File(s) not publicly available
Cortical reorganization consistent with spike timing-but not correlation-dependent plasticity
journal contribution
posted on 2023-05-18, 00:39 authored by Young, JM, Waleszczyk, WJ, Wang, C, Calford, MB, Dreher, B, Obermayer, KThe receptive fields of neurons in primary visual cortex that are inactivated by retinal damage are known to 'shift' to nondamaged retinal locations, seemingly due to the plasticity of intracortical connections. We have observed in cats that these shifts occur in a pattern that is highly convergent, even among receptive fields that are separated by large distances before inactivation. Here we show, using a computational model of primary visual cortex, that the observed convergent shifts are inconsistent with the common assumption that the underlying intracortical connection plasticity is dependent on the temporal correlation of pre- and postsynaptic action potentials. The shifts are, however, consistent with the hypothesis that this plasticity is dependent on the temporal order of pre- and postsynaptic action potentials. This convergent reorganization seems to require increased neuronal gain, revealing a mechanism that networks may use to selectively facilitate the didactic transfer of neuronal response properties. © 2007 Nature Publishing Group.
History
Publication title
Nature NeuroscienceVolume
10Issue
7Pagination
887-895ISSN
1097-6256Department/School
DVC - AcademicPublisher
Nature Publishing GroupPlace of publication
345 Park Ave South, New York, USA, Ny, 10010-1707Repository Status
- Restricted
Socio-economic Objectives
Clinical health not elsewhere classifiedUsage metrics
Categories
Keywords
Licence
Exports
RefWorksRefWorks
BibTeXBibTeX
Ref. managerRef. manager
EndnoteEndnote
DataCiteDataCite
NLMNLM
DCDC