What EXACT stroke protocol is your doctor having you do to make sure your brain waves are doing the correct thing and not giving you memory problems as a result of your stroke? This is an extremely serious question for your doctor, don't let them pooh-pooh it. Do these waves still form post-stroke?
http://www.rdmag.com/news/2015/02/how-brain-waves-guide-memory-formation?
Our brains generate a constant hum of activity: As neurons fire, they
produce brain waves that oscillate at different frequencies. Long
thought to be merely a byproduct of neuron activity, recent studies
suggest that these waves may play a critical role in communication
between different parts of the brain.
A new study from Massachusetts Institute of Technology (MIT)
neuroscientists adds to that evidence. The researchers found that two
brain regions that are key to learning—the hippocampus and the
prefrontal cortex—use two different brain-wave frequencies to
communicate as the brain learns to associate unrelated objects. Whenever
the brain correctly links the objects, the waves oscillate at a higher
frequency, called “beta,” and when the guess is incorrect, the waves
oscillate at a lower “theta” frequency.
“It’s like you’re playing a computer game and you get a ding when you
get it right, and a buzz when you get it wrong. These two areas of the
brain are playing two different ‘notes’ for correct guesses and wrong
guesses,” says Earl Miller, the Picower Professor of Neuroscience, a
member of MIT’s Picower Institute for Learning and Memory, and senior
author of a paper describing the findings in Nature Neuroscience.
Furthermore, these oscillations may reinforce the correct guesses
while repressing the incorrect guesses, helping the brain learn new
information, the researchers say.
Signaling right and wrong
Miller and lead author Scott Brincat, a research scientist at the
Picower Institute, examined activity in the brain as it forms a type of
memory called explicit memory—memory for facts and events. This includes
linkages between items such as names and faces, or between a location
and an event that took place there.
During the learning task, animals were shown pairs of images and
gradually learned, through trial and error, which pairs went together.
Each correct response was signaled with a reward.
As the researchers recorded brain waves in the hippocampus and the
prefrontal cortex during this task, they noticed that the waves occurred
at different frequencies depending on whether the correct or incorrect
response was given. When the guess was correct, the waves occurred in
the beta frequency, about 9 to 16 hertz (cycles per second). When
incorrect, the waves oscillated in the theta frequency, about 2 to 6
hertz.
Previous studies by MIT’s Mark Bear, also a member of the Picower
Institute, have found that stimulating neurons in brain slices at beta
frequencies strengthens the connections between the neurons, while
stimulating the neurons at theta frequencies weakens the connections.
Miller believes the same thing is happening during this learning task.
“When the animal guesses correctly, the brain hums at the correct
answer note, and that frequency reinforces the strengthening of
connections,” he says. “When the animal guesses incorrectly, the ‘wrong’
buzzer buzzes, and that frequency is what weakens connections, so it’s
basically telling the brain to forget about what it just did.”
The findings represent a major step in revealing how memories are
formed, says Howard Eichenbaum, director of the Center for Memory and
Brain at Boston Univ.
“This study offers a very specific, detailed story about the role of
different directions of flow, who’s sending information to whom, at what
frequencies, and how that feedback contributes to memory formation,”
says Eichenbaum, who was not part of the research team.
The study also highlights the significance of brain waves in
cognitive function, which has only recently been discovered by Miller
and others.
“Brain waves had been ignored for decades in neuroscience. It’s been
thought of as the humming of a car engine,” Miller says. “What we’re
discovering through this experiment and others is that these brain waves
may be the infrastructure that supports neural communication.”
Enhancing memory
The researchers are now investigating whether they can speed up learning
by delivering noninvasive electrical stimulation that oscillates at
beta frequencies when the correct answer is given and at theta
frequencies when the incorrect answer is given. “The idea is that you
make the correct guesses feel more correct to the brain, and the
incorrect guesses feel more incorrect,” Miller says.
This form of very low voltage electrical stimulation has already been approved for use in humans.
“This is a technique that people have used in humans, so if it works,
it could potentially have clinical relevance for enhancing memory or
treating neurological disorders,” Brincat says.
Source: Massachusetts Institute of Technology
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