Anne-Kristin Solbakk

Anatomical registration of intracranial electrodes. Robust model-based localization and deformable smooth brain-shift compensation methods

Abstract:

Background: Intracranial electrodes are typically localized from post-implantation CT artifacts. Automatic algorithms localizing low signal-to-noise ratio artifacts and high-density electrode arrays are missing. Additionally, implantation of grids/strips introduces brain deformations, resulting in registration errors when fusing post- implantation CT and pre-implantation MR images. Brain-shift compensation methods project electrode coordinates to cortex, but either fail to produce smooth solutions or do not account for brain deformations. New methods: We first introduce GridFit, a model-based fitting approach that simultaneously localizes all electrodes’ CT artifacts in grids, strips, or depth arrays. Second, we present CEPA, a brain-shift compensation algorithm combining orthogonal-based projections, spring-mesh models, and spatial regularization constraints. Results: We tested GridFit on ~6000 simulated scenarios. The localization of CT artifacts showed robust performance under difficult scenarios, such as noise, overlaps, and high-density implants (<1 mm errors). Validation with data from 20 challenging patients showed 99% accurate localization of the electrodes (3160/3192). We tested CEPA brain-shift compensation with data from 15 patients. Projections accounted for simple mechanical deformation principles with <0.4 mm errors. The inter-electrode distances smoothly changed across neighbor electrodes, while changes in inter-electrode distances linearly increased with projection distance. Comparison with existing methods: GridFit succeeded in difficult scenarios that challenged available methods and outperformed visual localization by preserving the inter-electrode distance. CEPA registration errors were smaller than those obtained for well-established alternatives. Additionally, modeling resting-state high-frequency activity in five patients further supported CEPA.

Authors:

  • Alejandro Omar Blenkmann

  • Sabine Liliana Leske

  • Anaïs Llorens

  • Jack J. Lin

  • Edward F. Chang

  • Peter Brunner

  • Gerwin Schalk

  • Jugoslav Ivanovic

  • Pål Gunnar Larsson

  • Robert Thomas Knight

  • Tor Endestad

  • Anne-Kristin Solbakk

Date: 2024

DOI: https://doi.org/10.1016/j.jneumeth.2024.110056

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Altered hierarchical auditory predictive processing after lesions to the orbitofrontal cortex

Abstract:

Orbitofrontal cortex (OFC) is classically linked to inhibitory control, emotion regulation, and reward processing. Recent perspectives propose that the OFC also generates predictions about perceptual events, actions, and their outcomes. We tested the role of the OFC in detecting violations of prediction at two levels of abstraction (i.e., hierarchical predictive processing) by studying the event-related potentials (ERPs) of patients with focal OFC lesions (n = 12) and healthy controls (n = 14) while they detected deviant sequences of tones in a local–global paradigm. The structural regularities of the tones were controlled at two hierarchical levels by rules defined at a local (i.e., between tones within sequences) and at a global (i.e., between sequences) level. In OFC patients, ERPs elicited by standard tones were unaffected at both local and global levels compared to controls. However, patients showed an attenuated mismatch negativity (MMN) and P3a to local prediction violation, as well as a diminished MMN followed by a delayed P3a to the combined local and global level prediction violation. The subsequent P3b component to conditions involving violations of prediction at the level of global rules was preserved in the OFC group. Comparable effects were absent in patients with lesions restricted to the lateral PFC, which lends a degree of anatomical specificity to the altered predictive processing resulting from OFC lesion. Overall, the altered magnitudes and time courses of MMN/P3a responses after lesions to the OFC indicate that the neural correlates of detection of auditory regularity violation are impacted at two hierarchical levels of rule abstraction.

Authors:

  • Olgerta Asko

  • Alejandro Omar Blenkmann

  • Sabine Liliana Leske

  • Maja Dyhre Foldal

  • Anais Llorens

  • Ingrid Funderud

  • Torstein R Meling

  • Robert T Knight

  • Tor Endestad

  • Anne-Kristin Solbakk

Date: 2024

DOI: https://doi.org/10.7554/eLife.86386

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Ramping dynamics and theta oscillations reflect dissociable signatures during rule-guided human behavior

abstract:

Contextual cues and prior evidence guide human goal-directed behavior. The neurophysiological mechanisms that implement contextual priors to guide subsequent actions in the human brain remain unclear. Using intracranial electroencephalography (iEEG), we demonstrate that increasing uncertainty introduces a shift from a purely oscillatory to a mixed processing regime with an additional ramping component. Oscillatory and ramping dynamics reflect dissociable signatures, which likely differentially contribute to the encoding and transfer of different cognitive variables in a cue-guided motor task. The results support the idea that prefrontal activity encodes rules and ensuing actions in distinct coding subspaces, while theta oscillations synchronize the prefrontal-motor network, possibly to guide action execution. Collectively, our results reveal how two key features of large-scale neural population activity, namely continuous ramping dynamics and oscillatory synchrony, jointly support rule-guided human behavior.

Authors:

  • Jan Weber

  • Anne-Kristin Solbakk

  • Alejandro O. Blenkmann

  • Anais Llorens

  • Ingrid Funderud

  • Sabine Leske

  • Pål Gunnar Larsson

  • Lugoslav Ivanovic

  • Robert T. Knight

  • Tor Endestad

  • Randolph F. Helfrich

Date: 2024

DOI: https://doi.org/10.1038/s41467-023-44571-7

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Periodic attention deficits after frontoparietal lesions provide causal evidence for rhythmic attentional sampling

Abstract:

Contemporary models conceptualize spatial attention as a blinking spotlight that sequentially samples visual space. Hence, behavior fluctuates over time, even in states of presumed ‘‘sustained’’ attention. Recent evidence has suggested that rhythmic neural activity in the frontoparietal network constitutes the functional basis of rhythmic attentional sampling. However, causal evidence to support this notion remains absent. Using a lateralized spatial attention task, we addressed this issue in patients with focal lesions in the frontoparietal attention network. Our results revealed that frontoparietal lesions introduce periodic attention deficits, i.e., temporally specific behavioral deficits that are aligned with the underlying neural oscillations. Attention guided perceptual sensitivity was on par with that of healthy controls during optimal phases but was attenuated during the less excitable sub-cycles. Theta-dependent sampling (3–8 Hz) was causally dependent on the prefrontal cortex, while high-alpha/low-beta sampling (8–14 Hz) emerged from parietal areas. Collectively, our findings reveal that lesion-induced high-amplitude, low-frequency brain activity is not epiphenomenal but has immediate behavioral consequences. More generally, these results provide causal evidence for the hypothesis that the functional architecture of attention is inherently rhythmic.

Authors:

  • Isabel Raposo

  • Sara M. Szczepanski

  • Kathleen Haaland

  • Tor Endestad

  • Anne-Kristin Solbakk

  • Robert T. Knight

  • Randolph F. Helfrich

Date: 2023

DOI: https://doi.org/10.1016/j.cub.2023.09.065

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Decision and response monitoring during working memory are sequentially represented in the human insula

Abstract:

Emerging research supports a role of the insula in human cognition. Here, we used intracranial EEG to investigate the spatiotemporal dynamics in the insula during a verbal working memory (vWM) task. We found robust effects for theta, beta, and high frequency activity (HFA) during probe presentation requiring a decision. Theta band activity showed differential involvement across left and right insulae while sequential HFA modulations were observed along the anteroposterior axis. HFA in anterior insula tracked decision making and subsequent HFA was observed in posterior insula after the behavioral response. Our results provide electrophysiological evidence of engagement of different insula subregions in both decision-making and response monitoring during vWM and expand our knowledge of the role of the insula in complex human behavior.

Authors:

  • Anaïs Llorens

  • Ludovic Bellier

  • Alejandro O. Blenkmann

  • Jugoslav Ivanovic

  • Pål G. Larsson

  • Jack J. Lin

  • Tor Endestad

  • Anne-Kristin Solbakk

  • Robert T. Knight

Date: 2023

DOI: https://doi.org/10.1016/j.isci.2023.107653

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Subspace partitioning in the human prefrontal cortex resolves cognitive interference

Abstract:

The human prefrontal cortex (PFC) constitutes the structural basis underlying flexible cognitive control, where mixed-selective neural populations encode multiple task features to guide subsequent behavior. The mechanisms by which the brain simultaneously encodes multiple task–relevant variables while minimizing interference from task-irrelevant features remain unknown. Leveraging intracranial recordings from the human PFC, we first demonstrate that competition between coexisting representations of past and present task variables incurs a behavioral switch cost. Our results reveal that this interference between past and present states in the PFC is resolved through coding partitioning into distinct low-dimensional neural states; thereby strongly attenuating behavioral switch costs. In sum, these findings uncover a fundamental coding mechanism that constitutes a central building block of flexible cognitive control.

Authors:

  • Jan Weber

  • Gabriela Iwama

  • Anne-Kristin Solbakk

  • Alejandro O. Blenkmann

  • Pal G. Larsson

  • Jugoslav Ivanovic

  • Robert T. Knight

  • Tor Endestad

  • Randolph Helfrich

Date: 2023

DOI: https://doi.org/10.1073/pnas.2220523120

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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 memory, which may contribute to confabulation in individuals with OFC damage. 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 damage 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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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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Gender bias in academia: A lifetime problem that needs solutions

Summary:

Despite increased awareness of the lack of gender equity in academia and a growing number of initiatives to address issues of diversity, change is slow, and inequalities remain. A major source of inequity is gender bias, which has a substantial negative impact on the careers, work-life balance, and mental health of underrepresented groups in science. Here, we argue that gender bias is not a single problem but manifests as a collection of distinct issues that impact researchers’ lives. We disentangle these facets and propose concrete solutions that can be adopted by individuals, academic institutions, and society.

Authors:

  • Anaïs Llorens

  • Athina Tzovara

  • Ludovic Bellier

  • Ilina Bhaya-Grossman

  • Aurélie Bidet-Caulet

  • William K Chang

  • Zachariah R Cross

  • Rosa Dominguez-Faus

  • Adeen Flinker

  • Yvonne Fonken

  • Mark A Gorenstein

  • Chris Holdgraf

  • Colin W Hoy

  • Maria V Ivanova

  • Richard T Jimenez

  • Soyeon Jun

  • Julia WY Kam

  • Celeste Kidd

  • Enitan Marcelle

  • Deborah Marciano

  • Stephanie Martin

  • Nicholas E Myers

  • Karita Ojala

  • Anat Perry

  • Pedro Pinheiro-Chagas

  • Stephanie K Riès

  • Ignacio Saez

  • Ivan Skelin

  • Katarina Slama

  • Brooke Staveland

  • Danielle S Bassett

  • Elizabeth A Buffalo

  • Adrienne L Fairhall

  • Nancy J Kopell

  • Laura J Kray

  • Jack J Lin

  • Anna C Nobre

  • Dylan Riley

  • Anne-Kristin Solbakk

  • Joni D Wallis

  • Xiao-Jing Wang

  • Shlomit Yuval-Greenberg

  • Sabine Kastner

  • Robert T Knight

  • Nina F Dronkers

Date: 2021

DOI: https://doi.org/10.1016/j.neuron.2021.06.002

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Intracranial recordings demonstrate medial temporal lobe engagement in visual search in humans

Abstract:

Visual search is a fundamental human behavior, which has been proposed to include two component processes: inefficient search (Search) and efficient search (Pop-out). According to extant research, these two processes map onto two separable neural systems located in the frontal and parietal association cortices. In the present study, we use intracranial recordings from 23 participants to delineate the neural correlates of Search and Pop-out with an unprecedented combination of spatiotemporal resolution and coverage across cortical and subcortical structures. First, we demonstrate a role for the medial temporal lobe in visual search, on par with engagement in frontal and parietal association cortex. Second, we show a gradient of increasing engagement over anatomical space from dorsal to ventral lateral frontal cortex. Third, we confirm previous work demonstrating nearly complete overlap in neural engagement across cortical regions in Search and Pop-out. We further demonstrate Pop-out selectivity manifesting as activity increase in Pop-out as compared to Search in a distributed set of sites including frontal cortex. This result is at odds with the view that Pop-out is implemented in low-level visual cortex or parietal cortex alone. Finally, we affirm a central role for the right lateral frontal cortex in Search.

Authors:

  • S. J. Katarina Slama

  • Richard Jimenez

  • Sujayam Saha

  • David King-Stephens

  • Kenneth D Laxer

  • Peter B Weber

  • Tor Endestad

  • Pål G Larsson

  • Anne-Kristin Solbakk

  • Jack J Lin

  • Robert T Knight

Date: 2021

DOI: https://doi.org/10.1162/jocn_a_01739

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Top–Down Attentional Modulation in Human Frontal Cortex: Differential Engagement during External and Internal Attention

Abstract:

Decades of electrophysiological research on top–down control converge on the role of the lateral frontal cortex in facilitating attention to behaviorally relevant external inputs. However, the involvement of frontal cortex in the top–down control of attention directed to the external versus internal environment remains poorly understood. To address this, we recorded intracranial electrocorticography while subjects directed their attention externally to tones and responded to infrequent target tones, or internally to their own thoughts while ignoring the tones. Our analyses focused on frontal and temporal cortices. We first computed the target effect, as indexed by the difference in high frequency activity (70–150 Hz) between target and standard tones. Importantly, we then compared the target effect between external and internal attention, reflecting a top–down attentional effect elicited by task demands, in each region of interest. Both frontal and temporal cortices showed target effects during external and internal attention, suggesting this effect is present irrespective of attention states. However, only the frontal cortex showed an enhanced target effect during external relative to internal attention. These findings provide electrophysiological evidence for top–down attentional modulation in the lateral frontal cortex, revealing preferential engagement with external attention.

Authors:

  • Julia WY Kam

  • Randolph F Helfrich

  • Anne-Kristin Solbakk

  • Tor Endestad

  • Pål G Larsson

  • Jack J Lin

  • Robert T Knight

Date: 2020

DOI: https://doi.org/10.1093/cercor/bhaa262

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The brain tracks auditory rhythm predictability independent of selective attention

Abstract:

The brain responds to violations of expected rhythms, due to extraction- and prediction of the temporal structure in auditory input. Yet, it is unknown how probability of rhythm violations affects the overall rhythm predictability. Another unresolved question is whether predictive processes are independent of attention processes. In this study, EEG was recorded while subjects listened to rhythmic sequences. Predictability was manipulated by changing the stimulus-onset-asynchrony (SOA deviants) for given tones in the rhythm. When SOA deviants were inserted rarely, predictability remained high, whereas predictability was lower with more frequent SOA deviants. Dichotic tone-presentation allowed for independent manipulation of attention, as specific tones of the rhythm were presented to separate ears. Attention was manipulated by instructing subjects to attend to tones in one ear only, while keeping the rhythmic structure of tones constant. The analyses of event-related potentials revealed an attenuated N1 for tones when rhythm predictability was high, while the N1 was enhanced by attention to tones. Bayesian statistics revealed no interaction between predictability and attention. A right-lateralization of attention effects, but not predictability effects, suggested potentially different cortical processes. This is the first study to show that probability of rhythm violation influences rhythm predictability, independent of attention.

Authors:

  • Maja D Foldal

  • Alejandro O Blenkmann

  • Anaïs Llorens

  • Robert T Knight

  • Anne-Kristin Solbakk

  • Tor Endestad

Date: 2020

DOI: https://doi.org/10.1038/s41598-020-64758-y

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Preservation of Interference Effects in Working Memory After Orbitofrontal Damage

Abstract:

Orbitofrontal cortex (OFC) is implicated in multiple cognitive processes, including inhibitory control, context memory, recency judgment, and choice behavior. Despite an emerging understanding of the role of OFC in memory and executive control, its necessity for core working memory (WM) operations remains undefined. Here, we assessed the impact of OFC damage on interference effects in WM using a Recent Probes task based on the Sternberg item-recognition task (1966). Subjects were asked to memorize a set of letters and then indicate whether a probe letter was presented in a particular set. Four conditions were created according to the forthcoming response (“yes”/“no”) and the recency of the probe (presented in the previous trial set or not). We compared behavioral and electroencephalography (EEG) responses between healthy subjects (n = 14) and patients with bilateral OFC damage (n = 14). Both groups had the same recency pattern of slower reaction time (RT) when the probe was presented in the previous trial but not in the current one, reflecting the proactive interference (PI). The within-group electrophysiological results showed no condition difference during letter encoding and maintenance. In contrast, event-related potentials (ERPs) to probes showed distinct within-group condition effects, and condition by group effects. The response and recency effects for controls occurred within the same time window (300–500 ms after probe onset) and were observed in two distinct spatial groups including right centro-posterior and left frontal electrodes. Both clusters showed ERP differences elicited by the response effect, and one cluster was also sensitive to the recency manipulation. Condition differences for the OFC group involved two different clusters, encompassing only left hemisphere electrodes and occurring during two consecutive time windows (345–463 ms and 565–710 ms). Both clusters were sensitive to the response effect, but no recency effect was found despite the behavioral recency effect. Although the groups had different electrophysiological responses, the maintenance of letters in WM, the evaluation of the context of the probe, and the decision to accept or reject a probed letter were preserved in OFC patients. The results suggest that neural reorganization may contribute to intact recency judgment and response after OFC damage.

Authors:

  • Anaïs Llorens

  • Ingrid Funderud

  • Alejandro O Blenkmann

  • James Lubell

  • Maja Foldal

  • Sabine Leske

  • Rene Huster

  • Torstein R Meling

  • Robert T Knight

  • Anne-Kristin Solbakk

  • Tor Endestad

Date: 2020

DOI: https://doi.org/10.3389/fnhum.2019.00445

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Default network and frontoparietal control network theta connectivity supports internal attention

Abstract:

Attending to our inner world is a fundamental cognitive phenomenon, yet its neural underpinnings remain largely unknown. Neuroimaging evidence implicates the default network (DN) and frontoparietal control network (FPCN); however, the electrophysiological basis for the interaction between these networks is unclear. Here we recorded intracranial electroencephalogram from DN and FPCN electrodes implanted in individuals undergoing presurgical monitoring for refractory epilepsy. Subjects performed an attention task during which they attended to tones (that is, externally directed attention) or ignored the tones and thought about whatever came to mind (that is, internally directed attention). Given the emerging role of theta band connectivity in attentional processes, we examined the theta power correlation between DN and two subsystems of the FPCN as a function of attention states. We found increased connectivity between DN and FPCNA during internally directed attention compared to externally directed attention, which positively correlated with attention ratings. There was no statistically significant difference between attention states in the connectivity between DN and FPCNB. Our results indicate that enhanced theta band connectivity between the DN and FPCNA is a core electrophysiological mechanism that underlies internally directed attention.

Authors:

  • Julia WY Kam

  • Jack J Lin

  • Anne-Kristin Solbakk

  • Tor Endestad

  • Pål G Larsson

  • Robert T Knight

Date: 2019

DOI: https://doi.org/10.1038/s41562-019-0717-0

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Auditory deviance detection in the human insula: An intracranial EEG study

Abstract:

The human insula is known to be involved in auditory processing, but knowledge about its precise functional role and the underlying electrophysiology is limited. To assess its role in automatic auditory deviance detection we analyzed the EEG high frequency activity (HFA; 75–145 Hz) and ERPs from 90 intracranial insular channels across 16 patients undergoing pre-surgical intracranial monitoring for epilepsy treatment. Subjects passively listened to a stream of standard and deviant tones differing in four physical dimensions: intensity, frequency, location or time. HFA responses to auditory stimuli were found in the short and long gyri, and the anterior, superior, and inferior segments of the circular sulcus of the insular cortex. Only a subset of channels in the inferior segment of the circular sulcus of the insula showed HFA deviance detection responses, i.e., a greater and longer latency response to specific deviants relative to standards. Auditory deviancy processing was also later in the insula when compared with the superior temporal cortex. ERP results were more widespread and supported the HFA insular findings. These results provide evidence that the human insula is engaged during auditory deviance detection.

Authors:

  • Alejandro O Blenkmann

  • Santiago Collavini

  • James Lubell

  • Anaïs Llorens

  • Ingrid Funderud

  • Jugoslav Ivanovic

  • Pål G Larsson

  • Torstein R Meling

  • Tristan Bekinschtein

  • Silvia Kochen

  • Tor Endestad

  • Robert T Knight

  • Anne-Kristin Solbakk

Date: 2019

DOI: https://doi.org/10.1016/j.cortex.2019.09.002

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Lesions to the fronto-parietal network impact alpha-band phase synchrony and cognitive control

Abstract:

Long-range phase synchrony in the α-oscillation band (near 10 Hz) has been proposed to facilitate information integration across anatomically segregated regions. Which areas may top-down regulate such cross-regional integration is largely unknown. We previously found that the moment-to-moment strength of high-α band (10–12 Hz) phase synchrony co-varies with activity in a fronto-parietal (FP) network. This network is critical for adaptive cognitive control functions such as cognitive flexibility required during set-shifting. Using electroencephalography (EEG) in 23 patients with focal frontal lobe lesions (resected tumors), we tested the hypothesis that the FP network is necessary for modulation of high-α band phase synchrony. Global phase-synchrony was measured using an adaptation of the phase-locking value (PLV) in a sliding window procedure, which allowed for measurement of changes in EEG-based resting-state functional connectivity across time. As hypothesized, the temporal modulation (range and standard deviation) of high-α phase synchrony was reduced as a function of FP network lesion extent, mostly due to dorsolateral prefrontal cortex (dlPFC) lesions. Furthermore, patients with dlPFC lesions exhibited reduced cognitive flexibility as measured by the Trail-Making Test (set-shifting). Our findings provide evidence that the FP network is necessary for modulatory control of high-α band long-range phase synchrony, and linked to cognitive flexibility.



Authors:

  • Sepideh Sadaghiani

  • Pascasie L Dombert

  • Marianne Løvstad

  • Ingrid Funderud

  • Torstein R Meling

  • Tor Endestad

  • Robert T Knight

  • Anne-Kristin Solbakk

  • Mark D’Esposito

Date: 2018

DOI: 10.1093/cercor/bhy296

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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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Bidirectional frontoparietal oscillatory systems support working memory

ABSTRACT

The ability to represent and select information in working memory provides the neurobiological infrastructure for human cognition. For 80 years, dominant views of working memory have focused on the key role of prefrontal cortex (PFC). However, more recent work has implicated posterior cortical regions, suggesting that PFC engagement during working memory is dependent on the degree of executive demand. We provide evidence from neurological patients with discrete PFC damage that challenges the dominant models attributing working memory to PFC-dependent systems. We show that neural oscillations, which provide a mechanism for PFC to communicate with posterior cortical regions, independently subserve communications both to and from PFC—uncovering parallel oscillatory mechanisms for working memory. Fourteen PFC patients and 20 healthy, age-matched controls performed a working memory task where they encoded, maintained, and actively processed information about pairs of common shapes. In controls, the electroencephalogram (EEG) exhibited oscillatory activity in the low-theta range over PFC and directional connectivity from PFC to parieto-occipital regions commensurate with executive processing demands. Concurrent alpha-beta oscillations were observed over parieto-occipital regions, with directional connectivity from parieto-occipital regions to PFC, regardless of processing demands. Accuracy, PFC low-theta activity, and PFC / parieto-occipital connectivity were attenuated in patients, revealing a PFC-independent, alpha-beta system. The PFC patients still demonstrated task proficiency, which indicates that the posterior alpha-beta system provides sufficient resources for working memory. Taken together, our findings reveal neurologically dissociable PFC and parieto-occipital systems and suggest that parallel, bidirectional oscillatory systems form the basis of working memory.


AUTHORS

  • Elizabeth L. Johnson

  • Callum Dewar

  • Anne-Kristin Solbakk

  • Tor Endestad

  • Torstein Meling

  • Robert T. Knight

Date: 2017

DOI: 10.1016/j.cub.2017.05.046

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