Scientists have long known the brain keeps refining itself after the teenage years, but the biological “why” has been hard to pinpoint. In a new mouse study from Albert Einstein College of Medicine, researchers identify a late-adolescent remodeling process inside a key memory hub—offering a mechanistic explanation for why recall can temporarily wobble during young adulthood. The work appears today in PLOS Biology, and it reframes adolescence as a period of circuit instability rather than simple maturation.
The team focused on the retrosplenial cortex (RSP), a region that helps organize contextual memories. Their central finding involves perineuronal nets (PNNs), protective mesh-like extracellular structures that stabilize synapses and memory pathways. In late adolescence, PNNs in the RSP unexpectedly weaken, then rebuild later in adulthood—while the nearby hippocampus shows no comparable effect.
Senior author Jelena Radulovic explains that earlier developmental models suggested the relevant memory circuits mature during early adolescence. Instead, the data indicate a temporary destabilization later on. As PNN support dips, retrieval of memories formed earlier becomes less reliable, even though the memories are not permanently erased.
To test behavior, the researchers trained mice to associate a chamber with an unpleasant mild foot shock. Shortly afterward, fear memories were strong and robust. But weeks later—when animals were in the adolescent-to-young-adult window—many mice trained during early adolescence failed to show the same freezing response. Importantly, when tested again under a new context, they still responded to the original chamber later, indicating temporary accessibility rather than loss.
Mechanistically, the study links the effect to reduced structural proteins that help construct and maintain PNNs, alongside diminished TGFβ2 activity, a growth-factor signal known to support these nets. When the researchers reinforced the protective network or restored TGFβ2 function, the ability to retrieve earlier memories returned.
By mid-adulthood, previously affected memories resurfaced—often with reduced precision. Instead of responding only to the original environment, mice generalized fear to unfamiliar settings. The authors note that this resembles the human “reminiscence bump,” in which adults preferentially recall experiences from adolescence and early adulthood while remembering emotional significance more readily than exact details.
Finally, the study hints at clinical relevance. Late adolescence is a window when schizophrenia and major depression often emerge. The authors propose that if similar PNN-related circuit remodeling occurs in people, variability in this process could contribute to vulnerability in genetically susceptible individuals.
Subject of Research: Animals (mouse experimental models)
Article Title: “Retrosplenial Cortical Reorganization During Late Adolescence Introduces Instability of Contextual Memory Circuits”
News Publication Date: 17-Jul-2026
Web References: https://doi.org/10.1371/journal.pbio.3003908
References: PLOS Biology (10.1371/journal.pbio.3003908)
Image Credits: Albert Einstein College of Medicine
Keywords: memory, adolescence, brain development, retrosplenial cortex, perineuronal nets, TGFβ2, contextual fear, psychiatric disorders, circuit remodeling, synaptic stabilization








