Within-Individual Organization of the Human Cerebral Cortex: Networks, Global Topography, and Function.
Jingnan DuLauren M DiNicolaPeter A AngeliNoam Saadon-GrosmanWendy SunStephanie KaiserJoanna LadopoulouAihuiping XueB T Thomas YeoMark C EldaiefRandy L BucknerPublished in: bioRxiv : the preprint server for biology (2023)
The human cerebral cortex is populated by specialized regions that are organized into networks. Here we estimated networks using a Multi-Session Hierarchical Bayesian sModel (MS-HBM) applied to intensively sampled within-individual functional MRI (fMRI) data. The network estimation procedure was initially developed and tested in two participants (each scanned 31 times) and then prospectively applied to 15 new participants (each scanned 8 to 11 times). Detailed analysis of the networks revealed a global organization. Locally organized first-order sensory and motor networks were surrounded by spatially adjacent second-order networks that also linked to distant regions. Third-order networks each possessed regions distributed widely throughout association cortex. Moreover, regions of distinct third-order networks displayed side-by-side juxtapositions with a pattern that repeated similarly across multiple cortical zones. We refer to these as Supra-Areal Association Megaclusters (SAAMs). Within each SAAM, two candidate control regions were typically adjacent to three separate domain-specialized regions. Independent task data were analyzed to explore functional response properties. The somatomotor and visual first-order networks responded to body movements and visual stimulation, respectively. A subset of the second-order networks responded to transients in an oddball detection task, consistent with a role in orienting to salient or novel events. The third-order networks, including distinct regions within each SAAM, showed two levels of functional specialization. Regions linked to candidate control networks responded to working memory load across multiple stimulus domains. The remaining regions within each SAAM did not track working memory load but rather dissociated across language, social, and spatial / episodic processing domains. These results support a model of the cerebral cortex in which progressively higher-order networks nest outwards from primary sensory and motor cortices. Within the apex zones of association cortex there is specialization of large-scale networks that divides domain-flexible from domain-specialized regions repeatedly across parietal, temporal, and prefrontal cortices. We discuss implications of these findings including how repeating organizational motifs may emerge during development.
Keyphrases
- working memory
- functional connectivity
- endothelial cells
- subarachnoid hemorrhage
- computed tomography
- magnetic resonance imaging
- transcranial direct current stimulation
- lymph node
- mental health
- ms ms
- resting state
- attention deficit hyperactivity disorder
- high frequency
- deep learning
- high intensity
- pluripotent stem cells
- solid state