TY - JOUR
T1 - Decoding of MSTd population activity accounts for variations in the precision of heading perception
AU - Gu, Yong
AU - Fetsch, Christopher R.
AU - Adeyemo, Babatunde
AU - DeAngelis, Gregory C.
AU - Angelaki, Dora E.
N1 - Funding Information:
We thank Amanda Turner for excellent monkey care and training, Baili Chen for help with collecting human psychophysical data, Zachary Briggs for his contributions to an early version of the Fisher Information analysis, and Michael Morgan and Katsu Takahashi for collecting part of the neurophysiological data. The work was supported by NIH grants EY017866, EY019087 and DC007620 (to DEA) and by NIH grant EY016178 (to GCD).
PY - 2010/5
Y1 - 2010/5
N2 - Humans and monkeys use both vestibular and visual motion (optic flow) cues to discriminate their direction of self-motion during navigation. A striking property of heading perception from optic flow is that discrimination is most precise when subjects judge small variations in heading around straight ahead, whereas thresholds rise precipitously when subjects judge heading around an eccentric reference. We show that vestibular heading discrimination thresholds in both humans and macaques also show a consistent, but modest, dependence on reference direction. We used computational methods (Fisher information, maximum likelihood estimation, and population vector decoding) to show that population activity in area MSTd predicts the dependence of heading thresholds on reference eccentricity. This dependence arises because the tuning functions for most neurons have a steep slope for directions near straight forward. Our findings support the notion that population activity in extrastriate cortex limits the precision of both visual and vestibular heading perception.
AB - Humans and monkeys use both vestibular and visual motion (optic flow) cues to discriminate their direction of self-motion during navigation. A striking property of heading perception from optic flow is that discrimination is most precise when subjects judge small variations in heading around straight ahead, whereas thresholds rise precipitously when subjects judge heading around an eccentric reference. We show that vestibular heading discrimination thresholds in both humans and macaques also show a consistent, but modest, dependence on reference direction. We used computational methods (Fisher information, maximum likelihood estimation, and population vector decoding) to show that population activity in area MSTd predicts the dependence of heading thresholds on reference eccentricity. This dependence arises because the tuning functions for most neurons have a steep slope for directions near straight forward. Our findings support the notion that population activity in extrastriate cortex limits the precision of both visual and vestibular heading perception.
KW - Sysneuro
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U2 - 10.1016/j.neuron.2010.04.026
DO - 10.1016/j.neuron.2010.04.026
M3 - Article
C2 - 20510863
AN - SCOPUS:77953245182
SN - 0896-6273
VL - 66
SP - 596
EP - 609
JO - Neuron
JF - Neuron
IS - 4
ER -