Data-driven Clustering Reveals a Fundamental Subdivision of the Human Cortex into Two Global Systems

Overview

Journal Neuropsychologia

Specialties Neurology
Psychology

Date 2007 Nov 27

PMID 18037453

Citations 83

Authors

Yulia Golland

Polina Golland

Shlomo Bentin

Rafael Malach

Affiliations

Soon will be listed here.

Abstract

Global organizational principles are critical for understanding cortical functionality. Recently, we proposed a global sub-division of the posterior cortex into two large-scale systems. One system, labeled extrinsic, comprises the sensory-motor cortex, and is associated with the external environment. The second system, labeled intrinsic, overlaps substantially with the previously described "default-mode" network, and is likely associated with inner-oriented processing. This global partition of the cerebral cortex emerged from hemodynamic imaging data the analysis of which was constrained by pre-determined hypotheses. Here we applied a hypothesis-free, unsupervised two-class clustering algorithm (k-means) to a large set of fMRI data. The two clusters delineated by this unsupervised hypothesis-free procedure showed high anatomical consistency across individuals, and their cortical topography coincided largely with the previously determined extrinsic and intrinsic systems. These new clustering-based results confirm that the intrinsic-extrinsic subdivision constitutes a fundamental cortical divide.

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