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GRETNA: a graph theoretical network analysis toolbox for imaging connectomics

2015· article· en· 1,472 citations· W1586771686 on OpenAlex· 10.3389/fnhum.2015.00386

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Opus teacher head0.040
GPT teacher head0.285
Teacher spread
0.245 · how far apart the two teachers sit on this one work
Validation status
score_only:v0-immature-baseline · verbatim from the scoring run: score_only means the number may rank works, and no category label ships from it

Abstract

Recent studies have suggested that the brain's structural and functional networks (i.e., connectomics) can be constructed by various imaging technologies (e.g., EEG/MEG; structural, diffusion and functional MRI) and further characterized by graph theory. Given the huge complexity of network construction, analysis and statistics, toolboxes incorporating these functions are largely lacking. Here, we developed the GRaph thEoreTical Network Analysis (GRETNA) toolbox for imaging connectomics. The GRETNA contains several key features as follows: (i) an open-source, Matlab-based, cross-platform (Windows and UNIX OS) package with a graphical user interface (GUI); (ii) allowing topological analyses of global and local network properties with parallel computing ability, independent of imaging modality and species; (iii) providing flexible manipulations in several key steps during network construction and analysis, which include network node definition, network connectivity processing, network type selection and choice of thresholding procedure; (iv) allowing statistical comparisons of global, nodal and connectional network metrics and assessments of relationship between these network metrics and clinical or behavioral variables of interest; and (v) including functionality in image preprocessing and network construction based on resting-state functional MRI (R-fMRI) data. After applying the GRETNA to a publicly released R-fMRI dataset of 54 healthy young adults, we demonstrated that human brain functional networks exhibit efficient small-world, assortative, hierarchical and modular organizations and possess highly connected hubs and that these findings are robust against different analytical strategies. With these efforts, we anticipate that GRETNA will accelerate imaging connectomics in an easy, quick and flexible manner. GRETNA is freely available on the NITRC website.

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The record

Venue
Frontiers in Human Neuroscience
Topic
Functional Brain Connectivity Studies
Field
Neuroscience
Canadian institutions
Montreal Neurological Institute and HospitalMcGill University
Funders
Natural Science Foundation of Zhejiang ProvinceNational Natural Science Foundation of China
Keywords
ConnectomicsToolboxPower graph analysisComputer scienceGraphConnectomeNeurosciencePsychologyTheoretical computer scienceFunctional connectivityProgramming language
Has abstract in OpenAlex
yes