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Open Access 25-09-2024 | Leukodystrophy | Magnetic Resonance

Quantitative MRI distinguishes different leukodystrophies and correlates with clinical measures

Authors: Menno D. Stellingwerff, Murtadha L. Al-Saady, Kwok-Shing Chan, Adam Dvorak, José P. Marques, Shannon Kolind, Daphne H. Schoenmakers, Romy van Voorst, Stefan D. Roosendaal, Frederik Barkhof, Nicole I. Wolf, Johannes Berkhof, Petra J. W. Pouwels, Marjo S. van der Knaap

Published in: European Radiology

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Abstract

Objectives

The leukodystrophy “vanishing white matter” (VWM) and “metachromatic leukodystrophy” (MLD) affect the brain's white matter, but have very different underlying pathology. We aim to determine whether quantitative MRI reflects known neuropathological differences and correlates with clinical scores in these leukodystrophies.

Methods

VWM and MLD patients and controls were prospectively included between 2020 and 2023. Clinical scores were recorded. MRI at 3 T included multi-compartment relaxometry diffusion-informed myelin water imaging (MCR-DIMWI) and multi-echo T2-relaxation imaging with compressed sensing (METRICS) to determine myelin water fractions (MWF). Multi-shell diffusion-weighted data were used for diffusion tensor imaging measures and neurite orientation dispersion and density imaging (NODDI) analysis, which estimates neurite density index, orientation dispersion index, and free water fraction. As quantitative MRI measures are age-dependent, ratios between actual and age-expected MRI measures were calculated. We performed the multilevel analysis with subsequent post-hoc and correlation tests to assess differences between groups and clinico-radiological correlations.

Results

Sixteen control (age range: 2.3–61.3 years, 8 male), 37 VWM (2.4–56.5 years, 20 male), and 14 MLD (2.2–41.7 years, 6 male) subjects were included. Neurite density index and MWF were lower in patients than in controls (p < 0.001). Free water fraction was highest in VWM (p = 0.01), but similar to controls in MLD (p = 0.99). Changes in diffusion tensor imaging measures relative to controls were generally more pronounced in VWM than in MLD. In both patient groups, MCR-DIMWI MWF correlated strongest with clinical measures.

Conclusion

Quantitative MRI correlates to clinical measures and yields differential profiles in VWM and MLD, in line with differences in neuropathology.

Key Points

Question Can quantitative MRI reflect known neuropathological differences and correlate with clinical scores for these leukodystrophies?
Finding Quantitative MRI measures, e.g., MWF, neurite density index, and free water fraction differ between leukodystrophies and controls, in correspondence to known histological differences.
Clinical relevance MRI techniques producing quantitative, biologically-specific, measures regarding the health of myelin and axons deliver more comprehensive information regarding pathological changes in leukodystrophies than current approaches, and are thus viable tools for monitoring patients and providing clinical trial outcome measures.
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Metadata
Title
Quantitative MRI distinguishes different leukodystrophies and correlates with clinical measures
Authors
Menno D. Stellingwerff
Murtadha L. Al-Saady
Kwok-Shing Chan
Adam Dvorak
José P. Marques
Shannon Kolind
Daphne H. Schoenmakers
Romy van Voorst
Stefan D. Roosendaal
Frederik Barkhof
Nicole I. Wolf
Johannes Berkhof
Petra J. W. Pouwels
Marjo S. van der Knaap
Publication date
25-09-2024
Publisher
Springer Berlin Heidelberg
Keyword
Leukodystrophy
Published in
European Radiology
Print ISSN: 0938-7994
Electronic ISSN: 1432-1084
DOI
https://doi.org/10.1007/s00330-024-11089-5