Temporal Dynamics of Direction Tuning in Motion-Sensitive Macaque Area MT

Functional Neurobiology, Helmholtz Institute, Faculty Biology, Utrecht University, Utrecht, The Netherlands Submitted 14 June 2004; accepted in final form 3 November 2004 We studied the temporal dynamics of motion direction sensitivity in macaque area MT using a motion reverse correlation paradigm....

Full description

Saved in:
Bibliographic Details
Published in:Journal of neurophysiology 2005-04, Vol.93 (4), p.2104-2116
Main Authors: Perge, Janos A, Borghuis, Bart G, Bours, Roger J. E, Lankheet, Martin J. M, van Wezel, Richard J. A
Format: Article
Language:English
Subjects:
Action Potentials - physiology
Animals
Macaca
Macaca mulatta
Male
Motion Perception - physiology
Photic Stimulation - methods
Temporal Lobe - physiology
Time Factors
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Functional Neurobiology, Helmholtz Institute, Faculty Biology, Utrecht University, Utrecht, The Netherlands Submitted 14 June 2004; accepted in final form 3 November 2004 We studied the temporal dynamics of motion direction sensitivity in macaque area MT using a motion reverse correlation paradigm. Stimuli consisted of a random sequence of motion steps in eight different directions. Cross-correlating the stimulus with the resulting neural activity reveals the temporal dynamics of direction selectivity. The temporal dynamics of direction selectivity at the preferred speed showed two phases along the time axis: one phase corresponding to an increase in probability for the preferred direction at short latencies and a second phase corresponding to a decrease in probability for the preferred direction at longer latencies. The strength of this biphasic behavior varied between neurons from weak to very strong and was uniformly distributed. Strong biphasic behavior suggests optimal responses for motion steps in the antipreferred direction followed by a motion step in the preferred direction. Correlating spikes to combinations of motion directions corroborates this distinction. The optimal combination for weakly biphasic cells consists of successive steps in the preferred direction, whereas for strongly biphasic cells, it is a reversal of directions. Comparing reverse correlograms to combinations of stimuli to predictions based on correlograms for individual directions revealed several nonlinear effects. Correlations for successive presentations of preferred directions were smaller than predicted, which could be explained by a static nonlinearity (saturation). Correlations to pairs of (nearly) opposite directions were larger than predicted. These results show that MT neurons are generally more responsive when sudden changes in motion directions occur, irrespective of the preferred direction of the neurons. The latter nonlinearities cannot be explained by a simple static nonlinearity at the output of the neuron, but most likely reflect network interactions. Address for reprint requests and other correspondence: R. van Wezel, Functional Neurobiology, Faculty Biology, Utrecht Univ., Padualaan 8, 3584 CH Utrecht, The Netherlands (E-mail: r.j.a.vanwezel{at}bio.uu.nl )
ISSN:0022-3077
1522-1598
DOI:10.1152/jn.00601.2004