Sleep -- or a lack thereof -- has a dramatic effect
Michigan Medicine - University of Michigan
Imagine you're a student, it's finals week,
and you're preparing for a big exam: do you pull an all-nighter or do you get
some rest?
Jacob Dwyer, Michigan Medicine
As many a groggy-eyed person who's stared
blankly at a test knows, a lack of sleep can make it extraordinarily difficult
to retain information.
Two new studies from University of Michigan
uncover why this is and what is happening inside the brain during sleep and
sleep deprivation to help or harm the formation of memories.
Specific neurons can be tuned to specific
stimuli.
For example, rats in a maze will have
neurons that light up once the animal reaches specific spots in the maze. These
neurons, called place neurons, are also active in people and help people
navigate their environment.
But what happens during sleep?
"If that neuron is responding during
sleep, what can you infer from that?" said Kamran Diba, Ph.D., associate
professor of Anesthesiology at U-M Medical School.
A study, summarized in the journal Nature and
led by Diba and former graduate student Kourosh Maboudi, Ph.D., looks at
neurons in the hippocampus, a seahorse shaped structure deep in the brain
involved in memory formation, and discovered a way to visualize the tuning of
neuronal patterns associated with a location while an animal was asleep.
A type of electrical activity called
sharp-wave ripples emanate from the hippocampus every couple of seconds, over a
period of many hours, during restful states and sleep.
Researchers have been intrigued by how
synchronous the ripples are and how far they travel, seemingly to spread
information from one part of the brain to another.
These firings are thought to allow neurons
to form and update memories, including of place.
For the study, the team measured a rat's
brain activity during sleep, after the rat completed a new maze.
Using a type of statistical inference
called Bayesian learning, they were for the first time able to track which
neurons would respond to which places in the maze.
"Let's say a neuron prefers a certain
corner of the maze. We might see that neuron activate with others that show a
similar preference during sleep. But sometimes neurons associated with other
areas might co-activate with that cell. We then saw that when we put it back on
the maze, the location preferences of neurons changed depending on which cells
they fired with during sleep," said Diba.
The method allows them to visualize the
plasticity or representational drift of the neurons in real time.
It also gives more support to the
long-standing theory that reactivation of neurons during sleep is part of why
sleep is important for memories.
Given sleep's importance, Diba's team
wanted to look at what happens in the brain in the context of sleep
deprivation.
In the second study, also published
in Nature, the team, led by Diba and former graduate student Bapun
Giri, Ph.D., compared the amount of neuron reactivation -- wherein the place
neurons that fired during maze exploration spontaneously fire again at rest --
and the sequence of their reactivation (quantified as replay), during sleep vs.
during sleep loss.
They discovered that the firing patterns of
neurons involved in reactivating and replaying the maze experience were higher
in sleep compared to during sleep deprivation.
Sleep deprivation corresponded with a
similar or higher rate of sharp-wave ripples, but lower amplitude waves and
lower power ripples.
"In almost half the cases, however,
reactivation of the maze experience during sharp-wave ripples was completely
suppressed during sleep deprivation," said Diba.
When sleep deprived rats were able to catch
up on sleep, he added, while the reactivation rebounded slightly, it never
matched that of rats who slept normally. Furthermore, replay was similarly
impaired but was not recovered when lost sleep was regained.
Since reactivation and replay are important
for memory, the findings demonstrate the detrimental effects of sleep
deprivation on memory.
Diba's team hopes to continue looking at
the nature of memory processing during sleep and why they need to be
reactivated and the effects of sleep pressure on memory.
Additional authors include Hiroyuki Miyawaki, Caleb Kemere, Nathaniel Kinshy, Utku Kaya and Ted Abel.
