Sleep
helps the brain consolidate what we’ve learned, but scientists have
struggled to determine what goes on in the brain to make that happen for
different kinds of learned tasks.
You take your piano lesson, you go to
sleep and when you wake up your fingers are better able to play that
beautiful sequence of notes. How does sleep make that difference? A new
study helps to explain what happens in your brain during those fateful,
restful hours when motor learning takes hold.
“The mechanisms of memory consolidations
regarding motor memory learning were still uncertain until now,” said
Masako Tamaki, a postdoctoral researcher at Brown University and lead
author of the study that appears Aug. 21 in the Journal of Neuroscience.
“We were trying to figure out which part of the brain is doing what
during sleep, independent of what goes on during wakefulness. We were
trying to figure out the specific role of sleep.”
In part because it employed three
different kinds of brain scans, the research is the first to precisely
quantify changes among certain brainwaves and the exact location of that
changed brain activity in subjects as they slept after learning a
sequential finger-tapping task. The task was a sequence of key punches
that is cognitively akin to typing or playing the piano.
Cap of Sensors
In a sleep lab on Brown’s campus
researchers use now using caps of EEG sensors in studies of how the
brain works to consolidate learning visual tasks. Here graduate student
Aaron Berard models the cap.Specifically, the results of complex
experiments performed at Massachusetts General Hospital and then
analyzed at Brown show that the improved speed and accuracy volunteers
showed on the task after a few hours sleep was significantly associated
with changes in fast-sigma and delta brainwave oscillations in their
supplementary motor area (SMA), a region on the top-middle of the brain.
These specific brainwave changes in the SMA occurred during a
particular phase of sleep known as “slow-wave” sleep.
Scientists have shown that sleep
improves many kinds of learning, including the kind of sequential
finger-tapping motor tasks addressed in the study, but they haven’t been
sure about why or how. It’s an intensive activity for the brain to
consolidate learning and so the brain may benefit from sleep perhaps
because more energy is available or because distractions and new inputs
are fewer, said study corresponding author Yuka Sasaki, a research
associate professor in Brown’s Department of Cognitive, Linguistic &
Psychological Sciences.
“Sleep is not just a waste of time,” Sasaki said.
The extent of reorganization that the
brain accomplishes during sleep is suggested by the distinct roles the
two brainwave oscillations appear to play. The authors wrote that the
delta oscillations appeared to govern the changes in the SMA’s
connectivity with other areas of the cortex, while the fast-sigma
oscillations appeared to pertain to changes within the SMA itself.
Meticulous measurements
Possible roles for fast-sigma and delta
brainwaves and for the SMA had suggestive support in the literature
before this study, but no one had obtained much proof in part because
doing so requires a complex experimental protocol.
To make their findings, Sasaki, Tamaki
and their team asked each of their 15 subjects to volunteer for the
motor learning experiments. For the first three nights, nine subjects
simply slept at whatever their preferred bedtime was while their brains
were scanned both with magnetoencephalography (MEG), which measures the
oscillations with precise timing, and polysomnography, which keeps track
of sleep phase. By this time the researchers had good baseline
measurements of their brain activity and subjects had become accustomed
to sleeping in the lab.
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