According to the new research, the most vulnerable white matter pathways—the core "scaffolding"—are not necessarily just the connections among the most vulnerable areas of gray matter. These findings help explain why seemingly small brain injuries may have such devastating effects. (Credit: Pete Jordan/Flickr)

‘Scaffold’ map reveals brain’s weak spots

For the first time, neuroscientists have systematically identified the white matter “scaffold” of the human brain, the critical communications network that supports brain function.

Their work, published today in the journal Frontiers in Human Neuroscience, has major implications for understanding brain injury and disease. By detailing the connections that have the greatest influence over all other connections, the researchers offer not only a first map of core white matter pathways, but also show which connections may be most vulnerable to damage.

“We coined the term white matter ‘scaffold’ because this network defines the information architecture which supports brain function,” says senior author John Darrell Van Horn of the University of Southern California Institute for Neuroimaging and Informatics and the Laboratory of Neuro Imaging at USC.

“While all connections in the brain have their importance, there are particular links which are the major players,” Van Horn says.

White matter injury

Using MRI data from a large sample of 110 individuals, lead author Andrei Irimia, also of the Institute for Neuroimaging and Informatics, and Van Horn systematically simulated the effects of damaging each white matter pathway.

They found that the most important areas of white and gray matter don’t always overlap. Gray matter is the outermost portion of the brain containing the neurons where information is processed and stored. Past research has identified the areas of gray matter that are disproportionately affected by injury.

But the current study shows that the most vulnerable white matter pathways—the core “scaffolding”—are not necessarily just the connections among the most vulnerable areas of gray matter, helping explain why seemingly small brain injuries may have such devastating effects.

“Sometimes people experience a head injury which seems severe but from which they are able to recover. On the other hand, some people have a seemingly small injury which has very serious clinical effects,” says Van Horn, associate professor of neurology at the Keck School of Medicine of USC.

“This research helps us to better address clinical challenges such as traumatic brain injury and to determine what makes certain white matter pathways particularly vulnerable and important.”

Compare to social networks

The researchers compare their brain imaging analysis to models used for understanding social networks. To get a sense of how the brain works, Irimia and Van Horn did not focus only on the most prominent gray matter nodes—which are akin to the individuals within a social network. Nor did they merely look at how connected those nodes are.

Rather, they also examined the strength of these white matter connections, i.e. which connections seemed to be particularly sensitive or to cause the greatest repercussions across the network when removed. Those connections that created the greatest changes form the network “scaffold.”

“Just as when you remove the internet connection to your computer you won’t get your email anymore, there are white matter pathways which result in large scale communication failures in the brain when damaged,” Van Horn says.

When white matter pathways are damaged, brain areas served by those connections may wither or have their functions taken over by other brain regions, the researchers explain.

Irimia and Van Horn’s research on core white matter connections is part of a worldwide scientific effort to map the 100 billion neurons and 1,000 trillion connections in the living human brain, led by the Human Connectome Project and the Laboratory of Neuro Imaging at USC.

Irimia notes that, “these new findings on the brain’s network scaffold help inform clinicians about the neurological impacts of brain diseases such as multiple sclerosis, Alzheimer’s disease, as well as major brain injury. Sports organizations, the military, and the US government have considerable interest in understanding brain disorders, and our work contributes to that of other scientists in this exciting era for brain research.”

The NIH supported the research.

Source: USC

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  1. 俞巍

    i model the brain mainly 2 parts, mind and memory. the mind should be of few cells, function mainly for feeling and intention, through interacting with peripheral neuro system, and memory. meanwhile, the memory used most of the gray matter. the data structure of memory is a graph, there two kind of elements, node and connection. nodes are in gray matter, connections are in white matter. the neuron physical address is the memory address.(this is possibly the biggest advantage, that brain has no digital memory address, but physical address, and this is the root cause of the algorithm of brain and computer) so the bigger the area of the surface of gray brain is, the more memory size. nodes belong to subgraphs, subgraph belongs to deeper graphs,…deep graphs are connected by white matter.

  2. Jee

    #swag

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