Quite rightly, research in Brain science is booming as
has all biological science. We are getting answers and lots of them.
What is missing yet though is a clear understanding of
memory itself. My own conjecture is that we establish a linkage
directly to the time and place in which an experience took place
partly because I suspect that this will turn out to be possible and
really possible at the molecular level and nature is wonderful at
grabbing every opportunity.
Thus the brain is about linkages only which is just what
we are looking at.
This item tells us just how exciting the field has
become.
Ancient
systems in the brain drive human cravings
Source: http://www.cbc.ca
By
Kelly Crowe, CBC
News
http://chrisinmaryville.net/ancient-systems-in-the-brain-drive-human-cravings.html
The neurotransmitter dopamine does its work through a form of unconscious learning
Neuroscience
is the new black, when it comes to fashion in scientific research.
“The
gene was the central issue in biology in 20th century,” Nobel
Laureate Dr. Eric Kandel, neuroscientist at Columbia
University said
in an interview in Toronto recently. “The mind is the essential
issue for biology in the 21st century.”
“And
certainly if you think of public health consequences, the diseases,
pain, schizophrenia, depression,
manic depressive disorder, post traumatic stress disorder, God knows
what, so many miseries of humankind come from psychiatric and
neurological disorders,” Kandel added.
Back
in the 1960′s, when Kandel began his Nobel prize winning
work searching for the biological source of memory, neuroscience was
a lonely field. “It didn’t interest many
biologists. Anatomy was considered boring, and electrophysiology was
too technically complicated for most scientists to pay attention to,”
he said.
Richard
Beninger is a behavioural neuroscientist at Queen’s University, who
recalls that as a student he studied the brain as a collection of
parts. “You could see white matter and dark matter and lots of fine
detail, right down to the neuron level, but it was all morphology,
structure,” he said.
“But
all of that changed, once scientists began to understand the chemical
pathways in the brain. The morphology is still there, but now we know
what the transmitter systems are. So we have a whole new brain only
in the last 40 years to work with,” Beninger said.
Today’s
technology allows scientists to put living, breathing humans into a
magnetic resonance imaging machine, tell them to think about
something, and watch as the biological traces of thought appear and
disappear in colorful bursts, measured by changes in blood oxygen
levels. It means scientists can now explore the neural landscape in
real time, and chart the cognitive forces that have shaped our
species from our earliest days.
As
they investigate this neural wonderland, scientists are probing the
very essence of what makes us human. It’s as though they are
lifting the hood of humanity, and tinkering with the wiring to find
how what makes us do what we do. And they are discovering that the
secret to everything we do, think, or feel, is in that wiring, a
constantly changing network of neuronal connections sculpted by
evolution and fired by electrical and chemical interactions.
Dr.
Kandel calls it the most complex organizational structure in the
universe. “So we’re far from understanding it completely, very
far, but the beginning has been quite dramatic,” he says.
“It’s
certainly extraordinary, our entire experience of life, all of our
mental experiences, if they all result from the activity of chemistry
in our brain, the activity of neurotransmitters and neurocircuits,
it’s amazing,” Beninger said.
Dopamine key to behaviour
For
Beninger, dopamine is the most fascinating neurotransmitter, allowing
us to interact with our environment, sending us in search of the
things we need for survival. “Something that’s biologically
valuable, food, for example, water, sexual partner, social companion,
social cooperation, those are things that activate the dopamine
system,” he says.
“These
systems are ancient, you know, fruit flies have similar systems, and
worms,” he says. “They’re found in fish and all vertebrates,
they’re very old, these dopamine neurons,” Beninger said.
Which
means the same chemical impulses that lead a fruit fly to dive into
your wineglass also makes you reach for the bottle and pour that
second glass.
“When
dopamine neurons are activated, whatever’s being encountered at the
time gets a stronger ability to attract in the future,”
Beninger says. “So for an animal in the wild, food-related stimuli,
things that signal food, like a particular place, a particular
object, then acquire the ability to draw the animal in the future.”
Dopamine
does its work through a form of unconscious learning, teaching the
brain to recognize environmental cues, sights sounds, smells,
feelings that lead back to the thing that first excited the reward
pathway, even if that ‘thing’ is dangerous. “So drugs that are
abused by people, all of them activate the dopamine system,”
Beninger explains.
Increasingly
scientists also believe food can hijack the brain’s reward system.
At York University, Professor Caroline Davis is studying the
biological basis of food addiction. She says the brain’s reward
system can be particularly sensitive to highly processed food with
combinations of salt, sugar, fat and flavours found nowhere in
nature.
The brain and food addiction
“Because
they’re so palatable, we tend to eat a lot of them and they give us
a greater dopamine boost than broccoli does,” Davis said. “The
things loaded with sugar, loaded with fat, salt, in combination
they’re very, very hard to resist and there’s evidence that if
you eat enough of these foods, in some vulnerable people, they
display behaviour that is very similar to the behaviour that we see
in other addicts.”
When
lab rats are given access to sugary food, they binge, and when the
sugar is taken away they show physical withdrawal systems that
resemble the animal’s withdrawal from heroin. Research has shown
that dopamine is one of the pathways activated in these
sugar-addicted mice.
Caroline
Davis has discovered a dopamine link in food-addicted humans, a
genetic profile that is associated with stronger dopamine signalling,
and she believes those genes might make some people more vulnerable
to dopamine’s cues.
“People
that tend to be very sensitive to reward, our data suggests, it may
be more difficult for them, in this environment. In another era, it
would have been quite adaptive because they would have gotten a great
pleasure out of food and they would have been the ones to pack on the
pounds and survived longer. But it doesn’t work so well in this
environment.”
Dopamine linked to motivation
Back
at Queen’s University in Kingston, Ont., Richard Beninger is
watching a series of videos of laboratory rats on a chin up bar,
taken by his students. When a normal rat is placed on the bar, it
gets down immediately. But something amazing happens when researchers
give the animal a drug that blocks the dopamine receptors. Now the
rat stays on the chin up bar, longer and longer after every dose.
“The
animal will just sit there if their dopamine is blocked. It’s not
that they can’t move, they are just not motivated to move,”
Beninger said. “It seems that you need dopamine to engage in the
environment.”
“I’m
still struggling to understand the implications of this condition,
‘catalepsy,’ he said. But he calls it an exciting finding. “I
think there’s some new, valuable information in this phenomenon.”
“I
think the cues that are around us, the things we interact with day to
day, all that we are able to respond to, pick up, and handle, all
that requires a certain level of dopamine.
And if we repeatedly are exposed to stimuli, with dopamine reduced,
we lose our ability to respond to those particular stimuli. It
seems that dopamine gives you a reason to move, get off the bar, act
on a stimuli, and without it, you have no interest in reacting the
stimuli or environment.”
Beninger
says it resembles the movement disruption in people with Parkinson’s
disease, which is associated with reduced dopamine activity,
something he is also studying in his lab.
Dopamine’s role in relationships
Beninger
is also studying how dopamine shapes our relationships. It seems that
when someone is nice to us, our dopamine will draw us back to that
person.
“So
when I interact cooperatively with someone else and they interact
cooperatively with me, that person, which is a representation in my
brain, by the action of dopamine, gains an enhanced ability to
attract me in the future,” Beninger says. “So
the dopamine sculpts our social landscape.”
I
think it’s an absolute marvel, you can only marvel more as you
begin to learn more about the chemical neuroanatomy of the brain,”
Beninger says. “It’s all of that working together that creates my
mental experience, my whole life. It’s an absolute marvel.”
If
they understand brain chemistry neuroscientists believe they will be
able to offer therapies to fight mental illness and improve the
entire human experience. And Dr. Eric Kandel says discoveries are
inevitable, in part because there are now so many scientists in the
field.
“When
I was a medical student, I wanted to take an elective in brain cell
science, but there was only one lab in New York City that had a good
person I could work with. It was unheard of. Now you go in the street
and every other person you meet is doing brain science.”
“I
was working in a lab for the first time in 1955. By 1969, a society
had formed in North America, called the Society of Neuroscience, and
it had 600 members. Now it has 35,000 members. The number of people
now working in brain science has grown enormously. It’s gone from
an arcane discipline. Now it’s one of the most exciting, if not the
most exciting area in biology.”
This
is part two of a four part series called Inside Your Brain on CBC’s
The National, World at Six and CBC.ca exploring how modern
neuroscience is changing the way we think about the way we think. In
part three Kelly Crowe discovers that our brains are highly active
even when we perceive them to be idle and the idle brain may be the
key to conciousness. The research for this series was funded by a
Canadian Institutes of Health Research journalism award.
i feel so stupid.
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