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Models of episodic emotional memory typically concern why emotional events are more likely to be remembered than neutral events, focusing on interactions between the amygdala and other medial temporal lobe regions. But memories of emotional events can be distinguished by their affective tone and framing. We propose that the dorsomedial prefrontal cortex (dmPFC), a region that is increasingly recognized to crosscut socio-affective and cognitive domains, plays a key role in this aspect of emotional memory. After briefly reviewing the role of the dmPFC in the control of behaviors ranging from actions to emotions to social cognition, we delve into the accumulating evidence that its functions also subserve the abstraction of meaning from events and the control of memories, particularly emotional memories. Its role begins during the encoding of emotional experiences, continues through their stabilization, and endures during the retrieval of memory content. At each phase, the dmPFC participates in the integration of affective and cognitive components of memories, setting up networks and framings that either emphasize or de-emphasize emotional content. Incorporating the dmPFC into models of episodic emotional memory should provide leverage in understanding the affective tone with which experiences are brought to memory.
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This content will become publicly available on September 4, 2025
Event Segmentation Promotes the Reorganization of Emotional Memory
Abstract Event boundaries help structure the content of episodic memories by segmenting continuous experiences into discrete events. Event boundaries may also serve to preserve meaningful information within an event, thereby actively separating important memories from interfering representations imposed by past and future events. Here, we tested the hypothesis that event boundaries organize emotional memory based on changing dynamics as events unfold. We developed a novel threat-reversal learning task whereby participants encoded trial-unique exemplars from two semantic categories across three phases: preconditioning, fear acquisition, and reversal. Shock contingencies were established for one category during acquisition (CS+) and then switched to the other during reversal (CS−). Importantly, reversal either was separated by a perceptible event boundary (Experiment 1) or occurred immediately after acquisition, with no perceptible context shift (Experiment 2). In a surprise recognition memory test the next day, memory performance tracked the learning contingencies from encoding in Experiment 1, such that participants selectively recognized more threat-associated CS+ exemplars from before (retroactive) and during acquisition, but this pattern reversed toward CS− exemplars encoded during reversal. By contrast, participants with continuous encoding—without a boundary between conditioning and reversal—exhibited undifferentiated memory for exemplars from both categories encoded before acquisition and after reversal. Further analyses highlight nuanced effects of event boundaries on reversing conditioned fear, updating mnemonic generalization, and emotional biasing of temporal source memory. These findings suggest that event boundaries provide anchor points to organize memory for distinctly meaningful information, thereby adaptively structuring memory based on the content of our experiences.
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- Award ID(s):
- 1844792
- PAR ID:
- 10557991
- Publisher / Repository:
- MIT Press
- Date Published:
- Journal Name:
- Journal of Cognitive Neuroscience
- ISSN:
- 0898-929X
- Page Range / eLocation ID:
- 1 to 25
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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