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If "How Brain Works - Large Scale Features" is not shown property. Visit the source link above.
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![[labeled picture of a brain from the side] - How Brain Works - Large Scale Features](http://www.eTagLive.com/Attachments/8/d/b/or_8db3c86d-62ea-4063-9a0c-a86f4c207c2c.jpg) |
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The brain is
probably the most complex structure in the known universe; complex
enough to coordinate the fingers of a concert pianist or to create
a three-dimensional landscape from light that falls on a
two-dimensional retina. While it is the product of many millions of
years of evolution, some of the structures unique to the human
species have only appeared relatively
recently. |
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For example, only
100,000 years ago, the ancestors of modern man had a brain weighing
only about one pound - roughly a third of the weight of the current
version. Most of this increased weight is associated with the most
striking feature of the human brain - the cortex - the two
roughly symmetrical, corrugated and folded hemispheres which sit
astride the central core. |
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![[picture of brain from side] - How Brain Works - Large Scale Features](http://www.eTagLive.com/Attachments/a/c/6/or_ac6be023-503e-4ba0-9540-5e82d77dfd87.jpg) |
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Almost all the tasks that seem hard or difficult
for human beings but that the present generation of computers can
easily perform are associated with processing in parts of the
relatively new cortex. Conversely, tasks that humans normally find
easy but that are difficult for computers typically have a much
longer evolutionary history. Although playing chess, doing higher
mathematics and trouble-shooting electronic circuits may seem
intellectually challenging for humans, current computers can cope
very straightforwardly. However, a modern computer (even after much
careful programming) is typically very poor at such simple tasks as
sensing its environment or coordinating movements. A simple
operation like recognizing someone's face, which we find rather
straightforward, is a formidable problem for a computer. Indeed, a
2-year-old child will perform much better at these tasks! This
observation is not so surprising, though, when one considers that
the child is using multiple levels of processing that have evolved
over many hundreds of thousands of years. |
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In evolutionary terms, all brains are extensions
of the spinal cord. The distant ancestor of the human brain
originated in the primordial seas some 500,000,000 years ago. Life
and survival in those seas was relatively simple and in consequence
these early brains consisted of just a few hundred nerve cells. As
these initial sea-creatures evolved and became more complex, so too
did the brain. A major change occurred when these early fish
crawled out of the seas and onto the land. The enhanced
difficulties of survival on land led to the creation of the
"reptilian brain". This brain design is still visible in all modern
reptiles and mammals and is a powerful clue to our common
evolutionary ancestry. |
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The next major addition occurred with the
mammalian brain in which a new structure emerged - the
cerebrum or forebrain along with its covering, the
cortex. By now, the brain consisted of literally hundreds of
millions of nerve cells organized into separate regions of the
brain and associated with different tasks. About 5,000,000 years
ago, another type of cortex appeared in a new species - early
man. In this brain, the surface of the cortex was organized
into separate columnar regions less than one millimeter wide but
each containing many millions of nerve cells or neurons. This new
structure allowed much more complex processing to take place.
Finally, about 100,000 years ago, this new cortex underwent rapid
expansion with the advent of modern man. The present day cortex
contains something like two-thirds of all neurons and weighs about
three pounds - almost triple its weight only one hundred thousand
years ago! |
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![[picture with a slice of the brain] - How Brain Works - Large Scale Features](http://www.eTagLive.com/Attachments/3/5/4/or_3545c11e-9426-45dc-8cfd-2e1da0084696.jpg) |
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Thus the human
brain consists of roughly three separate parts.
- The first segment
in the lower section, sometimes called the brain stem, consisting
of structures such as the medulla (controlling breathing, heart rate and
digestion) and the cerebellum (coordinating senses and
muscle movement). Much of these features are inherited "as is" from
the reptilian brain.
- The second segment
appears as a slight swelling in lower vertebrates and enlarges in
the higher primates and ourselves into the midbrain. The
structures contained here link the lower brain stem to the
thalamus (for information relay) and to the
hypothalamus (which is instrumental in regulating drives and
actions). The latter is part of the limbic system.
The limbic
system, essentially alike in all mammals, lies above the brain
stem and under the cortex and consists of a number of
interconnected structures. Researchers have linked these structures
to hormones, drives, temperature control, emotion, and one part,
the hippocampus to memory formation. Neurons affecting heart
rate and respiration appear concentrated in the hypothalamus
and direct most of the physiological changes that accompany strong
emotion. Aggressive behavior is linked to the action of the
amygdala, which lies next to the hippocampus. The latter
plays a crucial role in processing various forms of information as
part of our long term memory. Damage to the hippocampus will
produce global retrograde amnesia, or the inability to lay
down new stores of information.
As we have seen, much of the lower and mid brain are relatively
simple systems which are capable of registering experiences and
regulating behavior largely outside of any conscious awareness (we
don't have to think to remember to breathe!). In a sense, the human
brain is like an archeological site with the outer layer composed
of the most recent brain structure, and the deeper layers
consisting of structures from our shared evolutionary history with
the reptiles and mammals.
- Finally, the third
section, the forebrain appears as a mere bump in the brain
of the frog but balloons into the cerebrum of higher life
forms and covers the brain stem like the head of a mushroom. It has
further evolved in humans into the walnut-like configuration of
left and right hemispheres. The highly convoluted surface of the
hemispheres - the cortex - is about two millimeters thick
and has a total surface area of about 1.5 square-meters (the size
of a desktop).
The structure of
the cortex is extremely complicated. It is here that most of the
"high-level" functions associated to the mind are implemented. Some
of its regions are highly specialized - for example, the
occipital lobes located near the rear of the brain are
associated with the visual system. The motor cortex helps
coordinate all voluntary muscle
movements. |
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More neurons may be
dedicated to certain regions of the body than others - for example,
the fingers have many more nerve endings than the toes. We can use
this to construct a distorted map of the body which shows the
emphasis given to certain regions of the body's
surface. |
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There is an approximate symmetry between left and
right hemispheres - for example, there are two occipital lobes, two
parietal lobes and there are two two frontal lobes.. However this
symmetry is not exact - for example, the area associated with
language appears only on the left hemisphere. |
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The frontal lobes occupy the
front part of the brain behind the forehead and compose the portion
of the brain most closely associated with "control" of responses to
input from the rest of the system. They are most closely linked
with making decisions and judgements. |
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![[picture of front of brain] - How Brain Works - Large Scale Features](http://www.eTagLive.com/Attachments/9/0/9/or_90912347-e14a-413e-aebc-5620cb78456c.jpg) |
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In most people, the left hemisphere is
dominant over the right in deciding which response to make. Since
the frontal lobes occupy 29 percent of the cortex in our species
(as opposed to 3.5 percent in rats and 17 percent in chimpanzees),
they are often regarded as an index of our evolutionary
development. In individuals with normal hemispheric dominance, the
left hemisphere, which manages the right side of the body, controls
language and general cognitive functions. The right
hemisphere, controlling the left half of the body, manages
nonverbal processes, such as attention, pattern recognition, line
orientation and the detection of complex auditory tones. Although
the two hemispheres are in continual communication with each other,
each acting as independent parallel processors with complementary
functions, the dominant left-hemisphere appears most closely
associated with a conscious self. |
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These structural
features of the brain have been known for some time. In the section
Building Blocks we will explore the
nature of the cells themselves and later in Organization try to
understand how this set of intercommunicating complex structures we
have described can possibly arise from the function and
organization of the neurons themselves. |
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