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Neuronal processing of task-specific afferent whisker information in the rat barrel cortex

Fachliche Zuordnung Molekulare Biologie und Physiologie von Nerven- und Gliazellen
Förderung Förderung von 2010 bis 2016
Projektkennung Deutsche Forschungsgemeinschaft (DFG) - Projektnummer 141272880
 
Erstellungsjahr 2016

Zusammenfassung der Projektergebnisse

The work done in the BaCoFun project helped to revolutionize our view how tactile perception works. Our hypothesis at the outset of the project was based on the classic notion that active touch (active whisking in our case) samples whisker vibrations directly and continuously reflecting the microscopic 3D texture probed by converting a spatial measurement of height/depth (the 3D texture) into a temporal signal (the vibrotactile signal). The idea has been called ‘intensive coding’ and was put forward by the Mountcastle and Lederman groups (LaMotte and Mountcastle, 1975). In this view the tactile system either integrates this vibrotactile interval to arrive at an ‘intensity code’ or analyzes spectral content to arrive at a ‘frequency code’. Our key perceptional experiments, conducted during both funding periods, accumulated strong evidence against intensive coding which led us to formulate an entirely new perceptional hypothesis for the epicritic tactile sense on the microscopic spatial scale. This new hypothesis is called ‘slip hypothesis’ and has been suggested by biomechanical observations of other workers in the field. We were the first to add evidence from combined measurement of neuronal activity and psychophysics. We elaborated critical predictions of the slip hypothesis. The most important one is that tactile perception should be based on ‘near-instantaneous’ signal processing, working like a wellknown class of machine learning algorithms called ‘change detection’. The slip hypothesis entails that microscopic texture information is carried in short lived, large amplitude kinematic events, whisker jerks, carrying information in a probabilistic, spatio-temporally discrete code, rather than in a continuous, small amplitude vibration corrupted by noise. In the second funding period, we published five full length reports supporting slip coding and perception. We worked intensively on the motor side of the problem publishing three full length papers and summarized the new hypothesis in three review articles covering the perceptual processes and motor behavior. In a fourth review we integrated our results with those of the BaCoFun partners to showcase our view on how the respective neuronal coding is implemented in the barrel column. Conceptually, our work may have far reaching impact also on our understanding of tactile processing of ridge associated signals in primate glabrous skin. A new DFG funded project, inspired by this work, has started recently to study the concept of near-instantaneous coding also in humans.

Projektbezogene Publikationen (Auswahl)

 
 

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