PUBLICATION
High throughput, rapid receptive field estimation for global motion sensitive neurons using a contiguous motion noise stimulus
- Authors
- Zhang, Y., Arrenberg, A.B.
- ID
- ZDB-PUB-190730-9
- Date
- 2019
- Source
- Journal of Neuroscience Methods 326: 108366 (Journal)
- Registered Authors
- Arrenberg, Aristides, Zhang, Yue
- Keywords
- Receptive field, calcium imaging, direction-selective, motion vision, noise stimulus, optic flow, pretectum, reverse correlation
- MeSH Terms
-
- Animals
- Models, Biological*
- Motion Perception/physiology*
- Neurons/physiology*
- Neurosciences/methods*
- Optic Flow/physiology*
- Pretectal Region/physiology*
- Visual Fields/physiology*
- PubMed
- 31356837 Full text @ J. Neurosci. Methods
Citation
Zhang, Y., Arrenberg, A.B. (2019) High throughput, rapid receptive field estimation for global motion sensitive neurons using a contiguous motion noise stimulus. Journal of Neuroscience Methods. 326:108366.
Abstract
Background The systematic characterization of receptive fields (RF) is essential for understanding visual motion processing. The performance of RF estimation depends on the employed stimuli, the complexity of the encoded features, and the quality of the activity readout. Calcium imaging is an attractive readout method for high-throughput neuronal activity recordings. However, calcium recordings are oftentimes noisy and of low temporal resolution. The RF estimation of neurons sensitive to global motion is particularly challenging due to their potentially complex combination of preferred directions across visual field positions.
New method Here, we present a novel noise stimulus, which is enriched with spatiotemporally contiguous motion and thus triggers robust calcium responses. We combined this contiguous motion noise (CMN) stimulus with reverse correlation followed by a two-step nonparametric cluster bootstrapping test for efficient and reliable RF estimation.
Results The in silico evaluation of our approach showed that RF centre positions and preferred directions are reliably detected in most of the simulated neurons. Suppressive RF components were detected in 40% of the simulated neurons. We successfully applied our approach to estimate the RFs of 163 motion-sensitive neurons in vivo within 40 minutes in the pretectum of zebrafish. Many in vivo neurons were sensitive to elaborate directional flow fields in their RFs.
Comparison with existing methods Our approach outperforms white noise methods and others due to the optimized motion stimulus statistics and ascertainable fine RF structures.
Conclusions The CMN method enables efficient, non-biased RF estimation and will benefit systematic high-throughput investigations of RFs using calcium imaging.
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