Bridging the 3D geometrical organisation of white matter pathways across anatomical length scales and species

Hans Martin Kjer; Mariam Andersson; Yi He; Alexandra Pacureanu; Alessandro Daducci; Marco Pizzolato; Tim Salditt; Anna-Lena Robisch; Marina Eckermann; Mareike Töpperwien; Anders Bjorholm Dahl; Maria Louise Elkjær; Zsolt Illes; Maurice Ptito; Vedrana Andersen Dahl; Tim B. Dyrby

doi:10.7554/eLife.94917

Bridging the 3D geometrical organisation of white matter pathways across anatomical length scales and species

Hans Martin Kjer^*, Mariam Andersson, Yi He, Alexandra Pacureanu, Alessandro Daducci, Marco Pizzolato, Tim Salditt, Anna-Lena Robisch, Marina Eckermann, Mareike Töpperwien, Anders Bjorholm Dahl, Maria Louise Elkjær, Zsolt Illes, Maurice Ptito, Vedrana Andersen Dahl, Tim B. Dyrby^*

^*Corresponding author for this work

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Abstract

We used diffusion MRI and x-ray synchrotron imaging on monkey and mice brains to examine the organisation of fibre pathways in white matter across anatomical scales. We compared the structure in the corpus callosum and crossing fibre regions and investigated the differences in cuprizone-induced demyelination in mouse brains versus healthy controls. Our findings revealed common principles of fibre organisation that apply despite the varying patterns observed across species; small axonal fasciculi and major bundles formed laminar structures with varying angles, according to the characteristics of major pathways. Fasciculi exhibited non-straight paths around obstacles like blood vessels, comparable across the samples of varying fibre complexity and demyelination. Quantifications of fibre orientation distributions were consistent across anatomical length scales and modalities, whereas tissue anisotropy had a more complex relationship, both dependent on the field-of-view. Our study emphasises the need to balance field-of-view and voxel size when characterising white matter features across length scales.

Original language	English
Article number	RP94917
Journal	eLife
Volume	13
Number of pages	35
ISSN	2050-084X
DOIs	https://doi.org/10.7554/eLife.94917
Publication status	Published - 2024

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Kjer, H. M., Andersson, M., He, Y., Pacureanu, A., Daducci, A., Pizzolato, M., Salditt, T., Robisch, A.-L., Eckermann, M., Töpperwien, M., Bjorholm Dahl, A., Elkjær, M. L., Illes, Z., Ptito, M., Andersen Dahl, V., & Dyrby, T. B. (2024). Bridging the 3D geometrical organisation of white matter pathways across anatomical length scales and species. eLife, 13, Article RP94917. https://doi.org/10.7554/eLife.94917

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title = "Bridging the 3D geometrical organisation of white matter pathways across anatomical length scales and species",

abstract = "We used diffusion MRI and x-ray synchrotron imaging on monkey and mice brains to examine the organisation of fibre pathways in white matter across anatomical scales. We compared the structure in the corpus callosum and crossing fibre regions and investigated the differences in cuprizone-induced demyelination in mouse brains versus healthy controls. Our findings revealed common principles of fibre organisation that apply despite the varying patterns observed across species; small axonal fasciculi and major bundles formed laminar structures with varying angles, according to the characteristics of major pathways. Fasciculi exhibited non-straight paths around obstacles like blood vessels, comparable across the samples of varying fibre complexity and demyelination. Quantifications of fibre orientation distributions were consistent across anatomical length scales and modalities, whereas tissue anisotropy had a more complex relationship, both dependent on the field-of-view. Our study emphasises the need to balance field-of-view and voxel size when characterising white matter features across length scales.",

author = "Kjer, {Hans Martin} and Mariam Andersson and Yi He and Alexandra Pacureanu and Alessandro Daducci and Marco Pizzolato and Tim Salditt and Anna-Lena Robisch and Marina Eckermann and Mareike T{\"o}pperwien and {Bjorholm Dahl}, Anders and Elkj{\ae}r, {Maria Louise} and Zsolt Illes and Maurice Ptito and {Andersen Dahl}, Vedrana and Dyrby, {Tim B.}",

year = "2024",

doi = "10.7554/eLife.94917",

language = "English",

volume = "13",

journal = "eLife",

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Kjer, HM, Andersson, M, He, Y, Pacureanu, A, Daducci, A, Pizzolato, M, Salditt, T, Robisch, A-L, Eckermann, M, Töpperwien, M, Bjorholm Dahl, A, Elkjær, ML, Illes, Z, Ptito, M, Andersen Dahl, V & Dyrby, TB 2024, 'Bridging the 3D geometrical organisation of white matter pathways across anatomical length scales and species', eLife, vol. 13, RP94917. https://doi.org/10.7554/eLife.94917

TY - JOUR

T1 - Bridging the 3D geometrical organisation of white matter pathways across anatomical length scales and species

AU - Kjer, Hans Martin

AU - Andersson, Mariam

AU - He, Yi

AU - Pacureanu, Alexandra

AU - Daducci, Alessandro

AU - Pizzolato, Marco

AU - Salditt, Tim

AU - Robisch, Anna-Lena

AU - Eckermann, Marina

AU - Töpperwien, Mareike

AU - Bjorholm Dahl, Anders

AU - Elkjær, Maria Louise

AU - Illes, Zsolt

AU - Ptito, Maurice

AU - Andersen Dahl, Vedrana

AU - Dyrby, Tim B.

PY - 2024

Y1 - 2024

N2 - We used diffusion MRI and x-ray synchrotron imaging on monkey and mice brains to examine the organisation of fibre pathways in white matter across anatomical scales. We compared the structure in the corpus callosum and crossing fibre regions and investigated the differences in cuprizone-induced demyelination in mouse brains versus healthy controls. Our findings revealed common principles of fibre organisation that apply despite the varying patterns observed across species; small axonal fasciculi and major bundles formed laminar structures with varying angles, according to the characteristics of major pathways. Fasciculi exhibited non-straight paths around obstacles like blood vessels, comparable across the samples of varying fibre complexity and demyelination. Quantifications of fibre orientation distributions were consistent across anatomical length scales and modalities, whereas tissue anisotropy had a more complex relationship, both dependent on the field-of-view. Our study emphasises the need to balance field-of-view and voxel size when characterising white matter features across length scales.

AB - We used diffusion MRI and x-ray synchrotron imaging on monkey and mice brains to examine the organisation of fibre pathways in white matter across anatomical scales. We compared the structure in the corpus callosum and crossing fibre regions and investigated the differences in cuprizone-induced demyelination in mouse brains versus healthy controls. Our findings revealed common principles of fibre organisation that apply despite the varying patterns observed across species; small axonal fasciculi and major bundles formed laminar structures with varying angles, according to the characteristics of major pathways. Fasciculi exhibited non-straight paths around obstacles like blood vessels, comparable across the samples of varying fibre complexity and demyelination. Quantifications of fibre orientation distributions were consistent across anatomical length scales and modalities, whereas tissue anisotropy had a more complex relationship, both dependent on the field-of-view. Our study emphasises the need to balance field-of-view and voxel size when characterising white matter features across length scales.

U2 - 10.7554/eLife.94917

DO - 10.7554/eLife.94917

M3 - Journal article

C2 - 40019134

SN - 2050-084X

VL - 13

JO - eLife

JF - eLife

M1 - RP94917

ER -

Bridging the 3D geometrical organisation of white matter pathways across anatomical length scales and species

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