal affine 2D transformation was computed for each
pair of consecutive images using a Least Squares approach.
The resulting transformations were concatenated in an
iterative manner in order to yield absolute positions.
During this process, we applied a user-defined ROI of size
6x6mm2 to filter the number of matches and to obtain affine
parameters that are tailored to the local tissue
deformations.<br><br><b>Acknowledgements</b><br>Pavel
Chervakov and Xiao Gui (both INM-1) built and generally
maintain the infrastructure to provide interactive online
visualization of the reconstructed datasets.<br>This project
received funding from the European Union’s Horizon 2020
Research and Innovation Programme [grant agreement 785907
(HBP SGA2), 945539 (HBP SGA3)] and the Helmholtz
Association’s Initiative and Networking Fund through the
Helmholtz International BigBrain Analytics and Learning
Laboratory (HIBALL) [grant agreement
InterLabs-0015].<br>Computing time was granted through JARA
on the supercomputer JURECA at Jülich Supercomputing Centre
(JSC) as part of the project CJINM14.},
month = {Nov},
date = {2024-11-19},
organization = {INM Retreat 2024, Jülich (Germany),
19 Nov 2024 - 20 Nov 2024},
subtyp = {After Call},
cin = {INM-1},
cid = {I:(DE-Juel1)INM-1-20090406},
pnm = {5251 - Multilevel Brain Organization and Variability
(POF4-525) / 5254 - Neuroscientific Data Analytics and AI
(POF4-525) / HIBALL - Helmholtz International BigBrain
Analytics and Learning Laboratory (HIBALL) (InterLabs-0015)
/ EBRAINS 2.0 - EBRAINS 2.0: A Research Infrastructure to
Advance Neuroscience and Brain Health (101147319) / HBP SGA3
- Human Brain Project Specific Grant Agreement 3 (945539)},
pid = {G:(DE-HGF)POF4-5251 / G:(DE-HGF)POF4-5254 /
G:(DE-HGF)InterLabs-0015 / G:(EU-Grant)101147319 /
G:(EU-Grant)945539},
typ = {PUB:(DE-HGF)24},
url = {https://juser.fz-juelich.de/record/1033599},
}
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