2024-03-29T00:11:14Zhttp://digital.csic.es/dspace-oai/requestoai:digital.csic.es:10261/560612021-12-28T16:20:24Zcom_10261_133com_10261_1col_10261_386
Multiple timescale encoding of slowly varying whisker stimulus envelope in cortical and thalamic neurons in vivo
Lundstrom, Brian Nils
Fairhall, Adrienne L.
Maravall, Miguel
7 p., 5 figures and references
Adaptive processes over many timescales endow neurons with sensitivity to stimulus changes over a similarly wide range of scales. Although spike timing of single neurons can precisely signal rapid fluctuations in their inputs, the mean firing rate can convey information about slower-varying properties of the stimulus. Here, we investigate the firing rate response to a slowly varying envelope of whisker motion in two processing stages of the rat vibrissa pathway. The whiskers of anesthetized rats were moved through a noise trajectory with an amplitude that was sinusoidally modulated at one of several frequencies. In thalamic neurons, we found that the rate response to the stimulus envelope was also sinusoidal, with an approximately frequency-independent phase advance with respect to the input. Responses in cortex were similar but with a phase shift that was about three times larger, consistent with a larger amount of rate adaptation. These response properties can be described as a linear transformation of the input for which a single parameter quantifies the phase shift as well as the degree of adaptation. These results are reproduced by a model of adapting neurons connected by synapses with short-term plasticity, showing that the observed linear response and phase lead can be built up from a network that includes a sequence of nonlinear adapting elements. Our study elucidates how slowly varying envelope information under passive stimulation is preserved and transformed through the vibrissa processing pathway.
This work was supported by the following: International Human Frontier Science Program Organization shortterm fellowship (B.N.L.); Spanish Ministry of Science and Innovation Grant BFU2008-03017/BFI (M.M.), cofunded by
the European Regional Development Fund; CONSOLIDER Grant CSD2007-00023; European Commission Coordination Action ENINET, Contract LSHM-CT-2005-19063; and a McKnight Scholar Award in the Neurosciences (A.L.F.)
Peer reviewed
2012-09-11T09:48:30Z
2012-09-11T09:48:30Z
2010-04
artÃculo
http://purl.org/coar/resource_type/c_6501
Journal of Neuroscience 30(14): 5071-5077 (2010)
http://hdl.handle.net/10261/56061
10.1523/JNEUROSCI.2193-09.2010
1529-2401
20371827
en
http://dx.doi.org/10.1523/JNEUROSCI.2193-09.2010
open
Society for Neuroscience