The accomplishment is a first step toward creating a complete computer
model of the brain that will allow a deeper understanding of how our
noggins work — and what causes them to malfunction, according to the
scientists behind the feat.
For a starting point, researchers at the Max Planck Florida Institute are focused on how the rat brain processes information gathered by a single whisker.
They did so because studies in their lab and elsewhere
have shown that a single whisker is able to detect, in complete
darkness, whether a gap is safe to jump over and, if so, trigger the
order to jump.
What's more, there's a specific region of the
brain "that is dedicated to processing information from a dedicated
whisker," Marcel Oberlaender, a researcher at the institute and the
first author of a paper explaining the research in the journal Cerebral Cortex, told me today.
That
region is called the cortical column, a vertically-organized series of
connected neurons that form a brain circuit and an elementary building
block of the cortex.
The cortex is the part of the brain responsible for many of the higher functions, such as memory and consciousness.
To
build the model, the researchers studied the cortical column in awake
and anesthetized rats as well as brain slices and then used computer software and other tools to reconstruct it.
"The
model we built is really based on a complete reconstruction of these
nerve cells," Oberlaender said. "So how the model looks in the end
resembles how it would look in the real animal."
It is composed of
16,000 neurons, each of which can be divided into one of nine different
cell types that has characteristic functional, structural and
connectivity properties, he added.
The model can now be used to
run computer simulations that show, in realistic detail, how signals
flow within the brain. So, they can begin to understand, for example,
what neurons fire as the rat detects the gap and decides whether or not
to jump.
Until now, researchers have only been able to see how a
single neuron or a small group of neurons interact during such a
process. "We can now, in simulation experiments, mimic what is really
going on in these circuits," Oberlaender said.
Going forward, the
researchers should be able to use the methodology developed to build
this model to add more parts to it, thus incorporating other brain
functions such as the motor system that sends a signal down the spinal
cord and makes the limbs move so that rat can jump over the gap.
* * *
John Roach is a contributing writer for msnbc.com. To learn more about him, check out his website.
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