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Brain Images Of Previously Unattainable Quality In High-Resolution Brain Model

helps us to generate new knowledge on the healthy and also the diseased brain,” says , director at the Institute of Neuroscience and Medicine (INM-1) and the C. and at . For example: “As a consequence of its evolution, the human cerebral cortex is very heavily folded,” says the neuroscientist. She explains that this is the reason why, in some areas, the thickness of the cerebral cortex can only be determined very imprecisely using imaging techniques such as magnetic resonance imaging. However, the thickness of the cortex changes in the course of a lifetime and is also affected by neurodegenerative processes, such as those associated with Alzheimer’s disease. “With the help of our high-resolution brain model, we can now gain a new understanding of the normal structure of different functional areas of the brain, such as the motor cortex or a region that is important for learning and memory, and we can also measure numerous structural properties,” explains Katrin Amunts. This will contribute to the precise identification and evaluation of changes in the brains of patients.

Information from thousands of tissue samples

The three-dimensional virtual brain is based on information from more than 7,400 tissue sections, each of them a mere 20 micrometres thick, that were obtained from a . “We started off in Düsseldorf more than five years ago,” says co-initiator Prof. Karl Zilles, now a senior professor in JARA-BRAIN, the brain research cooperation between Forschungszentrum Jülich and RWTH Aachen University. Each individual tissue section was scanned at Forschungszentrum Jülich and then reconstructed in three dimensions with supercomputers. “It’s an extremely difficult and complex task to work with these ultrathin, fragile tissue samples,” says Katrin Amunts. Cutting the extremely thin sections can cause tears or folds that have to be ‘repaired’ in the digitized versions by means of modern image processing tools, explains the researcher. In order to process the huge data sets produced, reconstruct them in three dimensions, and evaluate them, the scientists needed powerful supercomputers in Canada and at Jülich.

Human Brain Project benefits from BigBrain

The findings obtained from BigBrain will also be used in the European large-scale Human Brain Project (HBP), which includes Jülich experts specializing in neuroscience and information technology. Together with other researchers from more than 80 scientific institutions in 23 countries, they plan to simulate the entire human brain, from the molecular level to the interaction of entire brain regions, on a supercomputer of the future within the next ten years. In addition to their neuroscientific findings, the Jülich scientists will also contribute to HBP with their innovative software tools. With these tools, data from other brain models can be integrated into the freely accessible software tool BigBrain and be made available to the scientific community.


Original publication:
Katrin Amunts et al, BigBrain: An Ultrahigh-Resolution 3D Human Brain Model, Science, 21. Juni 2013, Vol. 340, p. 1472-1475
DOI: 10.1126/science.1235381

Further information:

Institute of Neuroscience and Medicine, Structural and Functional Organization of the Brain (INM-1): http://www.fz-juelich.de/inm/inm-1/EN/Home/home_node.html

Link to the BigBrain software tool: https://bigbrain.loris.ca/main.php

Link to the Human Brain Project: http://www.humanbrainproject.eu/

Helmholtz Association of German Research Centres