Rotationally invariant clustering of diffusion MRI data using spherical harmonics

Matthew George Liptrot; Francois Bernard Lauze

doi:10.1117/12.2217090

Rotationally invariant clustering of diffusion MRI data using spherical harmonics

Matthew George Liptrot, Francois Bernard Lauze

Department of Computer Science

Abstract

We present a simple approach to the voxelwise classification of brain tissue acquired with diffusion weighted MRI (DWI). The approach leverages the power of spherical harmonics to summarise the diffusion information, sampled at many points over a sphere, using only a handful of coefficients. We use simple features that are invariant to the rotation of the highly orientational diffusion data. This provides a way to directly classify voxels whose diffusion characteristics are similar yet whose primary diffusion orientations differ. Subsequent application of machine-learning to the spherical harmonic coefficients therefore may permit classification of DWI voxels according to their inferred underlying fibre properties, whilst ignoring the specifics of orientation. After smoothing apparent diffusion coefficients volumes, we apply a spherical harmonic transform, which models the multi-directional diffusion data as a collection of spherical basis functions. We use the derived coefficients as voxelwise feature vectors for classification. Using a simple Gaussian mixture model, we examined the classification performance for a range of sub-classes (3-20). The results were compared against existing alternatives for tissue classification e.g. fractional anisotropy (FA) or the standard model used by Camino.1 The approach was implemented on both two publicly-available datasets: an ex-vivo pig brain and in-vivo human brain from the Human Connectome Project (HCP). We have demonstrated how a robust classification of DWI data can be performed without the need for a model reconstruction step. This avoids the potential confounds and uncertainty that such models may impose, and has the benefit of being computable directly from the DWI volumes. As such, the method could prove useful in subsequent pre-processing stages, such as model fitting, where it could inform about individual voxel complexities and improve model parameter choice.

Original language	English
Title of host publication	Medical Imaging 2016 : Image Processing
Number of pages	7
Volume	1
Publisher	SPIE - International Society for Optical Engineering
Publication date	2016
Article number	97843C
ISBN (Print)	978-1510-60019-5
DOIs	https://doi.org/10.1117/12.2217090
Publication status	Published - 2016
Event	SPIE Medical Imaging 2016 - San Diego, United States Duration: 27 Feb 2016 → 3 Mar 2016 http://spie.org/conferences-and-exhibitions/past-conferences-and-exhibitions/medical-imaging-2016

Conference

Conference	SPIE Medical Imaging 2016
Country/Territory	United States
City	San Diego
Period	27/02/2016 → 03/03/2016
Internet address	http://spie.org/conferences-and-exhibitions/past-conferences-and-exhibitions/medical-imaging-2016

Series	Progress in Biomedical Optics and Imaging
Number	39
Volume	17
ISSN	1605-7422

Access to Document

10.1117/12.2217090

Cite this

Rotationally invariant clustering of diffusion MRI data using spherical harmonics. / Liptrot, Matthew George; Lauze, Francois Bernard.

Medical Imaging 2016: Image Processing. Vol. 1 SPIE - International Society for Optical Engineering, 2016. 97843C (Progress in Biomedical Optics and Imaging; No. 39, Vol. 17).

Research output: Chapter in Book/Report/Conference proceeding › Article in proceedings › Research › peer-review

Liptrot, MG & Lauze, FB 2016, Rotationally invariant clustering of diffusion MRI data using spherical harmonics. in Medical Imaging 2016: Image Processing. vol. 1, 97843C, SPIE - International Society for Optical Engineering, Progress in Biomedical Optics and Imaging, no. 39, vol. 17, SPIE Medical Imaging 2016, San Diego, United States, 27/02/2016. https://doi.org/10.1117/12.2217090

@inproceedings{3efaa15c36c44bfeb4214000ebdb9356,

title = "Rotationally invariant clustering of diffusion MRI data using spherical harmonics",

abstract = "We present a simple approach to the voxelwise classification of brain tissue acquired with diffusion weighted MRI (DWI). The approach leverages the power of spherical harmonics to summarise the diffusion information, sampled at many points over a sphere, using only a handful of coefficients. We use simple features that are invariant to the rotation of the highly orientational diffusion data. This provides a way to directly classify voxels whose diffusion characteristics are similar yet whose primary diffusion orientations differ. Subsequent application of machine-learning to the spherical harmonic coefficients therefore may permit classification of DWI voxels according to their inferred underlying fibre properties, whilst ignoring the specifics of orientation. After smoothing apparent diffusion coefficients volumes, we apply a spherical harmonic transform, which models the multi-directional diffusion data as a collection of spherical basis functions. We use the derived coefficients as voxelwise feature vectors for classification. Using a simple Gaussian mixture model, we examined the classification performance for a range of sub-classes (3-20). The results were compared against existing alternatives for tissue classification e.g. fractional anisotropy (FA) or the standard model used by Camino.1 The approach was implemented on both two publicly-available datasets: an ex-vivo pig brain and in-vivo human brain from the Human Connectome Project (HCP). We have demonstrated how a robust classification of DWI data can be performed without the need for a model reconstruction step. This avoids the potential confounds and uncertainty that such models may impose, and has the benefit of being computable directly from the DWI volumes. As such, the method could prove useful in subsequent pre-processing stages, such as model fitting, where it could inform about individual voxel complexities and improve model parameter choice. ",

author = "Liptrot, {Matthew George} and Lauze, {Francois Bernard}",

year = "2016",

doi = "10.1117/12.2217090",

language = "English",

isbn = "978-1510-60019-5",

volume = "1",

series = "Progress in Biomedical Optics and Imaging",

publisher = "SPIE - International Society for Optical Engineering",

number = "39",

booktitle = "Medical Imaging 2016",

note = "SPIE Medical Imaging 2016 ; Conference date: 27-02-2016 Through 03-03-2016",

url = "http://spie.org/conferences-and-exhibitions/past-conferences-and-exhibitions/medical-imaging-2016",

}

TY - GEN

T1 - Rotationally invariant clustering of diffusion MRI data using spherical harmonics

AU - Liptrot, Matthew George

AU - Lauze, Francois Bernard

PY - 2016

Y1 - 2016

N2 - We present a simple approach to the voxelwise classification of brain tissue acquired with diffusion weighted MRI (DWI). The approach leverages the power of spherical harmonics to summarise the diffusion information, sampled at many points over a sphere, using only a handful of coefficients. We use simple features that are invariant to the rotation of the highly orientational diffusion data. This provides a way to directly classify voxels whose diffusion characteristics are similar yet whose primary diffusion orientations differ. Subsequent application of machine-learning to the spherical harmonic coefficients therefore may permit classification of DWI voxels according to their inferred underlying fibre properties, whilst ignoring the specifics of orientation. After smoothing apparent diffusion coefficients volumes, we apply a spherical harmonic transform, which models the multi-directional diffusion data as a collection of spherical basis functions. We use the derived coefficients as voxelwise feature vectors for classification. Using a simple Gaussian mixture model, we examined the classification performance for a range of sub-classes (3-20). The results were compared against existing alternatives for tissue classification e.g. fractional anisotropy (FA) or the standard model used by Camino.1 The approach was implemented on both two publicly-available datasets: an ex-vivo pig brain and in-vivo human brain from the Human Connectome Project (HCP). We have demonstrated how a robust classification of DWI data can be performed without the need for a model reconstruction step. This avoids the potential confounds and uncertainty that such models may impose, and has the benefit of being computable directly from the DWI volumes. As such, the method could prove useful in subsequent pre-processing stages, such as model fitting, where it could inform about individual voxel complexities and improve model parameter choice.

AB - We present a simple approach to the voxelwise classification of brain tissue acquired with diffusion weighted MRI (DWI). The approach leverages the power of spherical harmonics to summarise the diffusion information, sampled at many points over a sphere, using only a handful of coefficients. We use simple features that are invariant to the rotation of the highly orientational diffusion data. This provides a way to directly classify voxels whose diffusion characteristics are similar yet whose primary diffusion orientations differ. Subsequent application of machine-learning to the spherical harmonic coefficients therefore may permit classification of DWI voxels according to their inferred underlying fibre properties, whilst ignoring the specifics of orientation. After smoothing apparent diffusion coefficients volumes, we apply a spherical harmonic transform, which models the multi-directional diffusion data as a collection of spherical basis functions. We use the derived coefficients as voxelwise feature vectors for classification. Using a simple Gaussian mixture model, we examined the classification performance for a range of sub-classes (3-20). The results were compared against existing alternatives for tissue classification e.g. fractional anisotropy (FA) or the standard model used by Camino.1 The approach was implemented on both two publicly-available datasets: an ex-vivo pig brain and in-vivo human brain from the Human Connectome Project (HCP). We have demonstrated how a robust classification of DWI data can be performed without the need for a model reconstruction step. This avoids the potential confounds and uncertainty that such models may impose, and has the benefit of being computable directly from the DWI volumes. As such, the method could prove useful in subsequent pre-processing stages, such as model fitting, where it could inform about individual voxel complexities and improve model parameter choice.

U2 - 10.1117/12.2217090

DO - 10.1117/12.2217090

M3 - Article in proceedings

SN - 978-1510-60019-5

VL - 1

T3 - Progress in Biomedical Optics and Imaging

BT - Medical Imaging 2016

PB - SPIE - International Society for Optical Engineering

T2 - SPIE Medical Imaging 2016

Y2 - 27 February 2016 through 3 March 2016

ER -