Texture Signals in Whisker Vibrations

1 University/ETH Zurich, Institute of Neuroinformatics, Zurich, Switzerland.; 2 International School for Advanced Studies, Cognitive Neuroscience Sector, Trieste, Italy; 3 Max Planck Institute for Biological Cybernetics, Physiology of Cognitive Processes, Tubingen, Germany; and 4 University of Osnab...

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Published in:Journal of neurophysiology 2006-03, Vol.95 (3), p.1792-1799
Main Authors: Hipp, Joerg, Arabzadeh, Ehsan, Zorzin, Erik, Conradt, Jorg, Kayser, Christoph, Diamond, Mathew E, Konig, Peter
Format: Article
Language:English
Subjects:
Action Potentials - physiology
Afferent Pathways - physiology
Animals
Biomimetics - instrumentation
Biomimetics - methods
Computer Simulation
Discrimination Learning - physiology
Male
Mechanoreceptors - physiology
Models, Neurological
Movement - physiology
Physical Stimulation - instrumentation
Physical Stimulation - methods
Rats
Rats, Wistar
Sensory Thresholds - physiology
Space Perception - physiology
Surface Properties
Touch - physiology
Vibration
Vibrissae - physiology
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Summary:1 University/ETH Zurich, Institute of Neuroinformatics, Zurich, Switzerland.; 2 International School for Advanced Studies, Cognitive Neuroscience Sector, Trieste, Italy; 3 Max Planck Institute for Biological Cybernetics, Physiology of Cognitive Processes, Tubingen, Germany; and 4 University of Osnabruck, Institute of Cognitive Science, Department of Neurobiopsychology, Osnabruck, Germany Submitted 19 October 2005; accepted in final form 29 November 2005 Rodents excel in making texture judgments by sweeping their whiskers across a surface. Here we aimed to identify the signals present in whisker vibrations that give rise to such fine sensory discriminations. First, we used sensors to capture vibration signals in metal whiskers during active whisking of an artificial system and in natural whiskers during whisking of rats in vivo. Then we developed a classification algorithm that successfully matched the vibration frequency spectra of single trials to the texture that induced it. For artificial whiskers, the algorithm correctly identified one texture of eight alternatives on 40% of trials; for in vivo natural whiskers, the algorithm correctly identified one texture of five alternatives on 80% of trials. Finally, we asked which were the key discriminative features of the vibration spectra. Under both artificial and natural conditions, the combination of two features accounted for most of the information: The modulation power —the power of the part of the whisker movement representing the modulation due to the texture surface—increased with the coarseness of the texture; the modulation centroid —a measure related to the center of gravity within the power spectrum—decreased with the coarseness of the texture. Indeed, restricting the signal to these two parameters led to performance three-fourths as high as the full spectra. Because earlier work showed that modulation power and centroid are directly related to neuronal responses in the whisker pathway, we conclude that the biological system optimally extracts vibration features to permit texture classification. Address for reprint requests and other correspondence: J. Hipp, Institute of Neuroinformatics, University/ETH Zurich, Winterthurerstrasse 190, 8057 Zurich, Switzerland (E-mail: joerg{at}ini.phys.ethz.ch )
ISSN:0022-3077
1522-1598
DOI:10.1152/jn.01104.2005