Health

Study eyes brain-memory link during sleep

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A breakthrough study has demonstrated for the first time that long-lasting memories are consolidated in the human brain through communication between the hippocampus and the cerebral cortex during sleep. The researchers also found that by inducing deep-brain stimulation during sleep, they can improve memory consolidation.

The study, published June 1 in the journal Nature Neuroscience, involved an international collaboration led by Dr. Maya Geva-Sagiv of the University of California, Davis.

“This study was made possible by the collection of a rare group of 18 patients with epilepsy at the UCLA Medical Center,” says Professor Yuval Nir of UCLA. Professor Itzhak Fried of Tel Aviv University and UCLA “implanted electrodes in these patients’ brains to try and pinpoint the areas that cause their epileptic seizures, and they volunteered to take part in a study investigating the effects of deep-brain stimulation during sleep,” Geva-Sagiv said.

“We were able to test, for the first time in humans, the long-held hypothesis that coordinated activity of the hippocampus and cerebral cortex during sleep is a critical mechanism in consolidating memories.”

“We know that a good night’s sleep is critical for the consolidation of long-lasting memories, but so far we had little evidence regarding the precise processes that are at work during human sleep,” explains Geva-Sagiv. “In this study we directly examined the role of neural activity and electrical brain waves during sleep. Our goal was to enhance the natural mechanisms at play, to discover exactly how sleep assists in stabilizing memories.”

The researchers developed a deep-brain stimulation system that improves electrical communication between the hippocampus (a deep-brain region involved in acquiring new memories) and the frontal cortex (where memories are stored for the long term). By monitoring activity in the hippocampus during sleep, the system enabled the precisely timed delivery of electrical stimulation to the frontal cortex.

The study’s participants completed two memory tests, comparing their performance after two nights — one during which they slept undisturbed and one during which they received deep-brain stimulation. On both occasions, they were asked in the morning to recognize famous persons whose pictures they had been shown the previous evening. The study found that deep-brain stimulation significantly improved the accuracy of their memory.

“We found that our method had a beneficial effect on both brain activity during sleep and memory performance,” says Fried. “All patients who had received synchronized stimuli to the frontal cortex demonstrated better memory performance, compared to nights of undisturbed sleep. The control group, which received similar yet unsynchronized stimuli, showed no memory improvement.

“Our deep-brain stimulation method is unique because it is close-looped — stimuli are precisely synchronized with hippocampal activity. In addition, we monitored the stimuli’s impact on brain activity at a resolution of individual neurons.”

“Our findings support the hypothesis that precise coordination between sleep waves assists communication between the hippocampus that takes in new memories, and the frontal cortex that stores them for the long term,” Nir concludes. “To our surprise, we also discovered that the intervention did not significantly increase the number of right answers given by participants, but rather reduced the number of wrong answers.

“This suggests that sleep sharpens the accuracy of our memory. In other words, it removes various distractions from the relevant memory trace.”

The study was supported by grants from the US National Institutes of Health, the European Research Council, the US National Science Foundation, the US-Israel Bilateral Science Foundation, and the Human Frontier Science Program.