Default mode of brain function in monkeys

Human neuroimaging has revealed a specific network of brain regions-the default-mode network (DMN)-that reduces its activity during goal-directed behavior. So far, evidence for a similar network in monkeys is mainly indirect, since, except for one positron emission tomography study, it is all based...

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Bibliographic Details
Published in:The Journal of neuroscience 2011-09, Vol.31 (36), p.12954-12962
Main Authors: Mantini, Dante, Gerits, Annelis, Nelissen, Koen, Durand, Jean-Baptiste, Joly, Olivier, Simone, Luciano, Sawamura, Hiromasa, Wardak, Claire, Orban, Guy A, Buckner, Randy L, Vanduffel, Wim
Format: Article
Language:English
Subjects:
Algorithms
Animals
Brain - anatomy & histology
Brain - physiology
Cluster Analysis
Data Interpretation, Statistical
Female
Fixation, Ocular - physiology
Haplorhini - physiology
Life Sciences
Magnetic Resonance Imaging
Male
Nerve Net - anatomy & histology
Nerve Net - physiology
Neurons and Cognition
Rest - physiology
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Summary:Human neuroimaging has revealed a specific network of brain regions-the default-mode network (DMN)-that reduces its activity during goal-directed behavior. So far, evidence for a similar network in monkeys is mainly indirect, since, except for one positron emission tomography study, it is all based on functional connectivity analysis rather than activity increases during passive task states. Here, we tested whether a consistent DMN exists in monkeys using its defining property. We performed a meta-analysis of functional magnetic resonance imaging data collected in 10 awake monkeys to reveal areas in which activity consistently decreases when task demands shift from passive tasks to externally oriented processing. We observed task-related spatially specific deactivations across 15 experiments, implying in the monkey a functional equivalent of the human DMN. We revealed by resting-state connectivity that prefrontal and medial parietal regions, including areas 9/46d and 31, respectively, constitute the DMN core, being functionally connected to all other DMN areas. We also detected two distinct subsystems composed of DMN areas with stronger functional connections between each other. These clusters included areas 24/32, 8b, and TPOC and areas 23, v23, and PGm, respectively. Such a pattern of functional connectivity largely fits, but is not completely consistent with anatomical tract tracing data in monkeys. Also, analysis of afferent and efferent connections between DMN areas suggests a multisynaptic network structure. Like humans, monkeys increase activity during passive epochs in heteromodal and limbic association regions, suggesting that they also default to internal modes of processing when not actively interacting with the environment.
ISSN:0270-6474
1529-2401
DOI:10.1523/jneurosci.2318-11.2011