Visual motion integration of bidirectional transparent motion in mouse opto-locomotor reflexes

L.A.M.H. Kirkels; W. Zhang; Z. Rezvani; R.J.A. van Wezel; M.M. van Wanrooij

doi:10.1038/s41598-021-89974-y

Visual motion integration of bidirectional transparent motion in mouse opto-locomotor reflexes

L.A.M.H. Kirkels^*, W. Zhang, Z. Rezvani, R.J.A. van Wezel, M.M. van Wanrooij

^*Corresponding author for this work

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Abstract

Visual motion perception depends on readout of direction selective sensors. We investigated in mice whether the response to bidirectional transparent motion, activating oppositely tuned sensors, reflects integration (averaging) or winner-take-all (mutual inhibition) mechanisms. We measured whole body opto-locomotor reflexes (OLRs) to bidirectional oppositely moving random dot patterns (leftward and rightward) and compared the response to predictions based on responses to unidirectional motion (leftward or rightward). In addition, responses were compared to stimulation with stationary patterns. When comparing OLRs to bidirectional and unidirectional conditions, we found that the OLR to bidirectional motion best fits an averaging model. These results reflect integration mechanisms in neural responses to contradicting sensory evidence as has been documented for other sensory and motor domains.

Original language	English
Article number	10490
Journal	Scientific reports
Volume	11
Issue number	1
DOIs	https://doi.org/10.1038/s41598-021-89974-y
Publication status	Published - Dec 2021

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title = "Visual motion integration of bidirectional transparent motion in mouse opto-locomotor reflexes",

abstract = "Visual motion perception depends on readout of direction selective sensors. We investigated in mice whether the response to bidirectional transparent motion, activating oppositely tuned sensors, reflects integration (averaging) or winner-take-all (mutual inhibition) mechanisms. We measured whole body opto-locomotor reflexes (OLRs) to bidirectional oppositely moving random dot patterns (leftward and rightward) and compared the response to predictions based on responses to unidirectional motion (leftward or rightward). In addition, responses were compared to stimulation with stationary patterns. When comparing OLRs to bidirectional and unidirectional conditions, we found that the OLR to bidirectional motion best fits an averaging model. These results reflect integration mechanisms in neural responses to contradicting sensory evidence as has been documented for other sensory and motor domains.",

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Visual motion integration of bidirectional transparent motion in mouse opto-locomotor reflexes

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