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Literature DB >> 25878266

Microsecond-scale timing precision in rodent trigeminal primary afferents.

Michael R Bale¹, Dario Campagner², Andrew Erskine², Rasmus S Petersen³.

Abstract

Communication in the nervous system occurs by spikes: the timing precision with which spikes are fired is a fundamental limit on neural information processing. In sensory systems, spike-timing precision is constrained by first-order neurons. We found that spike-timing precision of trigeminal primary afferents in rats and mice is limited both by stimulus speed and by electrophysiological sampling rate. High-speed video of behaving mice revealed whisker velocities of at least 17,000°/s, so we delivered an ultrafast "ping" (>50,000°/s) to single whiskers and sampled primary afferent activity at 500 kHz. Median spike jitter was 17.4 μs; 29% of neurons had spike jitter < 10 μs. These results indicate that the input stage of the trigeminal pathway has extraordinary spike-timing precision and very high potential information capacity. This timing precision ranks among the highest in biology.

Entities: Species

Keywords: neural coding; trigeminal ganglion; vibrissa; whisker

Mesh：

Year: 2015 PMID： 25878266 PMCID： PMC4397594 DOI： 10.1523/JNEUROSCI.3876-14.2015

Source DB: PubMed Journal: J Neurosci ISSN： 0270-6474 Impact factor: 6.167

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