PUBLICATION
Tilt In Place Microscopy (TIPM): a simple, low-cost solution to image neural responses to body rotations
- Authors
- Hamling, K.R., Zhu, Y., Auer, F., Schoppik, D.
- ID
- ZDB-PUB-221216-19
- Date
- 2022
- Source
- The Journal of neuroscience : the official journal of the Society for Neuroscience 43(6): 936-948 (Journal)
- Registered Authors
- Schoppik, David, Zhu, Yunlu
- Keywords
- none
- MeSH Terms
-
- Animals
- Microscopy*
- Neurons/physiology
- Posture/physiology
- Spinal Cord*/physiology
- Vestibular Nuclei/physiology
- Zebrafish
- PubMed
- 36517242 Full text @ J. Neurosci.
Citation
Hamling, K.R., Zhu, Y., Auer, F., Schoppik, D. (2022) Tilt In Place Microscopy (TIPM): a simple, low-cost solution to image neural responses to body rotations. The Journal of neuroscience : the official journal of the Society for Neuroscience. 43(6):936-948.
Abstract
Animals use information about gravity and other destabilizing forces to balance and navigate through their environment. Measuring how brains respond to these forces requires considerable technical knowledge and/or financial resources. We present a simple alternative: Tilt In Place Microscopy (TIPM). TIPM is a low-cost and non-invasive way to measure neural activity following rapid changes in body orientation. Here we used TIPM to study vestibulospinal neurons in larval zebrafish during and immediately after roll tilts. Vestibulospinal neurons responded with reliable increases in activity that varied as a function of ipsilateral tilt amplitude. TIPM differentiated tonic (i.e. sustained tilt) from phasic responses, revealing coarse topography of stimulus sensitivity in the lateral vestibular nucleus. Neuronal variability across repeated sessions was minor relative to trial-to-trial variability, allowing us to use TIPM for longitudinal studies of the same neurons across two developmental timepoints. There, we observed global increases in response strength, and systematic changes in the neural representation of stimulus direction. Our data extend classical characterization of the body tilt representation by vestibulospinal neurons and establish TIPM's utility to study the neural basis of balance, especially in developing animals.Significance Statement:Vestibular sensation influences everything from navigation to interoception. Here we detail a straightforward, validated and nearly-universal approach to image how the nervous system senses and responds to body tilts. We use our new method to replicate and expand upon past findings of tilt sensing by a conserved population of spinal-projecting vestibular neurons. The simplicity and broad compatibility of our approach will democratize the study of the brain's response to destabilization, particularly across development.
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Human Disease / Model
Sequence Targeting Reagents
Fish
Orthology
Engineered Foreign Genes
Mapping