Neuronal Correlations in MT and MST Impair Population Decoding of Opposite Directions of Random Dot Motion

Neuronal Correlations in MT and MST Impair Population Decoding of Opposite Directions of Random Dot Motion

The study of neuronal responses to random-dot motion patterns has provided some of the most valuable insights into how the activity of neurons is related to perception. In the opposite directions of motion paradigm, the motion signal strength is decreased by manipulating the coherence of random dot...

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Bibliographic Details
Published in:eNeuro Vol. 5; no. 6; p. ENEURO.0336-18.2018
Main Authors: Chaplin, Tristan A, Hagan, Maureen A, Allitt, Benjamin J, Lui, Leo L
Format: Journal Article
Language:English
Published: United States Society for Neuroscience 01-11-2018
Subjects:
New Research
random dot
marmoset
motion
electrode arrays
population decoding
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Summary:The study of neuronal responses to random-dot motion patterns has provided some of the most valuable insights into how the activity of neurons is related to perception. In the opposite directions of motion paradigm, the motion signal strength is decreased by manipulating the coherence of random dot patterns to examine how well the activity of single neurons represents the direction of motion. To extend this paradigm to populations of neurons, studies have used modelling based on data from pairs of neurons, but several important questions require further investigation with larger neuronal datasets. We recorded neuronal populations in the middle temporal (MT) and medial superior temporal (MST) areas of anaesthetized marmosets with electrode arrays, while varying the coherence of random dot patterns in two opposite directions of motion (left and right). Using the spike rates of simultaneously recorded neurons, we decoded the direction of motion at each level of coherence with linear classifiers. We found that the presence of correlations had a detrimental effect to decoding performance, but that learning the correlation structure produced better decoding performance compared to decoders that ignored the correlation structure. We also found that reducing motion coherence increased neuronal correlations, but decoders did not need to be optimized for each coherence level. Finally, we showed that decoder weights depend of left-right selectivity at 100% coherence, rather than the preferred direction. These results have implications for understanding how the information encoded by populations of neurons is affected by correlations in spiking activity.
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This work was supported by Australian Research Council Grants DE130100493 (to L.L.L.) and CE140100007; DE180100344 (to M.A.H.) and by National Health and Medical Research Council of Australia Grants APP1066232 (to L.L.L.) and APP1159764 (to T.A.C.). T.A.C. was also funded by an Australian Postgraduate Award and a Monash University Faculty of Medicine Bridging Postdoctoral Fellowship.
The authors declare no competing financial interests.
Author contributions: T.A.C. and L.L.L. designed research; T.A.C., M.A.H., B.J.A., and L.L.L. performed research; T.A.C. analyzed data; T.A.C. and L.L.L. wrote the paper.
ISSN:2373-2822
2373-2822
DOI:10.1523/ENEURO.0336-18.2018