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Massively Multidimensional Diffusion-Relaxation Correlation MRI

Narvaez, Omar ; Svenningsson, Leo LU ; Yon, Maxime LU ; Sierra, Alejandra and Topgaard, Daniel LU (2022) In Frontiers in Physics 9.
Abstract

Diverse approaches such as oscillating gradients, tensor-valued encoding, and diffusion-relaxation correlation have been used to study microstructure and heterogeneity in healthy and pathological biological tissues. Recently, acquisition schemes with free gradient waveforms exploring both the frequency-dependent and tensorial aspects of the encoding spectrum b(ω) have enabled estimation of nonparametric distributions of frequency-dependent diffusion tensors. These “D(ω)-distributions” allow investigation of restricted diffusion for each distinct component resolved in the diffusion tensor trace, anisotropy, and orientation dimensions. Likewise, multidimensional methods combining longitudinal and transverse relaxation rates, R1... (More)

Diverse approaches such as oscillating gradients, tensor-valued encoding, and diffusion-relaxation correlation have been used to study microstructure and heterogeneity in healthy and pathological biological tissues. Recently, acquisition schemes with free gradient waveforms exploring both the frequency-dependent and tensorial aspects of the encoding spectrum b(ω) have enabled estimation of nonparametric distributions of frequency-dependent diffusion tensors. These “D(ω)-distributions” allow investigation of restricted diffusion for each distinct component resolved in the diffusion tensor trace, anisotropy, and orientation dimensions. Likewise, multidimensional methods combining longitudinal and transverse relaxation rates, R1 and R2, with (ω-independent) D-distributions capitalize on the component resolution offered by the diffusion dimensions to investigate subtle differences in relaxation properties of sub-voxel water populations in the living human brain, for instance nerve fiber bundles with different orientations. By measurements on an ex vivo rat brain, we here demonstrate a “massively multidimensional” diffusion-relaxation correlation protocol joining all the approaches mentioned above. Images acquired as a function of the magnitude, normalized anisotropy, orientation, and frequency content of b(ω), as well as the repetition time and echo time, yield nonparametric D(ω)-R1-R2-distributions via a Monte Carlo data inversion algorithm. The obtained per-voxel distributions are converted to parameter maps commonly associated with conventional lower-dimensional methods as well as unique statistical descriptors reporting on the correlations between restriction, anisotropy, and relaxation.

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author
; ; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
diffusion tensor distribution, diffusion-relaxation, multidimensional diffusion, rat brain, tensor-valued encoding spectrum
in
Frontiers in Physics
volume
9
article number
793966
publisher
Frontiers Media S. A.
external identifiers
  • scopus:85120349741
ISSN
2296-424X
DOI
10.3389/fphy.2021.793966
language
English
LU publication?
yes
id
3895f3e2-0337-4e31-b7b5-37fe4fdb755a
date added to LUP
2023-01-03 16:05:29
date last changed
2023-01-10 13:09:09
@article{3895f3e2-0337-4e31-b7b5-37fe4fdb755a,
  abstract     = {{<p>Diverse approaches such as oscillating gradients, tensor-valued encoding, and diffusion-relaxation correlation have been used to study microstructure and heterogeneity in healthy and pathological biological tissues. Recently, acquisition schemes with free gradient waveforms exploring both the frequency-dependent and tensorial aspects of the encoding spectrum b(ω) have enabled estimation of nonparametric distributions of frequency-dependent diffusion tensors. These “D(ω)-distributions” allow investigation of restricted diffusion for each distinct component resolved in the diffusion tensor trace, anisotropy, and orientation dimensions. Likewise, multidimensional methods combining longitudinal and transverse relaxation rates, R<sub>1</sub> and R<sub>2,</sub> with (ω-independent) D-distributions capitalize on the component resolution offered by the diffusion dimensions to investigate subtle differences in relaxation properties of sub-voxel water populations in the living human brain, for instance nerve fiber bundles with different orientations. By measurements on an ex vivo rat brain, we here demonstrate a “massively multidimensional” diffusion-relaxation correlation protocol joining all the approaches mentioned above. Images acquired as a function of the magnitude, normalized anisotropy, orientation, and frequency content of b(ω), as well as the repetition time and echo time, yield nonparametric D(ω)-R<sub>1</sub>-R<sub>2</sub>-distributions via a Monte Carlo data inversion algorithm. The obtained per-voxel distributions are converted to parameter maps commonly associated with conventional lower-dimensional methods as well as unique statistical descriptors reporting on the correlations between restriction, anisotropy, and relaxation.</p>}},
  author       = {{Narvaez, Omar and Svenningsson, Leo and Yon, Maxime and Sierra, Alejandra and Topgaard, Daniel}},
  issn         = {{2296-424X}},
  keywords     = {{diffusion tensor distribution; diffusion-relaxation; multidimensional diffusion; rat brain; tensor-valued encoding spectrum}},
  language     = {{eng}},
  month        = {{01}},
  publisher    = {{Frontiers Media S. A.}},
  series       = {{Frontiers in Physics}},
  title        = {{Massively Multidimensional Diffusion-Relaxation Correlation MRI}},
  url          = {{http://dx.doi.org/10.3389/fphy.2021.793966}},
  doi          = {{10.3389/fphy.2021.793966}},
  volume       = {{9}},
  year         = {{2022}},
}