Daigo Takeuchi scite author profile

Neuronal oscillations have been hypothesized to play an important role in cognition and its ensuing behavior, but evidence that links a specific neuronal oscillation to a discrete cognitive event is largely lacking. We measured neuronal activity in the entorhinal-hippocampal circuit while mice performed a reward-based spatial working memory task. During the memory retention period, a transient burst of high gamma synchronization preceded an animal's correct choice in both prospective planning and retrospective mistake correction, but not an animal's incorrect choice. Optogenetic inhibition of the circuit targeted to the choice point area resulted in a coordinated reduction in both high gamma synchrony and correct execution of a working-memory-guided behavior. These findings suggest that transient high gamma synchrony contributes to the successful execution of spatial working memory. Furthermore, our data are consistent with an association between transient high gamma synchrony and explicit awareness of the working memory content.

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Reversal of Interlaminar Signal Between Sensory and Memory Processing in Monkey Temporal Cortex

Takeuchi

Hirabayashi

Tamura

et al. 2011

Science

128

172

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The primate temporal cortex implements visual long-term memory. However, how its interlaminar circuitry executes cognitive computations is poorly understood. Using linear-array multicontact electrodes, we simultaneously recorded unit activities across cortical layers in the perirhinal cortex of macaques performing a pair-association memory task. Cortical layers were estimated on the basis of current source density profiles with histological verifications, and the interlaminar signal flow was determined with cross-correlation analysis between spike trains. During the cue period, canonical "feed-forward" signals flowed from granular to supragranular layers and from supragranular to infragranular layers. During the delay period, however, the signal flow reversed to the "feed-back" direction: from infragranular to supragranular layers. This reversal of signal flow highlights how the temporal cortex differentially recruits its laminar circuits for sensory and mnemonic processing.

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Direct Comparison of Spontaneous Functional Connectivity and Effective Connectivity Measured by Intracortical Microstimulation: An fMRI Study in Macaque Monkeys

Matsui

Tamura

Koyano

et al. 2011

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Correlated spontaneous activity in the resting brain is increasingly recognized as a useful index for inferring underlying functional-anatomic architecture. However, despite efforts for comparison with anatomical connectivity, neuronal origin of intrinsic functional connectivity (inFC) remains unclear. Conceptually, the source of inFC could be decomposed into causal components that reflect the efficacy of synaptic interactions and other components mediated by collective network dynamics (e.g., synchronization). To dissociate these components, it is useful to introduce another connectivity measure such as effective connectivity, which is a quantitative measure of causal interactions. Here, we present a direct comparison of inFC against emEC (effective connectivity probed with electrical microstimulation [EM]) in the somatosensory system of macaque monkeys. Simultaneous EM and functional magnetic resonance imaging revealed strong emEC in several brain regions in a manner consistent with the anatomy of somatosensory system. Direct comparison of inFC and emEC revealed colocalization and overall positive correlation within the stimulated hemisphere. Interestingly, we found characteristic differences between inFC and emEC in their interhemispheric patterns. Our results suggest that intrahemispheric inFC reflects the efficacy of causal interactions, whereas interhemispheric inFC may arise from interactions akin to network-level synchronization that is not captured by emEC.

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Functional Microcircuit Recruited during Retrieval of Object Association Memory in Monkey Perirhinal Cortex

Hirabayashi

Takeuchi

Tamura

et al. 2013

Neuron

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The primate temporal cortex implements neural mechanisms for memory retrieval from visual long-term storage, and memory neurons have been identified at the single-neuron level whose activities following cue presentation encode the presented object ("cue-holding" neurons) or to-be-recalled target ("pair-recall" neurons). Although these two types of neurons can potentially interact during the target recall, little is known about information flow among these neurons. We conducted simultaneous recordings of multiple single units in macaque perirhinal cortex while they performed a pair-association memory task. Granger causality analysis revealed the emergence of directed couplings during the delay period predominantly from cue-holding neurons to pair-recall neurons. Moreover, these interactions coincided with unidirectional signal flow from the recipient recall neuron to another recall neuron, implying cascade-like signal propagation among the memory cell assembly. These results suggest that directed interactions among perirhinal memory neurons are dynamically modulated to implement functional microcircuitry for retrieval of object association memory.

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A glass-coated tungsten microelectrode enclosing optical fibers for optogenetic exploration in primate deep brain structures

Tamura

Ohashi

Tsubota

et al. 2012

Journal of Neuroscience Methods

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Daigo Takeuchi

Successful Execution of Working Memory Linked to Synchronized High-Frequency Gamma Oscillations

Reversal of Interlaminar Signal Between Sensory and Memory Processing in Monkey Temporal Cortex

Direct Comparison of Spontaneous Functional Connectivity and Effective Connectivity Measured by Intracortical Microstimulation: An fMRI Study in Macaque Monkeys

Functional Microcircuit Recruited during Retrieval of Object Association Memory in Monkey Perirhinal Cortex

A glass-coated tungsten microelectrode enclosing optical fibers for optogenetic exploration in primate deep brain structures

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