The roles of the <scp>LpSTS</scp> and <scp>DLPFC</scp> in self‐prioritization: A transcranial magnetic stimulation study

Liang, Qiongdan; Zhang, Bozhen; Fu, Sinan; Wang, Fei

doi:10.1002/hbm.25730

Cited by 7 publications

(3 citation statements)

References 75 publications

(100 reference statements)

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“…A closer look at the consensus predictive network revealed that the FCs of several nodes within the DMN, SN, and DAN over the frontal and temporal lobes, such as the SFG, IFG, and STG, contributed signi cantly to the model. The involvement of these regions in self-related cognition has been repeatedly reported 6, 30,31 , and our results con rmed their roles in self-processing. In addition to these high-level cortices, the current ndings highlight the role of several subcortical structures, especially the FCs between the thalamus, insula, and amygdala.…”

Section: Discussionsupporting

confidence: 87%

“…The contributing FCs were further identi ed through analyses of model coe cients and computational lesions. Based on previous theoretical and empirical studies 1,8,28,29,30,31 , we hypothesized that the medial prefrontal cortex, posterior superior temporal sulcus, and dorsolateral prefrontal cortex would signi cantly contribute to the performance of the model. The roles of other regions were also examined using our data-driven approach.…”

Section: Introductionmentioning

confidence: 99%

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Decoding individual differences in self-prioritization from the resting-state functional connectome

Zhang

Wang

2022

Preprint

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Although the self has traditionally been viewed as a higher-order mental function by most theoretical frameworks, recent research advocates a fundamental self hypothesis, viewing the self as a baseline function of the brain embedded within its spontaneous activities. This hypothesis has been behaviorally established by observed self-biased effects, but its neural embeddedness remains uncorroborated. To provide a test, we investigated the association between spontaneous neural connectivity and robust self-prioritization in a perceptual matching task using task-irrelevant functional magnetic resonance imaging in 348 participants. By decoding whole-brain connectivity patterns, the support vector regression model successfully predicted the magnitude of behavioral self-prioritization, supporting the fundamental self hypothesis. The functional connectivity among default mode, cognitive control, and salience networks served as prominent neuromarkers of self-biased behavior. We further proposed a fundamental self-network model that portrays the brain mechanisms by which the self emerges internally and regulates responses to the external environment.

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Section: Discussionsupporting

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Decoding individual differences in self-prioritization from the resting-state functional connectome

Zhang

Wang

2022

Preprint

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“…A large body of task‐based functional magnetic resonance imaging (fMRI) research has been devoted to studying the neural basis of the SPE, mainly focusing on brain regions. For example, it was suggested that the causal coupling between the medial prefrontal cortex (MPFC) and the left posterior superior temporal sulcus (LpSTS) facilitates information flow between regions sensitive to self‐relevant features (Liang et al, 2021; Sui et al, 2013; Yin et al, 2021). There is also evidence that besides the MPFC and adjacent areas, processing of self‐relevant information is associated with activity in lateral posterior areas, such as the inferior parietal lobule (IPL) (van der Meer et al, 2010), posterior cingulate cortex (PCC), bilateral angular gyrus (Yaoi et al, 2015) and anterior insular cortex (ACC) (Molnar‐Szakacs & Uddin, 2013; Perini et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Self‐prioritization is supported by interactions between large‐scale brain networks

Yankouskaya

2022

Eur J of Neuroscience

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Resting-state functional magnetic resonance imaging (fMRI) has provided solid evidence that the default mode network (DMN) is implicated in selfreferential processing. The functional connectivity of the DMN has also been observed in tasks where self-referential processing leads to self-prioritization (SPE) in perception and decision-making. However, we are less certain about whether (i) SPE solely depends on the interplay within parts of the DMN or is driven by multiple brain networks and (ii) whether SPE is associated with a unique component of interconnected networks or can be explained by related effects such as emotion prioritization. We addressed these questions by identifying and comparing topological clusters of networks involved in self-and emotion prioritization effects generated in an associative-matching task. Using network-based statistics, we found that SPE controlled by emotion is supported by a unique component of interacting networks, including the medial prefrontal part of the DMN (MPFC), frontoparietal network (FPN) and insular salience network (SN). This component emerged as a result of a focal effect confined to few connections, indicating that interaction between DMN, FPC and SN is critical to cognitive operations for the SPE. This result was validated on a separate data set. In contrast, prioritization of happy emotion was associated with a component formed by interactions between the rostral prefrontal part of SN, posterior parietal part of FPN and the MPFC, whereas sad emotion reveals a cluster of the DMN, dorsal attention network (DAN)

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The roles of the LpSTS and DLPFC in self‐prioritization: A transcranial magnetic stimulation study

Liang

Zhang

et al. 2021

Human Brain Mapping

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The Self-Attention Network (SAN) has been proposed to describe the underlying neural mechanism of the self-prioritization effect, yet the roles of the key nodes in the SAN-the left posterior superior temporal sulcus (LpSTS) and the dorsolateral prefrontal cortex (DLPFC)-still need to be clarified. One hundred and nine participants were randomly assigned into the LpSTS group, the DLPFC group, or the sham group. We used the transcranial magnetic stimulation (TMS) technique to selectively disrupt the functions of the corresponding targeted region, and observed its impacts on self-prioritization effect based on the difference between the performance of the self-matching task before and after the targeted stimulation. We analyzed both model-free performance measures and HDDM-based performance measures for the self-matching task. The results showed that the inhibition of LpSTS could lead to reduced performance in processing self-related stimuli, which establishes a causal role for the LpSTS in self-related processing and provide direct evidence to support the SAN framework. However, the results of the DLPFC group from HDDM analysis were distinct from the results based on response efficiency. Our investigation further the understanding of the differentiated roles of key nodes in the SAN in supporting the self-salience in information processing.

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The roles of the LpSTS and DLPFC in self‐prioritization: A transcranial magnetic stimulation study

Cited by 7 publications

References 75 publications

Decoding individual differences in self-prioritization from the resting-state functional connectome

Decoding individual differences in self-prioritization from the resting-state functional connectome

Self‐prioritization is supported by interactions between large‐scale brain networks

The roles of the LpSTS and DLPFC in self‐prioritization: A transcranial magnetic stimulation study

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