Pattern Similarity Analyses of FrontoParietal Task Coding: Individual Variation and Genetic Influences

Etzel, Joset A.; Courtney, Ya'el; Carey, Caitlin E.; Gehred, Maria Z.; Agrawal, Arpana; Braver, Todd S.

doi:10.1093/cercor/bhz301

Cited by 16 publications

(15 citation statements)

References 65 publications

(104 reference statements)

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“…Current theoretical and empirical work has suggested a domain-general cognitive control capacity ( Assem et al, 2020 ; Kan et al, 2013 ; Miyake and Friedman, 2012 ), which enables flexible adaptation of thoughts and actions to fulfill a variety of task goals and demands ( Cole et al, 2013 ; Braver, 2012 ). Yet this hypothesis could not be tested in prior studies using twin-based neuroimaging designs, since they relied on evaluating heritability of neural activation in single cognitive control tasks ( Etzel et al, 2020 ; Koten et al, 2009 ; Matthews et al, 2007 ). Our work significantly extends these prior findings by demonstrating that twin similarity effects generalize across multiple cognitive control tasks; tasks which tap into different processes within this domain (e.g., selective attention, task-switching, working memory).…”

Section: Discussionmentioning

confidence: 99%

“…Individual differences in higher cognitive processes and general fluid intelligence have been closely linked to variation in the neural activations and functional connectivity within the fronto-parietal regions ( Cole et al, 2012 ; Duncan et al, 2020 ). In our own prior work ( Etzel et al, 2020 ), we identified clear patterns of fronto-parietal genetic variation related to cognitive control, using a twin-based design and multivariate pattern similarity approach with the N-back task. Nevertheless, the current study departs from our prior one and from other neuroimaging work, in that those prior studies were able to directly estimate genetic heritability effects by incorporating dizygotic (fraternal) as well as monozygotic twins.…”

Section: Discussionmentioning

confidence: 99%

“…In particular, reliable twin activation similarity effects have been observed in functionally selective brain regions during visual tasks, such as the fusiform face area ( Polk et al, 2007 ; Pinel et al, 2015 ). Utilizing the same approach, we recently demon-strated robust patterns of twin similarity in FPN activation patterns during N-back task performance in Human Connectome Project data ( Etzel et al, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

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Frontoparietal pattern similarity analyses of cognitive control in monozygotic twins

et al. 2021

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Frontoparietal pattern similarity analyses of cognitive control in monozygotic twins

et al. 2021

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“…Obviously, our paradigm did not tap into the contribution of individual perceptional differences to the current results. As a matter of fact, interindividual variability in perception may be genetically determined ( Etzel et al, 2020 ).…”

Section: Discussionmentioning

confidence: 99%

Face Processing in Developmental Prosopagnosia: Altered Neural Representations in the Fusiform Face Area

Haeger

Pouzat²,

Luecken

et al. 2021

Front. Behav. Neurosci.

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Rationale: Face expertise is a pivotal social skill. Developmental prosopagnosia (DP), i.e., the inability to recognize faces without a history of brain damage, affects about 2% of the general population, and is a renowned model system of the face-processing network. Within this network, the right Fusiform Face Area (FFA), is particularly involved in face identity processing and may therefore be a key element in DP. Neural representations within the FFA have been examined with Representational Similarity Analysis (RSA), a data-analytical framework in which multi-unit measures of brain activity are assessed with correlation analysis.Objectives: Our study intended to scrutinize modifications of FFA-activation during face encoding and maintenance based on RSA.Methods: Thirteen participants with DP (23–70 years) and 12 healthy control subjects (19–62 years) participated in a functional MRI study, including morphological MRI, a functional FFA-localizer and a modified Sternberg paradigm probing face memory encoding and maintenance. Memory maintenance of one, two, or four faces represented low, medium, and high memory load. We examined conventional activation differences in response to working memory load and applied RSA to compute individual correlation-matrices on the voxel level. Group correlation-matrices were compared via Donsker’s random walk analysis.Results: On the functional level, increased memory load entailed both a higher absolute FFA-activation level and a higher degree of correlation between activated voxels. Both aspects were deficient in DP. Interestingly, control participants showed a homogeneous degree of correlation for successful trials during the experiment. In DP-participants, correlation levels between FFA-voxels were significantly lower and were less sustained during the experiment. In behavioral terms, DP-participants performed poorer and had longer reaction times in relation to DP-severity. Furthermore, correlation levels were negatively correlated with reaction times for the most demanding high load condition.Conclusion: We suggest that participants with DP fail to generate robust and maintained neural representations in the FFA during face encoding and maintenance, in line with poorer task performance and prolonged reaction times. In DP, alterations of neural coding in the FFA might therefore explain curtailing in working memory and contribute to impaired long-term memory and mental imagery.

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“…Comparing whole dissimilarities among all task conditions in RDM, RSA becomes an effective approach to track the multidimensional representation among task conditions. On the one hand, researchers can construct hypothesis-based RDM for different conditions, then compare these theoretical models with RDMs from real neural activities to calculate how similar they are (Alfred et al, 2018 ; Feng et al, 2018 ; Hall-McMaster et al, 2019 ; Yokoi and Diedrichsen, 2019 ; Etzel et al, 2020 ). As a result, they can infer the information is coded in the brain.…”

Section: Representational Similarity Analysis Using Neuroramentioning

confidence: 99%

NeuroRA: A Python Toolbox of Representational Analysis From Multi-Modal Neural Data

2020

Front. Neuroinform.

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In studies of cognitive neuroscience, multivariate pattern analysis (MVPA) is widely used as it offers richer information than traditional univariate analysis. Representational similarity analysis (RSA), as one method of MVPA, has become an effective decoding method based on neural data by calculating the similarity between different representations in the brain under different conditions. Moreover, RSA is suitable for researchers to compare data from different modalities and even bridge data from different species. However, previous toolboxes have been made to fit specific datasets. Here, we develop NeuroRA, a novel and easy-to-use toolbox for representational analysis. Our toolbox aims at conducting cross-modal data analysis from multi-modal neural data (e.g., EEG, MEG, fNIRS, fMRI, and other sources of neruroelectrophysiological data), behavioral data, and computer-simulated data. Compared with previous software packages, our toolbox is more comprehensive and powerful. Using NeuroRA, users can not only calculate the representational dissimilarity matrix (RDM), which reflects the representational similarity among different task conditions and conduct a representational analysis among different RDMs to achieve a cross-modal comparison. Besides, users can calculate neural pattern similarity (NPS), spatiotemporal pattern similarity (STPS), and inter-subject correlation (ISC) with this toolbox. NeuroRA also provides users with functions performing statistical analysis, storage, and visualization of results. We introduce the structure, modules, features, and algorithms of NeuroRA in this paper, as well as examples applying the toolbox in published datasets.

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Pattern Similarity Analyses of FrontoParietal Task Coding: Individual Variation and Genetic Influences

Cited by 16 publications

References 65 publications

Frontoparietal pattern similarity analyses of cognitive control in monozygotic twins

Frontoparietal pattern similarity analyses of cognitive control in monozygotic twins

Face Processing in Developmental Prosopagnosia: Altered Neural Representations in the Fusiform Face Area

NeuroRA: A Python Toolbox of Representational Analysis From Multi-Modal Neural Data

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