UNC-Utah NA-MIC framework for DTI fiber tract analysis

Audrey R. Verde; Francois Budin; Jean Baptiste Berger; Aditya Gupta; Mahshid Farzinfar; Adrien Kaiser; Mihye Ahn; Hans Johnson; Joy Matsui; Heather C. Hazlett; Anuja Sharma; Casey Goodlett; Yundi Shi; Sylvain Gouttard; Clement Vachet; Joseph Piven; Hongtu Zhu; Guido Gerig; Martin Styner

doi:10.3389/fninf.2013.00051

UNC-Utah NA-MIC framework for DTI fiber tract analysis

Audrey R. Verde, Francois Budin, Jean Baptiste Berger, Aditya Gupta, Mahshid Farzinfar, Adrien Kaiser, Mihye Ahn, Hans Johnson, Joy Matsui, Heather C. Hazlett, Anuja Sharma, Casey Goodlett, Yundi Shi, Sylvain Gouttard, Clement Vachet, Joseph Piven, Hongtu Zhu, Guido Gerig, Martin Styner

Research output: Contribution to journal › Article › peer-review

53 Scopus citations

Abstract

Diffusion tensor imaging has become an important modality in the field of neuroimaging to capture changes in micro-organization and to assess white matter integrity or development. While there exists a number of tractography toolsets, these usually lack tools for preprocessing or to analyze diffusion properties along the fiber tracts. Currently, the field is in critical need of a coherent end-to-end toolset for performing an along-fiber tract analysis, accessible to non-technical neuroimaging researchers. The UNC-Utah NA-MIC DTI framework represents a coherent, open source, end-to-end toolset for atlas fiber tract based DTI analysis encompassing DICOM data conversion, quality control, atlas building, fiber tractography, fiber parameterization, and statistical analysis of diffusion properties. Most steps utilize graphical user interfaces (GUI) to simplify interaction and provide an extensive DTI analysis framework for non-technical researchers/investigators. We illustrate the use of our framework on a small sample, cross sectional neuroimaging study of eight healthy 1-year-old children from the Infant Brain Imaging Study (IBIS) Network. In this limited test study, we illustrate the power of our method by quantifying the diffusion properties at 1 year of age on the genu and splenium fiber tracts.

Original language	English (US)
Article number	51
Journal	Frontiers in Neuroinformatics
Volume	7
Issue number	JAN
DOIs	https://doi.org/10.3389/fninf.2013.00051
State	Published - Jan 9 2014

Keywords

DTI atlas building
Diffusion imaging quality control
Diffusion tensor imaging
Magnetic resonance imaging
Neonatal neuroimaging
White matter pathways

ASJC Scopus subject areas

Neuroscience (miscellaneous)
Biomedical Engineering
Computer Science Applications

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10.3389/fninf.2013.00051

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Verde, A. R., Budin, F., Berger, J. B., Gupta, A., Farzinfar, M., Kaiser, A., Ahn, M., Johnson, H., Matsui, J., Hazlett, H. C., Sharma, A., Goodlett, C., Shi, Y., Gouttard, S., Vachet, C., Piven, J., Zhu, H., Gerig, G., & Styner, M. (2014). UNC-Utah NA-MIC framework for DTI fiber tract analysis. Frontiers in Neuroinformatics, 7(JAN), Article 51. https://doi.org/10.3389/fninf.2013.00051

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abstract = "Diffusion tensor imaging has become an important modality in the field of neuroimaging to capture changes in micro-organization and to assess white matter integrity or development. While there exists a number of tractography toolsets, these usually lack tools for preprocessing or to analyze diffusion properties along the fiber tracts. Currently, the field is in critical need of a coherent end-to-end toolset for performing an along-fiber tract analysis, accessible to non-technical neuroimaging researchers. The UNC-Utah NA-MIC DTI framework represents a coherent, open source, end-to-end toolset for atlas fiber tract based DTI analysis encompassing DICOM data conversion, quality control, atlas building, fiber tractography, fiber parameterization, and statistical analysis of diffusion properties. Most steps utilize graphical user interfaces (GUI) to simplify interaction and provide an extensive DTI analysis framework for non-technical researchers/investigators. We illustrate the use of our framework on a small sample, cross sectional neuroimaging study of eight healthy 1-year-old children from the Infant Brain Imaging Study (IBIS) Network. In this limited test study, we illustrate the power of our method by quantifying the diffusion properties at 1 year of age on the genu and splenium fiber tracts.",

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AU - Verde, Audrey R.

AU - Budin, Francois

AU - Berger, Jean Baptiste

AU - Gupta, Aditya

AU - Farzinfar, Mahshid

AU - Kaiser, Adrien

AU - Ahn, Mihye

AU - Johnson, Hans

AU - Matsui, Joy

AU - Hazlett, Heather C.

AU - Sharma, Anuja

AU - Goodlett, Casey

AU - Shi, Yundi

AU - Gouttard, Sylvain

AU - Vachet, Clement

AU - Piven, Joseph

AU - Zhu, Hongtu

AU - Gerig, Guido

AU - Styner, Martin

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UNC-Utah NA-MIC framework for DTI fiber tract analysis

Abstract

Keywords

ASJC Scopus subject areas

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