Variable functional connectivity architecture of the preterm human brain: Impact of developmental cortical expansion and maturation

Stoecklein, Sophia; Hilgendorff, Anne; Li, Meiling; Förster, Kai; Flemmer, Andreas W.; Galiè, Franziska; Wunderlich, Stephan; Wang, Danhong; Stein, Sophie; Ehrhardt, Harald; Dietrich, Olaf; Zou, Qihong; Zhou, Shuqin; Ertl‐Wagner, Birgit; Liu, Hesheng

doi:10.1073/pnas.1907892117

Cited by 57 publications

(55 citation statements)

References 49 publications

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“…Since the advent of the spin test, numerous neuroimaging experiments have adopted it to corroborate claims about intermodal similarities (Lefèvre et al 2018;Paquola et al 2019;Schmitt et al 2019;Shafiei et al 2020;Cui et al 2020;Stoecklein et al 2020) and have extended its implementation to regionally parcellated maps (Váša et al 2018;Vázquez-Rodríguez et al 2019;Cornblath et al 2020).…”

Section: Introductionmentioning

confidence: 99%

A simple permutation-based test of intermodal correspondence

Weinstein

Vandekar²,

Adebimpe

et al. 2020

Preprint

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Many key findings in neuroimaging studies involve similarities between brain maps. While several statistical procedures have been proposed to test correspondence between maps, there remains no consensus on the correct framing of a null hypothesis or a suitable testing approach. We propose a simple yet powerful permutation-based testing procedure for assessing similarities between two modalities using subject-level data. Our proposed method is similar to traditional permutation procedures in that it involves randomly permuting subjects to generate a null distribution. However, it differs from other recently proposed methods that have involved spherical rotations of the cortical surface or spatial autocorrelation-preserving ''surrogate'' maps of the brain, which depend on strong and potentially unrealistic statistical assumptions. To address these issues, we first demonstrate in simulated data that our method is conservative in terms of type I error and has high power. Next, we illustrate that our method performs well for assessing intermodal relationships from multimodal magnetic resonance imaging data from the Philadelphia Neurodevelopmental Cohort. The proposed test rejects the null hypothesis for modalities for which there is known interdependence in structure (cortical thickness and sulcal depth) but not in cases where an association would not be predicted biologically (cortical thickness and activation on the n-back working memory task). In contrast to previous methods, our approach does not depend on strong statistical assumptions other than the independence of subjects. Notably, our method is the most flexible for analyzing intermodal correspondence within subregions of the brain and has the greatest potential to be used for generalizable statistical inference.

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Section: Introductionmentioning

confidence: 99%

A simple permutation-based test of intermodal correspondence

Weinstein

Vandekar²,

Adebimpe

et al. 2020

Preprint

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“…Several metrics that are found ubiquitously in real-world networks have been used to model brain connectivity in the neonatal brain, including local and global efficiency, small-worldness, clustering coefficient, characteristic path length and rich club coefficient [7,8,9,11,13], and often they reveal remarkable structural and functional architectural facsimiles between the newborn and adult brain [13,14,15]. Hierarchical complexity (HC) is a measure of the diversity of connectivity patterns found across hierarchically equivalent (same degree) network nodes, and it reflects the hierarchical and functionally diverse capacities of the human brain.…”

Section: Introductionmentioning

confidence: 99%

Hierarchical complexity of the macro-scale neonatal brain

Blesa

Galdi

Cox³

et al. 2020

Preprint

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The human adult structural connectome has a rich topology composed of nodal hierarchies containing highly diverse connectivity patterns, aligned to the diverse range of functional specialisations in the brain. The emergence of this hierarchical complexity in human development is unknown. Here, we substantiate the hierarchical tiers and complexity of brain networks in the newborn period, assess correspondences with hierarchical complexity in adulthood, and investigate the effect of preterm birth, a leading cause of neurocognitive impairment and atypical brain development, on hierarchical complexity. We report that the neonatal and adult structural connectomes are both composed of distinct hierarchical tiers. Consistency of ROIs is found at both ends of this hierarchy during early life and in adulthood, but significant differences are evident in intermediate tiers. The neonatal connectome is hierarchically complex in term born neonates, but hierarchically complexity is altered in association with preterm birth. This is mainly due to diversity of connectivity patterns in Tier 3, which is comprised of regions that underlie sensorimotor processing and its integration with cognitive information. For neonates and adults, the highest tier (comprising hub regions) is ordered, rather than complex, with more homogeneous connectivity patterns in structural hubs. This suggests that the brain develops first a more rigid hierarchical structure in hub regions allowing for the development of greater and more diverse functional specialisation in lower level regions, while connectivity underpinning this diversity is dysmature in infants born preterm.

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“…Differences in individual experience may contribute to measurable diversity as well. Inter-subject variability in preterm neonates and healthy adults exhibit overall similar patterns 13 , but variability increases for parts of the fronto-parietal and dorsal attention network during maturation. At the same time, genes contribute significantly to the variability of functional 14,15 , and structural 16,17 cortical networks.…”

Section: Introductionmentioning

confidence: 86%

Disentangling cortical functional connectivity strength and topography reveals divergent roles of genes and environment

Burger

Nenning

Schwartz

et al. 2021

Preprint

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The human brain varies across individuals in its morphology, function, and cognitive capacities. Variability is particularly high in phylogenetically modern regions associated with higher order cognitive abilities, but its relationship to the layout and strength of functional networks is poorly understood. In this study we disentangled the variability of two key aspects of functional connectivity: strength and topography. We then compared the genetic and environmental influences on these two features. Genetic contribution is heterogeneously distributed across the cortex and differs for strength and topography. In heteromodal areas genes predominantly affect the topography of networks, while their connectivity strength is shaped primarily by random environmental influence such as learning. We identified peak areas of genetic control of topography overlapping with parts of the processing stream from primary areas to network hubs in the default mode network, suggesting the coordination of spatial configurations across those processing pathways. These findings provide a detailed map of the diverse contribution of heritability and individual experience to the strength and topography of functional brain architecture.

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Variable functional connectivity architecture of the preterm human brain: Impact of developmental cortical expansion and maturation

Cited by 57 publications

References 49 publications

A simple permutation-based test of intermodal correspondence

A simple permutation-based test of intermodal correspondence

Hierarchical complexity of the macro-scale neonatal brain

Disentangling cortical functional connectivity strength and topography reveals divergent roles of genes and environment

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