At the cellular level,
it's a lot like faster networking
Newswise, May 25, 2016 — We tend to think our memory works
like a filing cabinet. We experience an event, generate a memory and then file
it away for later use.
In
fact, making memories is similar to plugging your laptop into an Ethernet
cable—the strength of the network determines how the event is translated within
your brain.
Neurons (nerve cells in the brain) communicate through
synaptic connections (structures that pass a signal from neuron-to-neuron) that
“talk” to each other when certain neurotransmitters (chemicals that allow the
transmission of these signals) are present.
Think of a neurotransmitter as an email. If you’re busy and
you receive one or two emails, you might ignore them.
But, if you are bombarded with hundreds of emails from the
same person, saying basically the same thing, all at the same time, you will
likely begin to pay attention and start a conversation with the sender: Why on
earth are you sending me all these emails?
Similarly, neurons only open a line of communication with each
other when they receive stimulation from several of the same neurotransmitters
at once: Oh, my neighbor keeps hitting me with the same signal? I better talk
to them! So, how exactly does this relate to memory? It’s the strength of these
connections between neurons that determines how a memory is formed.
“The persistent strengthening of these activated synapses
(connections) between neurons is called long-term potentiation (LTP),” said
William Griffith, Ph.D., a cellular neuroscientist and chair of the Department
of Neuroscience and Experimental Therapeutics at the Texas A&M Health
Science Center College of Medicine. “LTP is the most recognized cellular
mechanism to explain memory because it can alter the strength between brain
cell connections. If this strength is maintained, a memory can be formed.”
LTP happens when nerve cells “fire” or talk to one another at
an elevated rate without further increased stimulation from neurotransmitters.
In a sense, it’s like building a relationship with the email sender.
Once you’ve started a dialogue with the sender you’re in a
better position to communicate more easily and maintain a strong rapport. Just
like you might add the sender to your contact list, your brain has created a
‘strengthened synaptic contact.’ But, if you’re not talking, the relationship
wanes.
Likewise, your ability to recall and remember certain memories
depends on maintaining the strength of this long-term connection between
synaptic contacts. LTP acts as an Ethernet cable of sorts—allowing your brain
to upload, download and process at a higher rate—which may explain why some
memories are more vivid than others: the pathway on which you contact them
performs at a faster pace.
“The brain is a plastic organ,” Griffith explained. “This
means it can easily reconfigure or modify itself. However, it’s also a muscle.
You use it or you lose it. As the synapses and pathways between neurons are
used, they gain the ability to become strengthened or permanently enhanced.
This is the building block of how memory works.”
In the same vein, losing this strong LTP— or heightened
synaptic connections between neurons—could be the reason behind cognitive loss
and impairment.
“Because the brain is an organ, it will show wear and tear,”
Griffith continued.
“Many people believe this decrease in neurons ‘talking’ to one
another is responsible for cognitive loss—because the pathways are not being
used or strengthened. Just as muscles in the body atrophy when you don’t use
them, the brain will deteriorate when it’s not stimulated.”
Griffith said the argument about how memory is consolidated
and retrieved is vast, and there are many aspects that still need to be studied
about the phenomenon.
“When you look at or smell something, it contributes to your
memory of an event,” he said.
“This can be mapped in many parts of the brain. Memory may
also be involved in certain behaviors like addiction. Why does this happen? Is
it because the pathways for addiction are strengthened, or because they’re
repressed? We don’t know yet.”
The science behind memory is a complex one, and will likely be
studied for decades to come.
“Many different pathways in the brain interact to set up
complex circuits for different types of memories,” Griffith said. “There’s much
debate and more research that needs to be done to fully comprehend how our
brain generates, consolidates and retrieves memories.”
About Texas A&M Health Science Center
Texas A&M Health Science Center is Transforming Health through innovative
research, education and service in dentistry, medicine, nursing, pharmacy,
public health and medical sciences. As an independent state agency and academic
unit of Texas A&M University, the health science center serves the state
through campuses in Bryan-College Station, Dallas, Temple, Houston, Round Rock,
Kingsville, Corpus Christi and McAllen. Learn more at vitalrecord.tamhsc.edu or
follow @TAMHSC on Twitter.
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