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Medial prefrontal theta phase coupling during spatial memory retrieval. 2014

Raphael Kaplan, and Daniel Bush, and Mathilde Bonnefond, and Peter A Bandettini, and Gareth R Barnes, and Christian F Doeller, and Neil Burgess
NIMH-UCL Joint Neuroscience Graduate Partnership Program, National Institute of Mental Health, Bethesda, Maryland; Section on Functional Imaging Methods, Laboratory of Brain and Cognition, National Institute of Mental Health, Bethesda, Maryland; University College London, Institute of Cognitive Neuroscience, Alexandra House, London, WC1N 3AR, United Kingdom; University College London, Institute of Neurology, London, WC1N 1PJ, United Kingdom.

Memory retrieval is believed to involve a disparate network of areas, including medial prefrontal and medial temporal cortices, but the mechanisms underlying their coordination remain elusive. One suggestion is that oscillatory coherence mediates inter-regional communication, implicating theta phase and theta-gamma phase-amplitude coupling in mnemonic function across species. To examine this hypothesis, we used non-invasive whole-head magnetoencephalography (MEG) as participants retrieved the location of objects encountered within a virtual environment. We demonstrate that, when participants are cued with the image of an object whose location they must subsequently navigate to, there is a significant increase in 4-8 Hz theta power in medial prefrontal cortex (mPFC), and the phase of this oscillation is coupled both with ongoing theta phase in the medial temporal lobe (MTL) and perceptually induced 65-85 Hz gamma amplitude in medial parietal cortex. These results suggest that theta phase coupling between mPFC and MTL and theta-gamma phase-amplitude coupling between mPFC and neocortical regions may play a role in human spatial memory retrieval.

UI MeSH Term Description Entries
D008297 Male Males
D009483 Neuropsychological Tests Tests designed to assess neurological function associated with certain behaviors. They are used in diagnosing brain dysfunction or damage and central nervous system disorders or injury. Aphasia Tests,Cognitive Test,Cognitive Testing,Cognitive Tests,Memory for Designs Test,Neuropsychological Testing,AX-CPT,Behavioral Assessment of Dysexecutive Syndrome,CANTAB,Cambridge Neuropsychological Test Automated Battery,Clock Test,Cognitive Function Scanner,Continuous Performance Task,Controlled Oral Word Association Test,Delis-Kaplan Executive Function System,Developmental Neuropsychological Assessment,Hooper Visual Organization Test,NEPSY,Neuropsychologic Tests,Neuropsychological Test,Paced Auditory Serial Addition Test,Repeatable Battery for the Assessment of Neuropsychological Status,Rey-Osterrieth Complex Figure,Symbol Digit Modalities Test,Test of Everyday Attention,Test, Neuropsychological,Tests, Neuropsychological,Tower of London Test,Neuropsychologic Test,Test, Cognitive,Testing, Cognitive,Testing, Neuropsychological,Tests, Cognitive
D010296 Parietal Lobe Upper central part of the cerebral hemisphere. It is located posterior to central sulcus, anterior to the OCCIPITAL LOBE, and superior to the TEMPORAL LOBES. Brodmann Area 39,Brodmann Area 40,Brodmann Area 5,Brodmann Area 7,Brodmann's Area 39,Brodmann's Area 40,Brodmann's Area 5,Brodmann's Area 7,Inferior Parietal Cortex,Secondary Sensorimotor Cortex,Superior Parietal Lobule,Angular Gyrus,Gyrus Angularis,Gyrus Supramarginalis,Intraparietal Sulcus,Marginal Sulcus,Parietal Cortex,Parietal Lobule,Parietal Region,Posterior Paracentral Lobule,Posterior Parietal Cortex,Praecuneus,Precuneus,Precuneus Cortex,Prelunate Gyrus,Supramarginal Gyrus,Area 39, Brodmann,Area 39, Brodmann's,Area 40, Brodmann,Area 40, Brodmann's,Area 5, Brodmann,Area 5, Brodmann's,Area 7, Brodmann,Area 7, Brodmann's,Brodmanns Area 39,Brodmanns Area 40,Brodmanns Area 5,Brodmanns Area 7,Cortex, Inferior Parietal,Cortex, Parietal,Cortex, Posterior Parietal,Cortex, Precuneus,Cortex, Secondary Sensorimotor,Cortices, Inferior Parietal,Gyrus, Angular,Gyrus, Prelunate,Gyrus, Supramarginal,Inferior Parietal Cortices,Lobe, Parietal,Lobule, Parietal,Lobule, Posterior Paracentral,Lobule, Superior Parietal,Paracentral Lobule, Posterior,Paracentral Lobules, Posterior,Parietal Cortex, Inferior,Parietal Cortex, Posterior,Parietal Cortices,Parietal Cortices, Inferior,Parietal Cortices, Posterior,Parietal Lobes,Parietal Lobule, Superior,Parietal Lobules,Parietal Lobules, Superior,Parietal Regions,Posterior Paracentral Lobules,Posterior Parietal Cortices,Precuneus Cortices,Region, Parietal,Secondary Sensorimotor Cortices,Sensorimotor Cortex, Secondary,Superior Parietal Lobules
D003463 Cues Signals for an action; that specific portion of a perceptual field or pattern of stimuli to which a subject has learned to respond. Cue
D006801 Humans Members of the species Homo sapiens. Homo sapiens,Man (Taxonomy),Human,Man, Modern,Modern Man
D012815 Signal Processing, Computer-Assisted Computer-assisted processing of electric, ultrasonic, or electronic signals to interpret function and activity. Digital Signal Processing,Signal Interpretation, Computer-Assisted,Signal Processing, Digital,Computer-Assisted Signal Interpretation,Computer-Assisted Signal Interpretations,Computer-Assisted Signal Processing,Interpretation, Computer-Assisted Signal,Interpretations, Computer-Assisted Signal,Signal Interpretation, Computer Assisted,Signal Interpretations, Computer-Assisted,Signal Processing, Computer Assisted
D013826 Theta Rhythm Brain waves characterized by a frequency of 4-7 Hz, usually observed in the temporal lobes when the individual is awake, but relaxed and sleepy. Rhythm, Theta,Rhythms, Theta,Theta Rhythms
D014584 User-Computer Interface The portion of an interactive computer program that issues messages to and receives commands from a user. Interface, User Computer,Virtual Systems,User Computer Interface,Interface, User-Computer,Interfaces, User Computer,Interfaces, User-Computer,System, Virtual,Systems, Virtual,User Computer Interfaces,User-Computer Interfaces,Virtual System
D015225 Magnetoencephalography The measurement of magnetic fields over the head generated by electric currents in the brain. As in any electrical conductor, electric fields in the brain are accompanied by orthogonal magnetic fields. The measurement of these fields provides information about the localization of brain activity which is complementary to that provided by ELECTROENCEPHALOGRAPHY. Magnetoencephalography may be used alone or together with electroencephalography, for measurement of spontaneous or evoked activity, and for research or clinical purposes. Magnetoencephalogram,Magnetoencephalograms
D017397 Prefrontal Cortex The rostral part of the frontal lobe, bounded by the inferior precentral fissure in humans, which receives projection fibers from the MEDIODORSAL NUCLEUS OF THE THALAMUS. The prefrontal cortex receives afferent fibers from numerous structures of the DIENCEPHALON; MESENCEPHALON; and LIMBIC SYSTEM as well as cortical afferents of visual, auditory, and somatic origin. Anterior Prefrontal Cortex,Brodmann Area 10,Brodmann Area 11,Brodmann Area 12,Brodmann Area 47,Brodmann's Area 10,Brodmann's Area 11,Brodmann's Area 12,Brodmann's Area 47,Pars Orbitalis,Frontal Sulcus,Gyrus Frontalis Inferior,Gyrus Frontalis Superior,Gyrus Orbitalis,Gyrus Rectus,Inferior Frontal Gyrus,Lateral Orbitofrontal Cortex,Marginal Gyrus,Medial Frontal Gyrus,Olfactory Sulci,Orbital Area,Orbital Cortex,Orbital Gyri,Orbitofrontal Cortex,Orbitofrontal Gyri,Orbitofrontal Gyrus,Orbitofrontal Region,Rectal Gyrus,Rectus Gyrus,Straight Gyrus,Subcallosal Area,Superior Frontal Convolution,Superior Frontal Gyrus,Ventral Medial Prefrontal Cortex,Ventromedial Prefrontal Cortex,Anterior Prefrontal Cortices,Area 10, Brodmann,Area 10, Brodmann's,Area 11, Brodmann,Area 11, Brodmann's,Area 12, Brodmann,Area 12, Brodmann's,Area 47, Brodmann,Area 47, Brodmann's,Area, Orbital,Area, Subcallosal,Brodmanns Area 10,Brodmanns Area 11,Brodmanns Area 12,Brodmanns Area 47,Convolution, Superior Frontal,Convolutions, Superior Frontal,Cortex, Anterior Prefrontal,Cortex, Lateral Orbitofrontal,Cortex, Orbital,Cortex, Orbitofrontal,Cortex, Prefrontal,Cortex, Ventromedial Prefrontal,Cortices, Ventromedial Prefrontal,Frontal Convolution, Superior,Frontal Gyrus, Inferior,Frontal Gyrus, Medial,Frontal Gyrus, Superior,Frontalis Superior, Gyrus,Gyrus, Inferior Frontal,Gyrus, Marginal,Gyrus, Medial Frontal,Gyrus, Orbital,Gyrus, Orbitofrontal,Gyrus, Rectal,Gyrus, Rectus,Gyrus, Straight,Gyrus, Superior Frontal,Inferior, Gyrus Frontalis,Lateral Orbitofrontal Cortices,Olfactory Sulcus,Orbital Areas,Orbital Cortices,Orbital Gyrus,Orbitalis, Pars,Orbitofrontal Cortex, Lateral,Orbitofrontal Cortices,Orbitofrontal Cortices, Lateral,Orbitofrontal Regions,Prefrontal Cortex, Anterior,Prefrontal Cortex, Ventromedial,Prefrontal Cortices, Anterior,Region, Orbitofrontal,Subcallosal Areas,Sulcus, Frontal,Superior Frontal Convolutions,Superior, Gyrus Frontalis,Ventromedial Prefrontal Cortices

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