Spatiotemporal complexity patterns of resting‐state bioelectrical activity explain fluid intelligence: Sex matters

Dreszer, Joanna; Grochowski, Marek; Lewandowska, Monika; Nikadon, Jan; Gorgol, Joanna; Bałaj, Bibianna; Finc, Karolina; Duch, Włodzisław; Kałamała, Patrycja; Chuderski, Adam; Piotrowski, Tomasz

doi:10.1002/hbm.25162

Cited by 11 publications

(35 citation statements)

References 138 publications

(216 reference statements)

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“…Sample entropy of frontocentral channels demonstrated non-significant negative associations with intelligence at finer timescales, while sample entropy of fronto-parietal channels at coarser time scales demonstrated non-significant tendencies towards positive associations. Together, the finding of lower entropy at finer time scales and tendencies towards higher entropy at coarser time scales to be associated with higher intelligence is in line with the findings of Dreszer et al (2020) suggesting differences in local (linked to entropy at finer time scales) versus global (as reflected by entropy at coarser time scales) aspects (Vakorin et al, 2011;McIntosh et al, 2014;Courtiol et al, 2016) of intelligence-related information processes. Interestingly, it has been shown that entropy at finer time scales increases while entropy at coarser time scales decreases with increasing age (McIntosh et al, 2014), which is in regard to our observations, plausible as fluid intelligence decreases with increasing age (Schaie, 1994;Salthouse, 2010;Ghisletta et al, 2012).…”

Section: Discussionsupporting

confidence: 86%

“…Microstate A has been related to reduced activity of the temporal network (Michel and Koenig, 2018) and especially to areas implicated in phonological processing (Britz et al, 2010), which is consistent with the observation that Microstate A is more present during visualization tasks expectedly implying inhibition of left-hemispheric language areas (Milz et al, 2016). However, implications of microstate patterns on cognition are far away from being completely understood and more research is needed to clarify whether and to which extend a higher presence of microstates A may possibly reflect intrinsic dispositions for verbal processing (Dreszer et al, 2020) or visualization (Milz et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

“…In analogy to the most popular prediction frameworks in neuroimaging (connectome-based predictive modeling, CPM, Finn et al, 2015; Shen et al, 2017), the input features of this model were the means of z-normalized complexity measures positively X + and negatively X - correlated with intelligence ( p < .05): with β 0 = 0 and β 1 = 1 and the predicted intelligence score . To account for multicollinearity and the high proportion of MSE measures, MSE measures were averaged within spatial and temporal clusters (Dreszer et al, 2020). Specifically, we combined electrodes into seven spatial clusters: frontopolar (Fp1, Fp2), frontocentral (FC1, FC2, FC5, FC6), frontal (F3, F4, F7, F8), temporal (T7, T8), centroparietal (CP1, CP2, CP5, CP6), parietal (P3, P4, P7, P8, Pz), occipital (O1, O2, Oz) and aggregated the MSE values of these clusters over five time scales.…”

Section: Methodsmentioning

confidence: 99%

“…Higher intelligence has been associated with higher complexity (Jaušovec and Jaušovec, 2003; Thatcher et al, 2005; Stankova and Myshkin, 2016), Dreszner et al (2020) found both positive and negative associations, and other studies could not find any significant relation (Anokhin et al, 1999; Ueno et al, 2015). Sample characteristics (Dreszer et al, 2020), varying complexity measures (Goldberger et al, 2002; Ferenets et al, 2006), and differences in the considered time scale capturing, e.g., local vs. global processing (Vakorin et al, 2011; Courtiol et al, 2016; Dreszer et al, 2020) were proposed as contributing to this heterogeneity. Consequently, results of the existing studies are difficult to compare and highlight the need for a holistic framework simultaneously investigating the relation between intelligence and brain signal complexity with various measures, on multiple spatial and temporal scales and in different study samples.…”

Section: Introductionmentioning

confidence: 99%

“…Sufficient complexity of neural signals was hypothesized to constitute the basis for efficient neural communication (de Pasquale et al, 2016) and higher complexity was related to increased information processing capacity (Heisz and McIntosh, 2013). Further, individual variations in brain signal complexity have been associated with differences in creativity (Kaur et al, 2021), the genetic risk for psychological diseases (Li et al, 2008), and also with differences in intelligence (Dreszer et al, 2020; Lutzenberger et al, 1992). However, across-study findings on relations between individual differences in intelligence and intrinsic brain signal complexity are heterogeneous.…”

Section: Introductionmentioning

confidence: 99%

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Multimodal Brain Signal Complexity Predicts Human Intelligence

Thiele

Richter

Hilger

2022

Preprint

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Spontaneous brain activity builds the foundation for human cognitive processing during external demands. A huge number of neuroimaging studies identified specific characteristics of spontaneous (intrinsic) brain dynamics to be associated with individual differences in general cognitive ability, i.e., intelligence. However, respective research is inherently limited by low temporal resolution, thus, preventing conclusions about neural fluctuations within the range of milliseconds. Here, we used resting-state electroencephalographical (EEG) recordings from 144 healthy adults to test whether individual differences in intelligence (Raven’s Advanced Progressive Matrices scores) can be predicted from the complexity of temporally highly resolved intrinsic brain signals. We compared different operationalizations of brain signal complexity (multiscale entropy, Shannon entropy, Fuzzy entropy, and specific characteristics of microstates) in regard to their relation to intelligence. The results indicate that associations between brain signal complexity measures and intelligence are of small effect sizes (r ~ .20) and vary across different spatial and temporal scales. Specifically, higher intelligence scores were associated with lower complexity in local aspects of neural processing, and less activity in task-negative brain regions belonging to the default-mode network. Finally, we combined multiple measures of brain signal complexity to show that individual intelligence scores can be significantly predicted with a multimodal model within the sample (10-fold cross-validation) as well as in an independent sample (external replication, N = 57). In sum, our results highlight the temporal and spatial dependency of associations between intelligence and intrinsic brain dynamics, proposing multimodal approaches as promising means for future neuroscientific research on complex human traits.Significance StatementSpontaneous brain activity builds the foundation for intelligent processing - the ability of humans to adapt to various cognitive demands. Using resting-state EEG, we extracted multiple aspects of temporally highly resolved intrinsic brain dynamics to investigate their relationship with individual differences in intelligence. Single associations were of small effect sizes and varied critically across spatial and temporal scales. However, combining multiple measures in a multimodal cross-validated prediction model, allows to significantly predict individual intelligence scores in unseen participants. Our study adds to a growing body of research suggesting that observable associations between complex human traits and neural parameters might be rather small and proposes multimodal prediction approaches as promising tool to derive robust brain-behavior relations despite limited sample sizes.

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