PLoS Computational Biology (Oct 2017)

Decoding brain activity using a large-scale probabilistic functional-anatomical atlas of human cognition.

  • Timothy N Rubin,
  • Oluwasanmi Koyejo,
  • Krzysztof J Gorgolewski,
  • Michael N Jones,
  • Russell A Poldrack,
  • Tal Yarkoni

DOI
https://doi.org/10.1371/journal.pcbi.1005649
Journal volume & issue
Vol. 13, no. 10
p. e1005649

Abstract

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A central goal of cognitive neuroscience is to decode human brain activity-that is, to infer mental processes from observed patterns of whole-brain activation. Previous decoding efforts have focused on classifying brain activity into a small set of discrete cognitive states. To attain maximal utility, a decoding framework must be open-ended, systematic, and context-sensitive-that is, capable of interpreting numerous brain states, presented in arbitrary combinations, in light of prior information. Here we take steps towards this objective by introducing a probabilistic decoding framework based on a novel topic model-Generalized Correspondence Latent Dirichlet Allocation-that learns latent topics from a database of over 11,000 published fMRI studies. The model produces highly interpretable, spatially-circumscribed topics that enable flexible decoding of whole-brain images. Importantly, the Bayesian nature of the model allows one to "seed" decoder priors with arbitrary images and text-enabling researchers, for the first time, to generate quantitative, context-sensitive interpretations of whole-brain patterns of brain activity.