Nemenman et al., 2008

From Ilya Nemenman: Theoretical Biophysics @ Emory
Revision as of 12:28, 4 July 2018 by Ilya (talk | contribs) (1 revision imported)
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to: navigation, search

Back to the full Publications list.

I Nemenman, GD Lewen, W Bialek, RR. de Ruyter van Steveninck. Neural coding of a natural stimulus ensemble: Uncovering information at sub-millisecond resolution. PLoS Comput Biol 4(3): e1000025, 2008. PDF, arXiv.

Our knowledge of the sensory world is encoded by neurons in sequences of discrete, identical pulses termed action potentials or spikes. There is persistent controversy about the extent to which the precise timing of these spikes is relevant to the function of the brain. We revisit this issue, using the motion-sensitive neurons of the fly visual system as a test case. New experimental methods allow us to deliver more nearly natural visual stimuli, comparable to those which flies encounter in free, acrobatic flight, and new mathematical methods allow us to draw more reliable conclusions about the information content of neural responses even when the set of possible responses is very large. We find that significant amounts of visual information are represented by details of the spike train at millisecond and sub-millisecond precision, even though the sensory input has a correlation time of ~60ms; different patterns of spike timing represent distinct motion trajectories, and the absolute timing of spikes points to particular features of these trajectories with high precision. Under these naturalistic conditions, the system continues to transmit more information at higher photon flux, even though individual photoreceptors are counting more than one million photons per second, and removes redundancy in the stimulus to generate a more efficient neural code.

This paper has been presented at the CNS'07 meeting and is also available as:

I Nemenman, G Lewen, W Bialek, and R de Ruyter van Steveninck. Neural coding of natural stimuli: information at sub-millisecond resolution. BMC Neurosci. 8 (Suppl 2):S7, 2007. PDF.

This is what the others are saying about this paper: