DL Collins, NJ Kabani, AC Evans
McConnell Brain Imaging Centre, Montréal Neurological
Institute,
McGill University, Montréal, Canada
Published in the proceedings of the 4-th International Conference on Functional Mapping of the Human Brain
DL Collins, NJ Kabani, AC Evans
McConnell Brain Imaging Centre, Montréal Neurological
Institute,
McGill University, Montréal, Canada
The volume of a number of specific cerebral structures have been correlated with different pathologies such as epilepsy, schizophrenia, Alzheimer's disease, multiple infarct dementia and hydrocephalus. To determine structural abnormality, comparisons to a normative data-base are required. However, estimation of normal population parameters is a daunting task since manual structure segmentation is time-consuming, error-prone and inter- and intra-observer variabilities may confound the estimation of true structure variability. To address these problems, we have developed a fully automatic hybrid segmentation scheme based on ANIMAL [1] (non-linear registration) and INSECT [2] (tissue classification) that can be applied to large ensembles of MRI volumes.
Automatic segmentation is achieved by estimating the non-linear spatial
transformation required to register all voxels from a subject's MRI volume
with an average MRI brain that is co-registered with a SPAM (Statistical
Probability Anatomy Maps) Atlas in a Talairach-like stereotaxic space
[3]. The atlas' 90 average gross anatomical structures are
mapped through the inverse transform to effectively define customized masks
on the subject's MRI for the most-likely region for each structure.
Tissue classes such as grey-matter, white-matter and CSF, identified by a
minimum distance classifier, are masked by these regions to complete the
segmentation. This methodology was applied to the MRI volumes of 152 normal
subjects (86 male, 66 female, age
)
as part of the ICBM
project.
In the following table, all volumes are in cm3. Values (mean 
standard deviation) for left side precede the right for symmetric
structures. Significant differences (p<0.01, two-tailed Student's t-test
with Bonferoni correction) are indicated with '<' (right greater than
left) or '>' (left greater than right). The left-right volume difference
for temporal and parietal lobes are significant at the p=0.05 level.
frontal lobe![$[175.0\pm25.3=174.0\pm25.0]$](img6.gif){kind=small} |
precentral
![$[14.5 \pm 2.2 < 16.8 \pm 2.6]$](img7.gif){kind=small} ;
superior-frontal (fr)
![$[11.2 \pm 1.4 = 11.2 \pm 1.5]$](img8.gif){kind=small} ;
middle-fr
![$[24.9 \pm 3.5 = 22.7 \pm 3.1]$](img9.gif){kind=small} ;
inferior-fr
![$[11.4 \pm 1.7 = 12.8 \pm 1.9]$](img10.gif){kind=small} ;
medial-fr
![$[14.1 \pm 1.8 = 12.9 \pm 1.8]$](img11.gif){kind=small} ;
lateral-fronto-orbital (fo)
![$[9.2 \pm 1.4 = 10.1 \pm 1.5]$](img12.gif){kind=small} ;
medial-fo
![$[2.2 \pm 0.4 = 2.6 \pm 0.4]$](img13.gif){kind=small} |
temporal lobe![$[119.3\pm18.1 = 109.8\pm16.4]$](img14.gif){kind=small} |
superior-temporal (t)
![$[16.4 \pm 2.6 = 16.1 \pm 2.7 ]$](img15.gif){kind=small} ;
middle-t
![$[15.5 \pm 2.2 < 23.3 \pm 3.9 ]$](img16.gif){kind=small} ;
inferior-t
![$[6.8 \pm 1.4 = 7.5 \pm 1.3]$](img17.gif){kind=small} ;
medial occipito-temporal (ot)
![$[7.0 \pm 1.0 = 6.4 \pm 1.0]$](img18.gif){kind=small} ;
lateral-ot
![$[12.1 \pm 1.9 = 11.0 \pm 1.7]$](img19.gif){kind=small} ;
uncus
![$[2.5 \pm 0.5 = 2.7 \pm 0.7 ]$](img20.gif){kind=small} ;
parahippocampal
![$[4.4 \pm 0.8 = 5.4 \pm 1.0 ]$](img21.gif){kind=small} |
parietal lobe![$[95.0\pm13.7=99.3\pm14.3]$](img22.gif){kind=small} |
postcentral
![$[15.6 \pm 2.3 > 11.1 \pm 1.8 ]$](img23.gif){kind=small} ;
superior parietal lobule
![$[14.4 \pm 2.2 = 16.6 \pm 2.4 ]$](img24.gif){kind=small} ;
supramarginal
![$[7.1 \pm 1.2 = 5.3 \pm 0.9 ]$](img25.gif){kind=small} ;
angular
![$[7.8 \pm 1.2 < 11.0 \pm 1.7]$](img26.gif){kind=small} ;
precuneus
![$[4.4 \pm 0.8 = 4.4 \pm 0.8]$](img27.gif){kind=small} |
occipital lobe![$[44.8\pm7.9 = 45.9\pm8.2]$](img28.gif){kind=small} |
superior-occipital (o)
![$[5.2 \pm 1.0 = 5.0 \pm 1.0]$](img29.gif){kind=small} ;
middle-o
![$[4.3 \pm 0.7 = 5.3 \pm 0.9]$](img30.gif){kind=small} ;
inferior-o
![$[4.0 \pm 0.8 > 1.9 \pm 0.4]$](img31.gif){kind=small} ;
occipital pole
![$[3.3 \pm 0.9 = 2.8 \pm 0.7 ]$](img32.gif){kind=small} ;
cuneus
![$[5.5 \pm 1.1 = 5.6 \pm 1.0 ]$](img33.gif){kind=small} ;
lingual
![$[4.7 \pm 1.2 = 3.2 \pm 0.8]$](img34.gif){kind=small} |
| other grey | insula
![$[8.8 \pm 1.1 = 8.8 \pm 1.1 ]$](img35.gif){kind=small} ;
cingulate
![$[17.1 \pm 2.4 = 14.9 \pm 2.0 ]$](img36.gif){kind=small} ;
hippocampus
![$[5.1 \pm 0.8 = 4.0 \pm 0.6 ]$](img37.gif){kind=small} ;
caudate
![$[5.4 \pm 0.7 = 5.1 \pm 0.6 ]$](img38.gif){kind=small} ;
putamen
![$[5.4 \pm 0.7 = 5.5 \pm 0.7 ]$](img39.gif){kind=small} ;
globus pallidus
![$[0.9 \pm 0.2 = 1.4 \pm 0.2 ]$](img40.gif){kind=small} ;
thalamus
![$[8.3 \pm 0.9 = 9.0 \pm 1.0 ]$](img41.gif){kind=small} ;
nucleus accumbens
![$[0.3 \pm 0.1 = 0.4 \pm 0.1 ]$](img42.gif){kind=small} ;
subthalamic nucleus
![$[0.1 \pm 0.0 = 0.1 \pm 0.0 ]$](img43.gif){kind=small} |
| other | corpus collosum
![$[10.9 \pm 1.5]$](img44.gif){kind=small} ;
fornix
![$[0.3 \pm 0.1 ]$](img45.gif){kind=small} ;
anterior internal capsule (ic)
![$[3.3 \pm 0.5 = 3.0 \pm 0.6]$](img46.gif){kind=small} ;
posterior ic
![$[1.6 \pm 0.3 = 1.6 \pm 0.3 ]$](img47.gif){kind=small} ;
lateral ventricle (v)
![$[8.9 \pm 3.6 = 8.0 \pm 3.4 ]$](img48.gif){kind=small} ; |
The method presented here is completely automatic, fully objective, and has been applied to a large ensemble of brain volumes. The resulting volume statistics will prove useful as a normative data base for comparisons in future studies of normal or pathological brains.
1. D.L. Collins, C.J. Holmes, T.M. Peters and A.C. Evans. Human Brain Mapping. 3(3):190-208, 1996.
2. Zijdenbos, A.P., Evans, A.C., Riahi, et al. Proc Vis Biomed Comp. p 439-448 1996.
3. A.C. Evans, D.L. Collins, C.J. Holmes, et al. ``Towards a probabilistic atlas of human neuroanatomy'' in Brain Mapping: The Methods. 1996
Supported by the U.S. Human Brain Map Project and the
International Consortium for Brain Mapping.
Louis COLLINS