Altered Resting-State Functional Connectivity Between Awake and Isoflurane Anesthetized Marmosets

Hori, Yuki; Schaeffer, David J.; Gilbert, Kyle M.; Hayrynen, Lauren K.; Cléry, Justine; Gati, Joseph S.; Menon, Ravi S.; Everling, Stefan

doi:10.1093/cercor/bhaa168

Cited by 44 publications

(60 citation statements)

References 76 publications

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“…These RSNs were thresholded at z = 2.3 for visual purposes. Obtained RSNs were consistent with previously observed networks in marmosets (Belcher et al, 2013; Ghahremani et al, 2016; Hori et al, 2020b) such as default mode network (DMN) (Fig. 1A), attention network (ATN) (Fig.…”

Section: Resultssupporting

confidence: 89%

“…Fourteen components identified as resting-state networks in the marmosets. These networks were labeled based on previous studies (Belcher et al, 2013; Hori et al, 2020b) as follows: (A) default mode network (DMN); (B) attention network (ATN); (C) salience network (SAN); (D) left primary visual network (pVIS-Lt); (E) right primary VIS (pVIS-Rt); (F) orbitofrontal network (ORN); (G)-(J) high-order VIS (hVIS1-4); (K)-(M) somatomotor networks ventral (SMNv), dorsal (SMNd), and medial (SMNm); (N) premotor network (PMN). Color bar represents the z-score of these correlation patterns thresholding at 2.3.…”

Section: Resultsmentioning

confidence: 99%

“…Resting-state functional magnetic resonance imaging (RS-fMRI) allows for circumvention of some of these challenges by allowing for non-invasive identification of robust and reproducible resting-state networks across different species (Damoiseaux et al, 2006; Fox and Raichle, 2007; Smith et al, 2013; Sporns, 2013). With recent advances in MRI hardware, we are now able to measure the functional networks/connectivities in awake marmosets (Belcher et al, 2013; Cléry et al, 2020; Hori et al, 2020b; Schaeffer et al, 2019c). Particularly, the marmoset’s small size is ideal for ultra-high field small-bore fMRI, affording high spatial resolution and signal-to-noise ratio (SNR) even in subcortical areas.…”

Section: Introductionmentioning

confidence: 99%

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Cortico-subcortical functional connectivity profiles of resting-state networks in marmosets and humans

Hori

Schaeffer

Yoshida

et al. 2020

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Understanding the similarity of cortico-subcortical networks topologies between humans and nonhuman primate species is critical to study the origin of network alternations underlying human neurological and neuropsychiatric diseases. The New World common marmoset (Callithrix jacchus) has become popular as a non-human primate model for human brain function. Most marmoset connectomic research, however, has exclusively focused on cortical areas, with connectivity to subcortical networks less extensively explored. In this study, we aimed to first isolate patterns of subcortical connectivity with cortical resting-state networks (RSNs) in awake marmosets using resting-state functional magnetic resonance imaging (RS-fMRI), then to compare these networks to those in humans using connectivity fingerprinting. While we could match several marmoset and human RSNs based on their functional fingerprints, we also found a few striking differences, for example strong functional connectivity of the default mode network with the superior colliculus in marmosets that was much weaker in humans. Together, these findings demonstrate that many of the core cortico-subcortical networks in humans are also present in marmosets, but that small, potentially functionally relevant differences exist.

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Section: Resultssupporting

confidence: 89%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Cortico-subcortical functional connectivity profiles of resting-state networks in marmosets and humans

Hori

Schaeffer

Yoshida

et al. 2020

Preprint

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“…Functional interactions between distributed brain areas within specific neural networks give rise to coherent patterns of hemodynamic signals, measured as BOLD activity. Covariant relations of spontaneous BOLD signals in the resting state have been reported in humans ( Arcaro et al, 2015a ; Biswal et al, 1995 ; Fox et al, 2009 ; Power et al, 2011 ; Sporns and Honey, 2013 ) and awake NHPs ( Belcher et al, 2016 ; Ghahremani et al, 2017 ; Hori et al, 2020a ; Leopold et al, 2003 ; Liu et al, 2013 ; Logothetis, 2003b ; Silva, 2017 ; Wang et al, 2012 ) as well as in anesthetized NHPs ( Hori et al, 2020a , b ; Hutchison et al, 2012 ; Hutchison et al, 2013 ; Mantini et al, 2012a ; Vincent et al, 2007 ; Wu et al, 2016 ; Wu et al, 2017 ; Zhang et al, 2019 ). These studies have revealed that specialized cognitive and sensory networks retain their basic functional connectivity, even when not specifically engaged in task-relevant operations.…”

Section: Non-invasive Imaging Methods Are Used In Experimental and CLmentioning

confidence: 88%

Using non-invasive neuroimaging to enhance the care, well-being and experimental outcomes of laboratory non-human primates (monkeys)

et al. 2021

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Over the past 10–20 years, neuroscience witnessed an explosion in the use of non-invasive imaging methods, particularly magnetic resonance imaging (MRI), to study brain structure and function. Simultaneously, with access to MRI in many research institutions, MRI has become an indispensable tool for researchers and veterinarians to guide improvements in surgical procedures and implants and thus, experimental as well as clinical outcomes, given that access to MRI also allows for improved diagnosis and monitoring for brain disease. As part of the PRIMEatE Data Exchange, we gathered expert scientists, veterinarians, and clinicians who treat humans, to provide an overview of the use of non-invasive imaging tools, primarily MRI, to enhance experimental and welfare outcomes for laboratory non-human primates engaged in neuroscientific experiments. We aimed to provide guidance for other researchers, scientists and veterinarians in the use of this powerful imaging technology as well as to foster a larger conversation and community of scientists and veterinarians with a shared goal of improving the well-being and experimental outcomes for laboratory animals.

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“…Functional magnetic resonance imaging (fMRI) plays an important role in identifying the functional architecture of marmoset cortex (Belcher et al, 2013;Hori et al, 2020a;Schaeffer et al, 2019c) and in establishing brain homologies between primate species (Ghahremani et al, 2016;Hori et al, 2020b;Schaeffer et al, 2019c). In particular resting-state fMRI has been used (i) to identify homologous large-scale brain networks between marmosets and humans (Ghahremani et al, 2016;Hori et al, 2020a;Schaeffer et al, 2019c), (ii) to define functional boundaries based on intrinsic functional connectivity (Schaeffer et al, 2019b(Schaeffer et al, , 2019a, and (iii) to use functional connectivity "fingerprints" of brain areas to establish homologies between marmosets, rodents, and humans (Schaeffer et al, 2020a). Because resting state patterns are state-agnostic and spontaneous, however, this technique cannot be used to map the functional correspondences of interspecies BOLD fluctuations over time.…”

Section: Introductionmentioning

confidence: 99%

Interspecies activation correlations reveal functional correspondences between marmoset and human brain areas

Hori

Cléry

Schaeffer

et al. 2021

Preprint

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The common marmoset has enormous promise as a nonhuman primate model of human brain functions. While resting-state functional magnetic resonance imaging (fMRI) has provided evidence for a similar organization of marmoset and human cortices, the technique cannot be used to map the functional correspondences of brain regions between species. This limitation can be overcome by movie-driven fMRI (md-fMRI), which has become a popular tool for non-invasively mapping the neural patterns generated by rich and naturalistic stimulation. Here, we used md-fMRI in marmosets and humans to identify whole-brain functional correspondences between the two primate species. In particular, we describe functional correlates for the well-known human face, body, and scene patches in marmosets. We find that these networks have a similar organization in both species, suggesting a largely conserved organization of higher-order visual areas between New World marmoset monkeys and humans. However, while face patches in humans and marmosets were activated by marmoset faces, only human face patches responded to the faces of other animals. Together, the results demonstrate that md-fMRI is a powerful tool for interspecies functional mapping and characterization of higher-order visual functions.

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Altered Resting-State Functional Connectivity Between Awake and Isoflurane Anesthetized Marmosets

Cited by 44 publications

References 76 publications

Cortico-subcortical functional connectivity profiles of resting-state networks in marmosets and humans

Cortico-subcortical functional connectivity profiles of resting-state networks in marmosets and humans

Using non-invasive neuroimaging to enhance the care, well-being and experimental outcomes of laboratory non-human primates (monkeys)

Interspecies activation correlations reveal functional correspondences between marmoset and human brain areas

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