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Multimodal measures of spontaneous brain activity reveal both common and divergent patterns of cortical functional organization

Author

Listed:
  • Hadi Vafaii

    (University of Maryland)

  • Francesca Mandino

    (Yale School of Medicine)

  • Gabriel Desrosiers-Grégoire

    (Cerebral Imaging Center, Douglas Mental Health University Institute
    McGill University)

  • David O’Connor

    (Yale University)

  • Marija Markicevic

    (Yale School of Medicine)

  • Xilin Shen

    (Yale School of Medicine)

  • Xinxin Ge

    (School of Medicine, University of California San Francisco)

  • Peter Herman

    (Yale School of Medicine)

  • Fahmeed Hyder

    (Yale School of Medicine)

  • Xenophon Papademetris

    (Yale School of Medicine
    Yale University
    Yale School of Medicine)

  • Mallar Chakravarty

    (Cerebral Imaging Center, Douglas Mental Health University Institute
    McGill University
    McGill University
    McGill University)

  • Michael C. Crair

    (Yale School of Medicine
    Yale School of Medicine
    Yale School of Medicine)

  • R. Todd Constable

    (Yale School of Medicine
    Yale University
    Yale School of Medicine)

  • Evelyn M. R. Lake

    (Yale School of Medicine
    Yale University)

  • Luiz Pessoa

    (University of Maryland
    University of Maryland
    University of Maryland)

Abstract

Large-scale functional networks have been characterized in both rodent and human brains, typically by analyzing fMRI-BOLD signals. However, the relationship between fMRI-BOLD and underlying neural activity is complex and incompletely understood, which poses challenges to interpreting network organization obtained using this technique. Additionally, most work has assumed a disjoint functional network organization (i.e., brain regions belong to one and only one network). Here, we employ wide-field Ca2+ imaging simultaneously with fMRI-BOLD in mice expressing GCaMP6f in excitatory neurons. We determine cortical networks discovered by each modality using a mixed-membership algorithm to test the hypothesis that functional networks exhibit overlapping organization. We find that there is considerable network overlap (both modalities) in addition to disjoint organization. Our results show that multiple BOLD networks are detected via Ca2+ signals, and networks determined by low-frequency Ca2+ signals are only modestly more similar to BOLD networks. In addition, the principal gradient of functional connectivity is nearly identical for BOLD and Ca2+ signals. Despite similarities, important differences are also detected across modalities, such as in measures of functional connectivity strength and diversity. In conclusion, Ca2+ imaging uncovers overlapping functional cortical organization in the mouse that reflects several, but not all, properties observed with fMRI-BOLD signals.

Suggested Citation

  • Hadi Vafaii & Francesca Mandino & Gabriel Desrosiers-Grégoire & David O’Connor & Marija Markicevic & Xilin Shen & Xinxin Ge & Peter Herman & Fahmeed Hyder & Xenophon Papademetris & Mallar Chakravarty , 2024. "Multimodal measures of spontaneous brain activity reveal both common and divergent patterns of cortical functional organization," Nature Communications, Nature, vol. 15(1), pages 1-19, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-023-44363-z
    DOI: 10.1038/s41467-023-44363-z
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    References listed on IDEAS

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    1. Kevin Mann & Stephane Deny & Surya Ganguli & Thomas R. Clandinin, 2021. "Coupling of activity, metabolism and behaviour across the Drosophila brain," Nature, Nature, vol. 593(7858), pages 244-248, May.
    2. Gergely Palla & Imre Derényi & Illés Farkas & Tamás Vicsek, 2005. "Uncovering the overlapping community structure of complex networks in nature and society," Nature, Nature, vol. 435(7043), pages 814-818, June.
    3. Nikos K. Logothetis, 2008. "What we can do and what we cannot do with fMRI," Nature, Nature, vol. 453(7197), pages 869-878, June.
    4. Leto Peel & Tiago P. Peixoto & Manlio De Domenico, 2022. "Statistical inference links data and theory in network science," Nature Communications, Nature, vol. 13(1), pages 1-15, December.
    5. Charles R. Harris & K. Jarrod Millman & Stéfan J. Walt & Ralf Gommers & Pauli Virtanen & David Cournapeau & Eric Wieser & Julian Taylor & Sebastian Berg & Nathaniel J. Smith & Robert Kern & Matti Picu, 2020. "Array programming with NumPy," Nature, Nature, vol. 585(7825), pages 357-362, September.
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