Torstein R. Meling

Orbitofrontal cortex governs working memory for temporal order

Abstract:

How do we think about time? Converging lesion and neuroimaging evidence indicates that orbitofrontal cortex (OFC) supports the encoding and retrieval of temporal context in long-term memory1, which may contribute to confabulation in individuals with OFC damage2. Here, we reveal that OFC damage diminishes working memory for temporal order, that is, the ability to disentangle the relative recency of events as they unfold. OFC lesions reduced working memory for temporal order but not spatial position, and individual deficits were commensurate with lesion size. Comparable effects were absent in patients with lesions restricted to lateral prefrontal cortex (PFC). Based on these findings, we propose that OFC supports understanding of the order of events. Well-documented behavioral changes in individuals with OFC damage2 may relate to impaired temporal-order understanding.

Authors:

  • Elizabeth L. Johnson

  • William K. Chang

  • Callum D. Dewar

  • Donna Sorensen

  • Jack J. Lin

  • Anne-Kristin Solbakk

  • Tor Endestad

  • Pal G. Larsson

  • Jugoslav Ivanovic

  • Torstein R. Meling

  • Donatella Scabini

  • Robert T. Knight

Date: 2022

DOI: https://doi.org/10.1016/j.cub.2022.03.074

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Lateral prefrontal cortex lesion impairs regulation of internally and externally directed attention

ABSTRACT

According to the competition account of lexical selection in word production, conceptually driven word retrieval involves the activation of a set of candidate words in left temporal cortex and competitive selection of the intended word from this set, regulated by frontal cortical mechanisms. However, the relative contribution of these brain regions to competitive lexical selection is uncertain. In the present study, five patients with left prefrontal cortex lesions (overlapping in ventral and dorsal lateral cortex), eight patients with left lateral temporal cortex lesions (overlapping in middle temporal gyrus), and 13 matched controls performed a picture-word interference task. Distractor words were semantically related or unrelated to the picture, or the name of the picture (congruent condition). Semantic interference (related vs. unrelated), tapping into competitive lexical selection, was examined. An overall semantic interference effect was observed for the control and left-temporal groups separately. The left-frontal patients did not show a reliable semantic interference effect as a group. The left-temporal patients had increased semantic interference in the error rates relative to controls. Error distribution analyses indicated that these patients had more hesitant responses for the related than for the unrelated condition. We propose that left middle temporal lesions affect the lexical activation component, making lexical selection more susceptible to errors.





AUTHORS

  • Julia W.Y. Kam

  • Anne-Kristin Solbakk

  • Tor Endestad

  • Torstein R. Meling

  • Robert T. Knight

Date: 2018

DOI: 10.1016/j.neuroimage.2018.03.063

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Orbitofrontal damage reduces auditory sensory response in humans






AUTHORS

  • Julia W.Y. Kam

  • Anne-Kristin Solbakk

  • Ingrid Funderud

  • Tor Endestad

  • Torstein R. Meling

  • Robert T. Knight

Date: 2017

DOI: 10.1016/j.cortex.2017.12.023.

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Dynamic frontotemporal systems process space and time in working memory

ABSTRACT

How do we rapidly process incoming streams of information in working memory, a cognitive mechanism central to human behavior? Dominant views of working memory focus on the prefrontal cortex (PFC), but human hippocampal recordings provide a neurophysiological signature distinct from the PFC. Are these regions independent, or do they interact in the service of working memory? We addressed this core issue in behavior by recording directly from frontotemporal sites in humans performing a visuospatial working memory task that operationalizes the types of identity and spatiotemporal information we encounter every day. Theta band oscillations drove bidirectional interactions between the PFC and medial temporal lobe (MTL; including the hippocampus). MTL theta oscillations directed the PFC preferentially during the processing of spatiotemporal information, while PFC theta oscillations directed the MTL for all types of information being processed in working memory. These findings reveal an MTL theta mechanism for processing space and time and a domain-general PFC theta mechanism, providing evidence that rapid, dynamic MTL–PFC interactions underlie working memory for everyday experiences.






AUTHORS

  • Elizabeth L. Johnson

  • Jenna N. Adams

  • Anne-Kristin Solbakk

  • Tor Endestad

  • Pål G. Larsson

  • Jugoslav Ivanovic

  • Torstein R. Meling

  • Jack J. Lin

  • Robert T. Knight

Date: 2018

DOI: 10.1371/journal.pbio.2004274

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