How rhythmic brain activities shape our perception

Contrary to our intuition, the precision with which we perceive the real world is not stable in time, rather it rhythmically fluctuates between high precision and low precision states several times per second. These fluctuations follow rhythmic electrical activities in the brain. Electrical rhythms of the brain range across different frequencies, from 1 to 250 hertz. Using these different frequencies the brain regulates how relevant information is transmitted between different brain regions.

A group of neuroscientists has critically reviewed the evidence on this subject and shows how these frequencies may determine fundamental perceptual processes in the brain.

One basic phenomenon observed throughout brain areas is that slower rhythms (approx. 4 to 8 hertz) modulate the strength of a faster rhythm (approx. 40 to 80 hertz). This is known as cross-frequency coupling. The pair of frequencies coupled to each other varies, based upon the cortical area and its function for behavior. In some instances, attention may cause nerve cells to become de-synchronized, allowing them to carry different informations, like when one string instrument plays a different melody from the rest of the orchestra. In others, attention may lead to the activation of large numbers of neurons to maximize their impact. ”These two different functions may be organized in the brain through cross frequency coupling,” says one of the authors.

The simultaneous existence of different frequency bands in the brain also helps tagging different modalities of information arriving at the same brain region. For example color and direction of a hang glider flying in the sky. “Our brain routes information about color and motion through different frequencies to higher order brain areas, just like telecommunication systems transmitting different types of information to the same receiver,” says the author.

“The rhythmic activity of neuronal networks plays a critical role for visual perception in humans and other primates,” summarizes a co-author. “Understanding how exactly these activity patterns interact and are controlled, not only helps us to better understand the neural basis of perception, but also may help to elucidate some of the perceptual deficits in neurological conditions, such as dyslexia, ADHD, and schizophrenia.”