Brain Forgets Fast - One Bit Per Neuron Per Second Lost
Author: Max-Planck-Gesellschaft
Published: 2011/01/24 - Updated: 2026/02/20
Publication Type: Findings
Category Topic: Human Brain - Related Publications
Contents: Synopsis - Introduction - Main - Insights, Updates
Synopsis: This research, published in Physical Review Letters, presents findings from the Max Planck Institute for Dynamics and Self-Organization and the Bernstein Center for Computational Neuroscience in Gottingen that quantify, for the first time, the rate at which the human cerebral cortex discards stored sensory information. Using a realistic neuron model rather than the simplified versions relied on in earlier studies, the researchers determined that approximately one bit of information is lost per active neuron per second - a deletion rate so high that sensory data can only be maintained for a few neural spikes before it vanishes. These findings are relevant to anyone interested in how the brain processes and retains information, including individuals living with neurological conditions, cognitive disabilities, or age-related memory decline, as the study sheds light on the fundamental mechanics behind how and why sensory memories are so fleeting - Disabled World (DW).
- Topic Definition: Sensory Information Forgetting
Sensory information forgetting refers to the process by which the brain's cerebral cortex discards data encoded in the electrical activity patterns of its neurons. When the brain receives input from the senses, neurons communicate through rapid electrical pulses called spikes, generating unique activity patterns that serve as a real-time record of that information. Because signal transmission in cortical networks is inherently chaotic - meaning that even tiny changes in neuronal behavior can produce dramatically different outcomes - these activity patterns degrade quickly rather than persisting in stable form. The rate of this information loss, measured for the first time by researchers in Gottingen at roughly one bit per active neuron per second, means the cortex effectively operates as a processor of brief sensory snapshots rather than a long-term storage system, a finding with significant implications for neuroscience, cognitive health, and the understanding of memory disorders.
Introduction
How Quickly We Forget - Out of Mind in a Matter of Seconds
Surprising rate at which neuronal networks in the cerebral cortex delete sensory information.
The dynamics behind signal transmission in the brain are extremely chaotic. This conclusion has been reached by scientists from the Max Planck Institute for Dynamics and Self-Organization at the University of Gattingen and the Bernstein Center for Computational Neuroscience Gattingen. In addition, the Gattingen-based researchers calculated, for the first time, how quickly information stored in the activity patterns of the cerebral cortex neurons is discarded. At one bit per active neuron per second, the speed at which this information is forgotten is surprisingly high. Physical Review Letters, 105, 268104 (2010)
Main Content
The dynamics behind signal transmission in the brain are extremely chaotic.
This conclusion has been reached by scientists from the Max Planck Institute for Dynamics and Self-Organization at the University of Gattingen and the Bernstein Center for Computational Neuroscience Gattingen. In addition, the Gattingen-based researchers calculated, for the first time, how quickly information stored in the activity patterns of the cerebral cortex neurons is discarded. At one bit per active neuron per second, the speed at which this information is forgotten is surprisingly high. Physical Review Letters, 105, 268104 (2010)
The brain codes information in the form of electrical pulses, known as spikes.
Each of the brain's approximately 100 billion interconnected neurons acts as both a receiver and transmitter: these bundle all incoming electrical pulses and, under certain circumstances, forward a pulse of their own to their neighbors. In this way, each piece of information processed by the brain generates its own activity pattern. This indicates which neuron sent an impulse to its neighbors: in other words, which neuron was active, and when. Therefore, the activity pattern is a kind of communication protocol that records the exchange of information between neurons.
How reliable is such a pattern?
Do even minor changes in the neuronal communication produce a completely different pattern in the same way that a modification to a single contribution in a conversation could alter the message completely? Such behavior is defined by scientists as chaotic. In this case, the dynamic processes in the brain could not be predicted for long. In addition, the information stored in the activity pattern would be gradually lost as a result of small errors. As opposed to this, so-called stable, that is non-chaotic, dynamics would be far less error-prone. The behavior of individual neurons would then have little or no influence on the overall picture.
The new results obtained by the scientists in Gattingen have revealed that the processes in the cerebral cortex, the brain's main switching center, are extremely chaotic. The fact that the researchers used a realistic model of the neurons in their calculations for the first time was crucial. When a spike enters a neuron, an additional electric potential forms on its cell membrane. The neuron only becomes active when this potential exceeds a critical value.
"This process is very important", says Fred Wolf, head of the Theoretical Neurophysics research group at the Max Planck Institute for Dynamics and Self-Organization. "This is the only way that the uncertainty as to when a neuron becomes active can be taken into account precisely in the calculations".
Older models described the neurons in a very simplified form and did not take into account exactly how and under what conditions a spike arises.
"This gave rise to stable dynamics in some cases but non-stable dynamics in others", explains Michael Monteforte from the Max Planck Institute for Dynamics and Self-Organization, who is also a doctoral student at the Gattingen Graduate School for Neurosciences and Molecular Biosciences (GGNB).
It was thus impossible to resolve the long-established disagreement as to whether the processes in the cerebral cortex are chaotic or not, using these models.
Thanks to their more differentiated approach, the Gattingen-based researchers were able to calculate, for the first time, how quickly an activity pattern is lost through tiny changes; in other words, how it is forgotten. Approximately one bit of information disappears per active neuron per second.
"This extraordinarily high deletion rate came as a huge surprise to us", says Wolf.
It appears that information is lost in the brain as quickly as it can be "delivered" from the senses.
This has fundamental consequences for our understanding of the neural code of the cerebral cortex. Due to the high deletion rate, information about sensory input signals can only be maintained for a few spikes. These new findings therefore indicate that the dynamics of the cerebral cortex are specifically tailored to the processing of brief snapshots of the outside world.
Insights, Analysis, and Developments
Editorial Note: What stands out most about this research is how it reframes forgetting not as a flaw but as a built-in feature of brain architecture. The cerebral cortex, it turns out, is not designed to hold on to every sensory impression that comes its way - it is wired to process rapid snapshots and move on, discarding information almost as fast as it arrives. For the millions of people affected by memory-related conditions, from traumatic brain injury to age-associated cognitive decline, studies like this one offer something genuinely valuable: a clearer scientific picture of what is happening at the neuronal level when memory fails. Understanding that the brain's default mode is rapid deletion, not long-term storage, could eventually reshape how clinicians approach memory rehabilitation and how assistive technologies are designed to support those who need them most - Disabled World (DW).Attribution/Source(s): This quality-reviewed publication was selected for publishing by the editors of Disabled World (DW) due to its relevance to the disability community. Originally authored by Max-Planck-Gesellschaft and published on 2011/01/24, this content may have been edited for style, clarity, or brevity.