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by Linda Faye Tidwell

Slow brain waves make neocortex especially receptive

It has been known for nearly 20 years that slow, synchronous electrical waves in the brain during deep sleep support the formation of memories. Why that is was previously unknown. Now, writing in the journal Nature Communications, a team of researchers from Charité – Universitätsmedizin Berlin posits an explanation. According to the study, the slow waves make the neocortex, the location of long-term memory, especially receptive to information. The findings could help to optimize the treatment approaches that are intended to support memory formation from outside.

How do permanent memories form? Experts believe that while we sleep, our brains replay the events of the day, moving information from the location of short-term memory, the hippocampus, to the long-term memory located in the neocortex. “Slow waves” are especially key to this process: slow, synchronous oscillations of electrical voltage in the cortex that occur during the deep sleep phase. They can be measured using an electroencephalogram (EEG). The waves originate when the electrical voltage in many neurons rises and falls simultaneously once per second.

“We’ve known for many years that these voltage fluctuations contribute to the formation of memory,” explains Prof. Jörg Geiger, director of the Institute of Neurophysiology at Charité, ECN Member and the head of the newly published study. “When slow-wave sleep is artificially augmented from outside, memory improves. But what we didn’t know until now was what exactly is happening inside the brain when this occurs, because it is extremely difficult to study the flows of information inside the human brain.”

Slow waves strengthen synapses

He and his team have now used intact human brain tissue, which is extremely rare, to clarify the processes that are very likely to underlie the formation of memory during deep sleep. According to their findings, the slow electrical waves influence the strength of synaptic connections between the neurons in the neocortex – and thus their receptivity.

For their study, the team of researchers studied intact neocortical tissue samples taken from 45 patients who had undergone neurosurgery to treat epilepsy or a brain tumor at Charité, the Evangelisches Klinikum Bethel (EvKB) hospital, or the University Medical Center Hamburg-Eppendorf (UKE). The researchers simulated the voltage fluctuations typical of slow brain waves during deep sleep in the tissue and then measured the nerve cells’ response. To achieve this, they used glass micropipettes positioned precisely down to the nanometer. To “listen in” on the communications among multiple nerve cells connected through the tissue, they used up to ten “pipette feelers” at once – an extra large number for this method, which is known as the multipatch technique.

Perfect timing contributes to memory formation

The team of researchers discovered that the synaptic connections between neurons in the neocortex are maximally enhanced at a very specific point in time during the voltage fluctuations. “The synapses work most efficiently immediately after the voltage rises from low to high,” explains Franz Xaver Mittermaier, a researcher at the Institute of Neurophysiology at Charité and the first author of the study. “During that brief time window, the cortex can be thought of as having been placed in a state of elevated readiness. If the brain plays back a memory at exactly this time, it is transferred to long-term memory especially effectively. So, slow-wave sleep evidently supports memory formation by making the neocortex particularly receptive for many short periods of time.”

Neurons in the neocortex: Slow-wave sleep strengthens the connections between them, supporting memory formation. © Charité | Sabine Grosser
Nervenzellen in der Hirnrinde: Der Slow-Wave-Schlaf verstärkt die Verbindungen zwischen ihnen und unterstützt so die Gedächtnisbildung. © Charité | Sabine Grosser

This knowledge could be used to improve memory, for example in mild cognitive impairment in the elderly. Research groups around the world are working on methods of using subtle electrical impulses – transcranial electrostimulation – or acoustic signals to influence slow waves during sleep. “Right now, though, these stimulation approaches are being optimized through trial and error, which is a laborious and time-consuming process,” Geiger says. “Our findings about the perfect timing could help with this. Now, for the first time, they allow for targeted development of methods of stimulation to boost memory formation.”

*Mittermaier FX et al. Membrane potential states gate synaptic consolidation in human neocortical tissue. Nat Commun 2024 Dec 12. doi: 10.1038/s41467-024-53901-2

Slow brain waves
Slow waves, or slow oscillations, are a type of electrical wave arising in the brain during deep sleep. “Delta” waves comprise a certain frequency range that shows up in an EEG. These are slow brain waves that can arise outside sleep as well, as part of a disease or disorder. This broader term is sometimes used synonymously with the term “slow waves.”

About the study
When surgery is performed for drug-resistant epilepsy or brain tumors, it is often medically necessary to remove small fragments of the neocortex. The resected tissue can be preserved for up to two days outside the body in an artificial nutrient solution before activity ceases. The explicit consent of patients was required in order to examine this valuable tissue for the study that has just been published. The research group is profoundly grateful to the patients for their consent. The study was conducted in close cooperation between the basic research and clinical arms of Charité and the University Clinic for Neurosurgery at Evangelisches Klinikum Bethel (EvKB) in Bielefeld and the Department of Neurosurgery at the University Medical Center Hamburg-Eppendorf (UKE). Under the leadership of the Institute of Neurophysiology, the following were involved on Charité’s side: the Department of Neurosurgery, the Department of Neurology with Experimental Neurology, the Institute of Integrative Neuroanatomy, the Neuroscience Research Center, the NeuroCure Cluster of Excellence, the Division of Pediatric Neurosurgery, and the Department of Pediatric Neurology.

Source: Press Release Charité - Universitätsmedizin Berlin

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