Brain Circuit Identifies What’s Familiar, Important, or Just Noise

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https://neurosciencenews.com/familiar-important-background-neuroscience-24832/

Brain Circuit Identifies What’s Familiar, Important, or Just Background Noise

February 19, 2025

Summary:

Scientists have identified a previously unknown brain circuit that rapidly evaluates sensory information by integrating memories and emotions. This direct feedback loop between the entorhinal cortex and hippocampus allows the brain to prioritize important sights and sounds almost instantly.

Unlike the slower, previously known pathway, this circuit may help distinguish relevant stimuli from background noise, with implications for conditions like PTSD and autism. The discovery advances understanding of how the brain filters information and may lead to new strategies for treating sensory and memory-related disorders.

Key Facts:

● New Brain Circuit Identified: A direct feedback loop connects the hippocampus and entorhinal cortex, prioritizing sensory information.

● Fast Learning & Memory Integration: This pathway enables rapid tagging of stimuli as familiar or important.

● Clinical Implications: The findings could help address PTSD, autism, and memory-related disorders.

A  newly identified part of a brain circuit mixes sensory information, memories, and emotions to tell whether things are familiar or new, and important or just “background noise.”

Led by researchers from NYU Langone Health, the work found that a circuit known to carry messages from a brain region that processes sensory information, the entorhinal cortex (EC), to the memory processing center in the hippocampus (HC) has a previously unrecognized pathway that carries messages directly back to the EC.

“The differences we found in their wiring, timing, and location suggest that the loops have separate but parallel roles that let them work together to encode even more complex information,” added Basu, faculty in the Institute for Translational Neuroscience at NYU Langone Health and a recent winner of the Presidential Early Career Award for Scientists and Engineers.

A better understanding of the interplay between the two brain regions may yield new solutions to problems within related circuits, researchers say, like those seen in patients with post-traumatic stress disorder who struggle to tell apart past trauma from current loud noises, or in the sensory overload experienced by some children with autism as they try to tell apart objects or interact with people.

Delicate Signals:

The long-understood model of the studied circuit posits that the hippocampus (HC) receives sensory information about the outside world from entorhinal cortex (EC) surface layers 2 and 3, but sends back signals to the EC only by indirectly wiring first into a deep EC layer (layer 5), which then routes them into EC surface layers 2 and 3. The indirect route can cause time lags that change the HC feedback signals.

Using modern methods, the current research team found a second loop that directly connects the HC to EC layers 2 and 3, letting memories and emotions stored in the HC quickly add weight to perceived sights and sounds as part of learning.

A paradox in the field has been that there i

s no known direct pathway connecting the hippocampal memory center with the brain’s emotional center, the amygdala. The newfound connections to the EC may serve as a crossroads.

Other results of the study map connections between brain cells based on their ability to pump charged particles through channels, building up charge imbalances (potentials) along their membranes.

Upon receiving the right signal, cells open their channels, enabling the particles to rush out (depolarize) under electrochemical force, with charge flows acting like switches.

Brain cells in signaling pathways “fire” as their membrane potential shift, which causes each nerve cell’s extensions (axons) to depolarize until the electric pulse reaches a synapse, a gap between one cell and the next.

When it reaches a gap, the electric pulse is converted into a chemical signal that either turns up (excites) or turns downs (inhibits) the strength of the message passed to the next cell, with their mixture sculpting signals underlying thoughts and memories.

Importantly, the current study measured these properties for the first time in both loops. Dr. Basu’s team found the previously known indirect loop to be excitatory, often triggering all-or-nothing signals called action potentials, large depolarizations that encode information based on their frequency.

The new direct feedback loop, however, in response to the same range of incoming signal strength, was found to recruit strong inhibition in brain cells (neurons) in EC layers 2 and 3, never eliciting action potentials.

This newfound circuit activity instead sends small depolarizing potentials from the HC to EC layers 2 and 3. The authors say these delicate, repeated signals can combine with messages from other brain regions to make possible more intricate computations, accelerated learning, and greater plasticity, the strengthening of connections between neurons.

Moving forward, the research team plans to study how hippocampal output related to emotions and memories shapes decision-making functions in prefrontal cortex or the emotional coding of fear in the amygdala.

The team will also examine what happens to their newfound direct circuit over the course of aging and in Alzheimer’s disease in study mice, and its parallels in humans.