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Literature DB >> 25744881

Microcircuitry of agranular frontal cortex: contrasting laminar connectivity between occipital and frontal areas.

Taihei Ninomiya¹, Kacie Dougherty¹, David C Godlove¹, Jeffrey D Schall¹, Alexander Maier².

Abstract

Neocortex is striking in its laminar architecture. Tracer studies have uncovered anatomical connectivity among laminae, but the functional connectivity between laminar compartments is still largely unknown. Such functional connectivity can be discerned through spontaneous neural correlations during rest. Previous work demonstrated a robust pattern of mesoscopic resting-state connectivity in macaque primary visual cortex (V1) through interlaminar cross-frequency coupling. Here we investigated whether this pattern generalizes to other cortical areas by comparing resting-state laminar connectivity between V1 and the supplementary eye field (SEF), a frontal area lacking a granular layer 4 (L4). Local field potentials (LFPs) were recorded with linear microelectrode arrays from all laminae of granular V1 and agranular SEF while monkeys rested in darkness. We found substantial differences in the relationship between the amplitude of gamma-band (>30 Hz) LFP and the phase of alpha-band (7-14 Hz) LFP between these areas. In V1, gamma amplitudes in L2/3 and L5 were coupled with alpha-band LFP phase in L5, as previously described. In contrast, in SEF phase-amplitude coupling was prominent within L3 and much weaker across layers. These results suggest that laminar interactions in agranular SEF are unlike those in granular V1. Thus the intrinsic functional connectivity of the cortical microcircuit does not seem to generalize across cortical areas.

Entities: Disease

Keywords: canonical microcircuit; cortical column; cross-frequency coupling; ongoing activity; phase-amplitude coupling; spontaneous activity

Mesh：

Year: 2015 PMID： 25744881 PMCID： PMC4440241 DOI： 10.1152/jn.00624.2014

Source DB: PubMed Journal: J Neurophysiol ISSN： 0022-3077 Impact factor: 2.714

56 in total

Review 1. Neuronal circuits of the neocortex.

Authors: Rodney J Douglas; Kevan A C Martin
Journal: Annu Rev Neurosci Date: 2004 Impact factor: 12.449

2. High gamma power is phase-locked to theta oscillations in human neocortex.

Authors: R T Canolty; E Edwards; S S Dalal; M Soltani; S S Nagarajan; H E Kirsch; M S Berger; N M Barbaro; R T Knight
Journal: Science Date: 2006-09-15 Impact factor: 47.728

3. A spatiotemporal profile of visual system activation revealed by current source density analysis in the awake macaque.

Authors: C E Schroeder; A D Mehta; S J Givre
Journal: Cereb Cortex Date: 1998 Oct-Nov Impact factor: 5.357

4. The pulvinar regulates information transmission between cortical areas based on attention demands.

Authors: Yuri B Saalmann; Mark A Pinsk; Liang Wang; Xin Li; Sabine Kastner
Journal: Science Date: 2012-08-10 Impact factor: 47.728

Review 5. The functional role of cross-frequency coupling.

Authors: Ryan T Canolty; Robert T Knight
Journal: Trends Cogn Sci Date: 2010-11 Impact factor: 20.229

6. Distinct superficial and deep laminar domains of activity in the visual cortex during rest and stimulation.

Authors: Alexander Maier; Geoffrey K Adams; Christopher Aura; David A Leopold
Journal: Front Syst Neurosci Date: 2010-08-10

7. Layer-specific entrainment of γ-band neural activity by the α rhythm in monkey visual cortex.

Authors: Eelke Spaak; Mathilde Bonnefond; Alexander Maier; David A Leopold; Ole Jensen
Journal: Curr Biol Date: 2012-11-15 Impact factor: 10.834

8. Laminar specificity of functional input to distinct types of inhibitory cortical neurons.

Authors: Xiangmin Xu; Edward M Callaway
Journal: J Neurosci Date: 2009-01-07 Impact factor: 6.167

9. Cross-frequency coupling between neuronal oscillations.

Authors: Ole Jensen; Laura L Colgin
Journal: Trends Cogn Sci Date: 2007-06-04 Impact factor: 20.229

10. FieldTrip: Open source software for advanced analysis of MEG, EEG, and invasive electrophysiological data.

Authors: Robert Oostenveld; Pascal Fries; Eric Maris; Jan-Mathijs Schoffelen
Journal: Comput Intell Neurosci Date: 2010-12-23

19 in total

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Authors: Kacie Dougherty; Michele A Cox; Taihei Ninomiya; David A Leopold; Alexander Maier
Journal: Cereb Cortex Date: 2017-02-01 Impact factor: 5.357

2. Corticocortical Systems Underlying High-Order Motor Control.

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Journal: J Neurosci Date: 2019-03-18 Impact factor: 6.167

3. V1 microcircuit dynamics: altered signal propagation suggests intracortical origins for adaptation in response to visual repetition.

Authors: Jacob A Westerberg; Michele A Cox; Kacie Dougherty; Alexander Maier
Journal: J Neurophysiol Date: 2019-03-27 Impact factor: 2.714

Review 9. A Role of Phase-Resetting in Coordinating Large Scale Neural Networks During Attention and Goal-Directed Behavior.

Authors: Benjamin Voloh; Thilo Womelsdorf
Journal: Front Syst Neurosci Date: 2016-03-08

10. EEG Phase-Amplitude Coupling Strength and Phase Preference: Association with Age over the First Three Years after Birth.

Authors: Michael G Mariscal; April R Levin; Laurel J Gabard-Durnam; Wanze Xie; Helen Tager-Flusberg; Charles A Nelson
Journal: eNeuro Date: 2021-06-24