TY - JOUR
T1 - What makes an event significant
T2 - an fMRI study on self-defining memories
AU - Monsa, Rotem
AU - Dafni-Merom, Amnon
AU - Arzy, Shahar
N1 - Publisher Copyright:
© The Author(s) 2024.
PY - 2024/7/1
Y1 - 2024/7/1
N2 - Self-defining memories are highly significant personal memories that contribute to an individual’s life story and identity. Previous research has identified 4 key subcomponents of self-defining memories: content, affect, specificity, and self-ref lection. However, these components were not tested under functional neuroimaging. In this study, we first explored how self-defining memories distinguish themselves from everyday memories (non-self-defining) through their associated brain activity. Next, we evaluated the different self-defining memory subcomponents through their activity in the underlying brain system. Participants recalled both self-defining and non-self-defining memories under functional MRI and evaluated the 4 subcomponents for each memory. Multivoxel pattern analysis uncovered a brain system closely related to the default mode network to discriminate between self-defining and non-self-defining memories. Representational similarity analysis revealed the neural coding of each subcomponent. Self-ref lection was coded mainly in the precuneus, middle and inferior frontal gyri, and cingulate, lateral occipital, and insular cortices. To a much lesser extent, content coding was primarily in the left angular gyrus and fusiform gyrus. No region was found to represent information on affect and specificity. Our findings highlight the marked difference in brain processing between significant and non-significant memories, and underscore self-ref lection as a predominant factor in the formation and maintenance of self-defining memories, inviting a reassessment of what constitutes significant memories.
AB - Self-defining memories are highly significant personal memories that contribute to an individual’s life story and identity. Previous research has identified 4 key subcomponents of self-defining memories: content, affect, specificity, and self-ref lection. However, these components were not tested under functional neuroimaging. In this study, we first explored how self-defining memories distinguish themselves from everyday memories (non-self-defining) through their associated brain activity. Next, we evaluated the different self-defining memory subcomponents through their activity in the underlying brain system. Participants recalled both self-defining and non-self-defining memories under functional MRI and evaluated the 4 subcomponents for each memory. Multivoxel pattern analysis uncovered a brain system closely related to the default mode network to discriminate between self-defining and non-self-defining memories. Representational similarity analysis revealed the neural coding of each subcomponent. Self-ref lection was coded mainly in the precuneus, middle and inferior frontal gyri, and cingulate, lateral occipital, and insular cortices. To a much lesser extent, content coding was primarily in the left angular gyrus and fusiform gyrus. No region was found to represent information on affect and specificity. Our findings highlight the marked difference in brain processing between significant and non-significant memories, and underscore self-ref lection as a predominant factor in the formation and maintenance of self-defining memories, inviting a reassessment of what constitutes significant memories.
KW - functional MRI
KW - multi-voxel pattern analysis
KW - representational similarity analysis
KW - self-defining memories
KW - self-reflection
UR - http://www.scopus.com/inward/record.url?scp=85199936267&partnerID=8YFLogxK
U2 - 10.1093/cercor/bhae303
DO - 10.1093/cercor/bhae303
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C2 - 39073379
AN - SCOPUS:85199936267
SN - 1047-3211
VL - 34
JO - Cerebral Cortex
JF - Cerebral Cortex
IS - 7
M1 - bhae303
ER -