Microcircuitry of Agranular Frontal Cortex: Testing the Generality of the Canonical Cortical Microcircuit. Godlove, D. C., Maier, A., Woodman, G. F., & Schall, J. D. Journal of Neuroscience, 34(15):5355–5369, 2014.
Microcircuitry of Agranular Frontal Cortex: Testing the Generality of the Canonical Cortical Microcircuit [link]Paper  doi  abstract   bibtex   
We investigated whether a frontal area that lacks granular layer IV, supplementary eye field, exhibits features of laminar circuitry similar to those observed in primary sensory areas. We report, for the first time, visually evoked local field potentials (LFPs) and spiking activity recorded simultaneously across all layers of agranular frontal cortex using linear electrode arrays. We calculated current source density from the LFPs and compared the laminar organization of evolving sinks to those reported in sensory areas. Simultaneous, transient synaptic current sinks appeared first in layers III and V followed by more prolonged current sinks in layers I/II and VI. We also found no variation of single- or multi-unit visual response latency across layers, and putative pyramidal neurons and interneurons displayed similar response latencies. Many units exhibited pronounced discharge suppression that was strongest in superficial relative to deep layers. Maximum discharge suppression also occurred later in superficial than in deep layers. These results are discussed in the context of the canonical cortical microcircuit model originally formulated to describe early sensory cortex. The data indicate that agranular cortex resembles sensory areas in certain respects, but the cortical microcircuit is modified in nontrivial ways.
@article{godlove2014microcircuitry,
abstract = {We investigated whether a frontal area that lacks granular layer IV, supplementary eye field, exhibits features of laminar circuitry similar to those observed in primary sensory areas. We report, for the first time, visually evoked local field potentials (LFPs) and spiking activity recorded simultaneously across all layers of agranular frontal cortex using linear electrode arrays. We calculated current source density from the LFPs and compared the laminar organization of evolving sinks to those reported in sensory areas. Simultaneous, transient synaptic current sinks appeared first in layers III and V followed by more prolonged current sinks in layers I/II and VI. We also found no variation of single- or multi-unit visual response latency across layers, and putative pyramidal neurons and interneurons displayed similar response latencies. Many units exhibited pronounced discharge suppression that was strongest in superficial relative to deep layers. Maximum discharge suppression also occurred later in superficial than in deep layers. These results are discussed in the context of the canonical cortical microcircuit model originally formulated to describe early sensory cortex. The data indicate that agranular cortex resembles sensory areas in certain respects, but the cortical microcircuit is modified in nontrivial ways.},
author = {Godlove, D. C. and Maier, A. and Woodman, G. F. and Schall, J. D.},
doi = {10.1523/JNEUROSCI.5127-13.2014},
isbn = {1529-2401 (Electronic)$\backslash$r0270-6474 (Linking)},
issn = {0270-6474},
journal = {Journal of Neuroscience},
keywords = {Subgroup2},
mendeley-tags = {Subgroup2},
number = {15},
pages = {5355--5369},
pmid = {24719113},
title = {{Microcircuitry of Agranular Frontal Cortex: Testing the Generality of the Canonical Cortical Microcircuit}},
url = {http://www.jneurosci.org/cgi/doi/10.1523/JNEUROSCI.5127-13.2014},
volume = {34},
year = {2014}
}
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