Evolutionarily conserved fMRI network dynamics in the mouse, macaque, and human brain

Gutierrez-Barragan, Daniel; Ramirez, Julian S.B.; Panzeri, Stefano; Xu, Ting; Gozzi, Alessandro

doi:10.1101/2023.07.19.549681

Cited by 2 publications

(1 citation statement)

References 88 publications

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“…Translational work across species can be aided by using common tools (e.g., imaging modalities) and analytical frameworks 38,39 (here, connectome-based ID). Work of this nature contributes by establishing whether (and the degree to which) specific measurements are possible in multiple species 40 and by extension how useful animal models might be within a specific analytical framework or clinical context.…”

Section: Discussionmentioning

confidence: 99%

Multimodal identification of the mouse brain using simultaneous Ca²⁺imaging and fMRI

Mandino,

Horien,

Shen

et al. 2024

Preprint

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Individual differences in neuroimaging are of interest to clinical and cognitive neuroscientists based on their potential for guiding the personalized treatment of various heterogeneous neurological conditions and diseases. Despite many advantages, the workhorse in this arena, BOLD (blood-oxygen-level-dependent) functional magnetic resonance imaging (fMRI) suffers from low spatiotemporal resolution and specificity as well as a propensity for noise and spurious signal corruption. To better understand individual differences in BOLD-fMRI data, we can use animal models where fMRI, alongside complementary but more invasive contrasts, can be accessed. Here, we apply simultaneous wide-field fluorescence calcium imaging and BOLD-fMRI in mice to interrogate individual differences using a connectome-based identification framework adopted from the human fMRI literature. This approach yields high spatiotemporal resolution cell-type specific signals (here, from glia, excitatory, as well as inhibitory interneurons) from the whole cortex. We found mouse multimodal connectome-based identification to be successful and explored various features of these data.

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Section: Discussionmentioning

confidence: 99%

Multimodal identification of the mouse brain using simultaneous Ca²⁺imaging and fMRI

Mandino,

Horien,

Shen

et al. 2024

Preprint

View full text Add to dashboard Cite

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Mapping and comparing fMRI connectivity networks across species

Pagani,

Gutierrez‐Barragan,

de Guzman

et al. 2023

Commun Biol

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Technical advances in neuroimaging, notably in fMRI, have allowed distributed patterns of functional connectivity to be mapped in the human brain with increasing spatiotemporal resolution. Recent years have seen a growing interest in extending this approach to rodents and non-human primates to understand the mechanism of fMRI connectivity and complement human investigations of the functional connectome. Here, we discuss current challenges and opportunities of fMRI connectivity mapping across species. We underscore the critical importance of physiologically decoding neuroimaging measures of brain (dys)connectivity via multiscale mechanistic investigations in animals. We next highlight a set of general principles governing the organization of mammalian connectivity networks across species. These include the presence of evolutionarily conserved network systems, a dominant cortical axis of functional connectivity, and a common repertoire of topographically conserved fMRI spatiotemporal modes. We finally describe emerging approaches allowing comparisons and extrapolations of fMRI connectivity findings across species. As neuroscientists gain access to increasingly sophisticated perturbational, computational and recording tools, cross-species fMRI offers novel opportunities to investigate the large-scale organization of the mammalian brain in health and disease.

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Evolutionarily conserved fMRI network dynamics in the mouse, macaque, and human brain

Cited by 2 publications

References 88 publications

Multimodal identification of the mouse brain using simultaneous Ca²⁺imaging and fMRI

Multimodal identification of the mouse brain using simultaneous Ca²⁺imaging and fMRI

Mapping and comparing fMRI connectivity networks across species

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Evolutionarily conserved fMRI network dynamics in the mouse, macaque, and human brain

Cited by 2 publications

References 88 publications

Multimodal identification of the mouse brain using simultaneous Ca2+imaging and fMRI

Multimodal identification of the mouse brain using simultaneous Ca2+imaging and fMRI

Mapping and comparing fMRI connectivity networks across species

Contact Info

Product

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Multimodal identification of the mouse brain using simultaneous Ca²⁺imaging and fMRI

Multimodal identification of the mouse brain using simultaneous Ca²⁺imaging and fMRI