A Nonparametric Approach for Estimating Three-Dimensional Fiber Orientation Distribution Functions (ODFs) in Fibrous Materials

Adam Rauff; Lucas H. Timmins; Ross T. Whitaker; Jeffrey A. Weiss

doi:10.1109/TMI.2021.3115716

A Nonparametric Approach for Estimating Three-Dimensional Fiber Orientation Distribution Functions (ODFs) in Fibrous Materials

Adam Rauff, Lucas H. Timmins, Ross T. Whitaker, Jeffrey A. Weiss

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

4 Scopus citations

Abstract

Many biological tissues contain an underlying fibrous microstructure that is optimized to suit a physiological function. The fiber architecture dictates physical characteristics such as stiffness, diffusivity, and electrical conduction. Abnormal deviations of fiber architecture are often associated with disease. Thus, it is useful to characterize fiber network organization from image data in order to better understand pathological mechanisms. We devised a method to quantify distributions of fiber orientations based on the Fourier transform and the Qball algorithm from diffusion MRI. The Fourier transform was used to decompose images into directional components, while the Qball algorithm efficiently converted the directional data from the frequency domain to the orientation domain. The representation in the orientation domain does not require any particular functional representation, and thus the method is nonparametric. The algorithm was verified to demonstrate its reliability and used on datasets from microscopy to show its applicability. This method increases the ability to extract information of microstructural fiber organization from experimental data that will enhance our understanding of structure-function relationships and enable accurate representation of material anisotropy in biological tissues.

Original language	English (US)
Pages (from-to)	446-455
Number of pages	10
Journal	IEEE Transactions on Medical Imaging
Volume	41
Issue number	2
DOIs	https://doi.org/10.1109/TMI.2021.3115716
State	Published - Feb 1 2022

Keywords

Fibers
Fourier transform
Nonparametric distributions
Orientation distribution function (ODF)

ASJC Scopus subject areas

Software
Radiological and Ultrasound Technology
Computer Science Applications
Electrical and Electronic Engineering

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10.1109/TMI.2021.3115716

Cite this

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title = "A Nonparametric Approach for Estimating Three-Dimensional Fiber Orientation Distribution Functions (ODFs) in Fibrous Materials",

abstract = "Many biological tissues contain an underlying fibrous microstructure that is optimized to suit a physiological function. The fiber architecture dictates physical characteristics such as stiffness, diffusivity, and electrical conduction. Abnormal deviations of fiber architecture are often associated with disease. Thus, it is useful to characterize fiber network organization from image data in order to better understand pathological mechanisms. We devised a method to quantify distributions of fiber orientations based on the Fourier transform and the Qball algorithm from diffusion MRI. The Fourier transform was used to decompose images into directional components, while the Qball algorithm efficiently converted the directional data from the frequency domain to the orientation domain. The representation in the orientation domain does not require any particular functional representation, and thus the method is nonparametric. The algorithm was verified to demonstrate its reliability and used on datasets from microscopy to show its applicability. This method increases the ability to extract information of microstructural fiber organization from experimental data that will enhance our understanding of structure-function relationships and enable accurate representation of material anisotropy in biological tissues.",

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author = "Adam Rauff and Timmins, {Lucas H.} and Whitaker, {Ross T.} and Weiss, {Jeffrey A.}",

note = "Funding Information: Manuscript received August 31, 2021; accepted September 17, 2021. Date of publication September 24, 2021; date of current version February 2, 2022. The work of Adam Rauff was supported in part by NIH Heart, Lung, and Blood Institute under Grant F31HL154781. The work of Jeffrey A. Weiss was supported by NIH Heart, Lung, and Blood Institute under Grant R01HL131856-01A1. (Corresponding author: Jeffrey A. Weiss.) Adam Rauff, Lucas H. Timmins, and Jeffrey A. Weiss are with the Scientific Computing and Imaging Institute, The University of Utah, Salt Lake City, UT 84112 USA, and also with the Department of Biomedical Engineering, The University of Utah, Salt Lake City, UT 84112 USA (e-mail: [email protected]; [email protected]; [email protected]). Publisher Copyright: {\textcopyright} 1982-2012 IEEE.",

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N1 - Funding Information: Manuscript received August 31, 2021; accepted September 17, 2021. Date of publication September 24, 2021; date of current version February 2, 2022. The work of Adam Rauff was supported in part by NIH Heart, Lung, and Blood Institute under Grant F31HL154781. The work of Jeffrey A. Weiss was supported by NIH Heart, Lung, and Blood Institute under Grant R01HL131856-01A1. (Corresponding author: Jeffrey A. Weiss.) Adam Rauff, Lucas H. Timmins, and Jeffrey A. Weiss are with the Scientific Computing and Imaging Institute, The University of Utah, Salt Lake City, UT 84112 USA, and also with the Department of Biomedical Engineering, The University of Utah, Salt Lake City, UT 84112 USA (e-mail: [email protected]; [email protected]; [email protected]). Publisher Copyright: © 1982-2012 IEEE.

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N2 - Many biological tissues contain an underlying fibrous microstructure that is optimized to suit a physiological function. The fiber architecture dictates physical characteristics such as stiffness, diffusivity, and electrical conduction. Abnormal deviations of fiber architecture are often associated with disease. Thus, it is useful to characterize fiber network organization from image data in order to better understand pathological mechanisms. We devised a method to quantify distributions of fiber orientations based on the Fourier transform and the Qball algorithm from diffusion MRI. The Fourier transform was used to decompose images into directional components, while the Qball algorithm efficiently converted the directional data from the frequency domain to the orientation domain. The representation in the orientation domain does not require any particular functional representation, and thus the method is nonparametric. The algorithm was verified to demonstrate its reliability and used on datasets from microscopy to show its applicability. This method increases the ability to extract information of microstructural fiber organization from experimental data that will enhance our understanding of structure-function relationships and enable accurate representation of material anisotropy in biological tissues.

AB - Many biological tissues contain an underlying fibrous microstructure that is optimized to suit a physiological function. The fiber architecture dictates physical characteristics such as stiffness, diffusivity, and electrical conduction. Abnormal deviations of fiber architecture are often associated with disease. Thus, it is useful to characterize fiber network organization from image data in order to better understand pathological mechanisms. We devised a method to quantify distributions of fiber orientations based on the Fourier transform and the Qball algorithm from diffusion MRI. The Fourier transform was used to decompose images into directional components, while the Qball algorithm efficiently converted the directional data from the frequency domain to the orientation domain. The representation in the orientation domain does not require any particular functional representation, and thus the method is nonparametric. The algorithm was verified to demonstrate its reliability and used on datasets from microscopy to show its applicability. This method increases the ability to extract information of microstructural fiber organization from experimental data that will enhance our understanding of structure-function relationships and enable accurate representation of material anisotropy in biological tissues.

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A Nonparametric Approach for Estimating Three-Dimensional Fiber Orientation Distribution Functions (ODFs) in Fibrous Materials

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Keywords

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