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The role of spatial embedding in mouse brain networks constructed from diffusion tractography and tracer injections

Diffusion MRI tractography is the only noninvasive method to measure the structural connectome in humans. However, recent validation studies have revealed limitations of modern tractography approaches, which lead to significant mistracking caused in part by local uncertainties in fiber orientations...

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Autores principales: Trinkle, Scott, Foxley, Sean, Wildenberg, Gregg, Kasthuri, Narayanan, La Rivière, Patrick
Formato: Online Artículo Texto
Lenguaje:English
Publicado: 2021
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8611903/
https://www.ncbi.nlm.nih.gov/pubmed/34520833
http://dx.doi.org/10.1016/j.neuroimage.2021.118576
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author Trinkle, Scott
Foxley, Sean
Wildenberg, Gregg
Kasthuri, Narayanan
La Rivière, Patrick
author_facet Trinkle, Scott
Foxley, Sean
Wildenberg, Gregg
Kasthuri, Narayanan
La Rivière, Patrick
author_sort Trinkle, Scott
collection PubMed
description Diffusion MRI tractography is the only noninvasive method to measure the structural connectome in humans. However, recent validation studies have revealed limitations of modern tractography approaches, which lead to significant mistracking caused in part by local uncertainties in fiber orientations that accumulate to produce larger errors for longer streamlines. Characterizing the role of this length bias in tractography is complicated by the true underlying contribution of spatial embedding to brain topology. In this work, we compare graphs constructed with ex vivo tractography data in mice and neural tracer data from the Allen Mouse Brain Connectivity Atlas to random geometric surrogate graphs which preserve the low-order distance effects from each modality in order to quantify the role of geometry in various network properties. We find that geometry plays a substantially larger role in determining the topology of graphs produced by tractography than graphs produced by tracers. Tractography underestimates weights at long distances compared to neural tracers, which leads tractography to place network hubs close to the geometric center of the brain, as do corresponding tractography-derived random geometric surrogates, while tracer graphs place hubs further into peripheral areas of the cortex. We also explore the role of spatial embedding in modular structure, network efficiency and other topological measures in both modalities. Throughout, we compare the use of two different tractography streamline node assignment strategies and find that the overall differences between tractography approaches are small relative to the differences between tractography- and tracer-derived graphs. These analyses help quantify geometric biases inherent to tractography and promote the use of geometric benchmarking in future tractography validation efforts.
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spelling pubmed-86119032021-12-01 The role of spatial embedding in mouse brain networks constructed from diffusion tractography and tracer injections Trinkle, Scott Foxley, Sean Wildenberg, Gregg Kasthuri, Narayanan La Rivière, Patrick Neuroimage Article Diffusion MRI tractography is the only noninvasive method to measure the structural connectome in humans. However, recent validation studies have revealed limitations of modern tractography approaches, which lead to significant mistracking caused in part by local uncertainties in fiber orientations that accumulate to produce larger errors for longer streamlines. Characterizing the role of this length bias in tractography is complicated by the true underlying contribution of spatial embedding to brain topology. In this work, we compare graphs constructed with ex vivo tractography data in mice and neural tracer data from the Allen Mouse Brain Connectivity Atlas to random geometric surrogate graphs which preserve the low-order distance effects from each modality in order to quantify the role of geometry in various network properties. We find that geometry plays a substantially larger role in determining the topology of graphs produced by tractography than graphs produced by tracers. Tractography underestimates weights at long distances compared to neural tracers, which leads tractography to place network hubs close to the geometric center of the brain, as do corresponding tractography-derived random geometric surrogates, while tracer graphs place hubs further into peripheral areas of the cortex. We also explore the role of spatial embedding in modular structure, network efficiency and other topological measures in both modalities. Throughout, we compare the use of two different tractography streamline node assignment strategies and find that the overall differences between tractography approaches are small relative to the differences between tractography- and tracer-derived graphs. These analyses help quantify geometric biases inherent to tractography and promote the use of geometric benchmarking in future tractography validation efforts. 2021-09-11 2021-12-01 /pmc/articles/PMC8611903/ /pubmed/34520833 http://dx.doi.org/10.1016/j.neuroimage.2021.118576 Text en https://creativecommons.org/licenses/by/4.0/This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/ (https://creativecommons.org/licenses/by/4.0/) )
spellingShingle Article
Trinkle, Scott
Foxley, Sean
Wildenberg, Gregg
Kasthuri, Narayanan
La Rivière, Patrick
The role of spatial embedding in mouse brain networks constructed from diffusion tractography and tracer injections
title The role of spatial embedding in mouse brain networks constructed from diffusion tractography and tracer injections
title_full The role of spatial embedding in mouse brain networks constructed from diffusion tractography and tracer injections
title_fullStr The role of spatial embedding in mouse brain networks constructed from diffusion tractography and tracer injections
title_full_unstemmed The role of spatial embedding in mouse brain networks constructed from diffusion tractography and tracer injections
title_short The role of spatial embedding in mouse brain networks constructed from diffusion tractography and tracer injections
title_sort role of spatial embedding in mouse brain networks constructed from diffusion tractography and tracer injections
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8611903/
https://www.ncbi.nlm.nih.gov/pubmed/34520833
http://dx.doi.org/10.1016/j.neuroimage.2021.118576
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