https://scitechdaily.com/contrary-to-previous-belief-new-study-links-brain-waves-directly-to-memory/
Neurons produce rhythmic patterns of electrical activity or oscillations in the brain, driven primarily by memory, according to a recent study. Contrary to previous beliefs, the research showed that these theta oscillations in the hippocampus were more prevalent when individuals were remembering events than experiencing them, highlighting memory as a key driver in theta activity and offering potential pathways for treating brain damage and cognitive impairments.
The findings may establish the groundwork for therapy for cognitive impairment and help improve memory.
Neurons create rhythmic electrical activity patterns within the brain. A pressing question in neuroscience is the primary driver of these rhythmic signals, known as oscillations. Researchers from the University of Arizona discovered that merely recalling events could set off these oscillations, even more than experiencing the events themselves.
The research, published in the journal Neuron, specifically focused on theta oscillations. These occur in the brain’s hippocampus during activities such as exploration, navigation, and sleep. The hippocampus plays a crucial role in the brain’s ability to remember the past.
Prior to this study, it was believed that the external environment played a more important role in driving theta oscillations, said Arne Ekstrom, professor of cognition and neural systems at the UArizona Department of Psychology and senior author of the study. But Ekstrom and his collaborators found that memory generated in the brain is the main driver of theta activity.
“Surprisingly, we found that theta oscillations in humans are more prevalent when someone is just remembering things, compared to experiencing events directly,” said lead study author Sarah Seger, a graduate student in the Department of Neuroscience.
The results of the study could have implications for treating patients with brain damage and cognitive impairments, including patients who have experienced seizures, stroke, and Parkinson’s disease, Ekstrom said. Memory could be used to create stimulations from within the brain and drive theta oscillations, which could potentially lead to improvements in memory over time, he said.
UArizona researchers collaborated on the study with researchers from the University of Texas Southwestern Medical Center in Dallas, including neurosurgeon Dr. Brad Lega and research technician Jennifer Kriegel. The researchers recruited 13 patients who were being monitored at the center in preparation for epilepsy surgery. As part of the monitoring, electrodes were implanted in the patients’ brains to detect occasional seizures. The researchers recorded the theta oscillations in the hippocampus of the brain.
The patients participated in a virtual reality experiment, in which they were given a joystick to navigate to shops in a virtual city on a computer. When they arrived at the correct destination, the virtual reality experiment was paused. The researchers asked the participants to imagine the location at which they started their navigation and instructed them to mentally navigate the route they just passed through. The researchers then compared theta oscillations during initial navigation to participants’ subsequent recollection of the route.
During the actual navigation process using the joystick, the oscillations were less frequent and shorter in duration compared to oscillations that occurred when participants were just imagining the route. So, the researchers conclude that memory is a strong driver of theta oscillations in humans.
One way to compensate for impaired cognitive function is by using cognitive training and rehabilitation, Ekstrom said.
“Basically, you take a patient who has memory impairments, and you try to teach them to be better at memory,” he said.
In the future, Ekstrom is planning to conduct this research in freely walking patients as opposed to patients in beds and find how freely navigating compares to memory with regard to brain oscillations.
“Being able to directly compare the oscillations that were present during the original experience, and during a later retrieval of that is a huge step forward in the field in terms of designing new experiments and understanding the neural basis of memory,” Seger said.
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