1. Graph Metrics of Structural Brain Networks in Individuals with Schizophrenia and Healthy Controls: Group Differences, Relationships with Intelligence, and Genetics
- Author
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Stefan Ehrlich, Rex E. Jung, Marcel A. de Reus, Scott R. Sponheim, Ronald A. Yeo, Vince D. Calhoun, Andrew R. Mayer, Beng-Choon Ho, Eric M. Morrow, Sephira G. Ryman, S. Charles Schulz, Jessica Pommy, Martijn P. van den Heuvel, Dara S. Manoach, and Human genetics
- Subjects
Male ,0301 basic medicine ,Intelligence ,Neuropsychological Tests ,Language and Linguistics ,0302 clinical medicine ,ddc:150 ,Neural Pathways ,Statistics ,Image Processing, Computer-Assisted ,Connectivity ,General Neuroscience ,White matter ,Brain ,Cognition ,Magnetic Resonance Imaging ,Multicenter Study ,Psychiatry and Mental health ,Clinical Psychology ,Principal component analysis ,Graph (abstract data type) ,Female ,Psychology ,Adult ,Linguistics and Language ,Cognitive ,Neuroscience(all) ,Non-P.H.S ,Clinical Neurology ,Research Support ,Cognitive, White matter, Graph theory, Brain, Copy number variation, Connectivity ,N.I.H ,Young Adult ,03 medical and health sciences ,Research Support, N.I.H., Extramural ,Group differences ,Kognitiv, Weiße Substanz, Graphentheorie, Gehirn, Kopierzahlvariation, Konnektivität ,Journal Article ,Humans ,ddc:610 ,Genetic Testing ,Psychiatric Status Rating Scales ,Copy number variation ,Extramural ,Genetic Variation ,Graph theory ,Clinical neurology ,030104 developmental biology ,Multicenter study ,Neurocognitive Tests ,Linear Models ,Schizophrenia ,U.S. Gov't ,Neurology (clinical) ,Cognition Disorders ,Neuroscience ,Research Support, U.S. Gov't, Non-P.H.S ,030217 neurology & neurosurgery ,Follow-Up Studies - Abstract
Objectives: One of the most prominent features of schizophrenia is relatively lower general cognitive ability (GCA). An emerging approach to understanding the roots of variation in GCA relies on network properties of the brain. In this multi-center study, we determined global characteristics of brain networks using graph theory and related these to GCA in healthy controls and individuals with schizophrenia. Methods: Participants (N=116 controls, 80 patients with schizophrenia) were recruited from four sites. GCA was represented by the first principal component of a large battery of neurocognitive tests. Graph metrics were derived from diffusion-weighted imaging. Results: The global metrics of longer characteristic path length and reduced overall connectivity predicted lower GCA across groups, and group differences were noted for both variables. Measures of clustering, efficiency, and modularity did not differ across groups or predict GCA. Follow-up analyses investigated three topological types of connectivity—connections among high degree “rich club” nodes, “feeder” connections to these rich club nodes, and “local” connections not involving the rich club. Rich club and local connectivity predicted performance across groups. In a subsample (N=101 controls, 56 patients), a genetic measure reflecting mutation load, based on rare copy number deletions, was associated with longer characteristic path length. Conclusions: Results highlight the importance of characteristic path lengths and rich club connectivity for GCA and provide no evidence for group differences in the relationships between graph metrics and GCA. (JINS, 2016, 22, 240–249)
- Published
- 2016