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Fast connectivity gradient approximation: maintaining spatially fine-grained connectivity gradients while reducing computational costs.

Karl-Heinz NenningTing XuArielle TambiniAlexandre Rosa FrancoDaniel S MarguliesStanley J ColcombeMichael Peter Milham
Published in: Communications biology (2024)
Brain connectome analysis suffers from the high dimensionality of connectivity data, often forcing a reduced representation of the brain at a lower spatial resolution or parcellation. This is particularly true for graph-based representations, which are increasingly used to characterize connectivity gradients, capturing patterns of systematic spatial variation in the functional connectivity structure. However, maintaining a high spatial resolution is crucial for enabling fine-grained topographical analysis and preserving subtle individual differences that might otherwise be lost. Here we introduce a computationally efficient approach to establish spatially fine-grained connectivity gradients. At its core, it leverages a set of landmarks to approximate the underlying connectivity structure at the full spatial resolution without requiring a full-scale vertex-by-vertex connectivity matrix. We show that this approach reduces computational time and memory usage while preserving informative individual features and demonstrate its application in improving brain-behavior predictions. Overall, its efficiency can remove computational barriers and enable the widespread application of connectivity gradients to capture spatial signatures of the connectome. Importantly, maintaining a spatially fine-grained resolution facilitates to characterize the spatial transitions inherent in the core concept of gradients of brain organization.
Keyphrases
  • resting state
  • functional connectivity
  • molecular dynamics
  • air pollution
  • white matter
  • single molecule
  • working memory
  • gene expression
  • blood brain barrier
  • electronic health record
  • artificial intelligence