PUBLICATION
Quantitative Image Analysis of Axonal Morphology in In Vivo Model
- Authors
- Nemoz-Billet, L., Brocard, J., Ruggiero, F., Bretaud, S.
- ID
- ZDB-PUB-231223-6
- Date
- 2023
- Source
- Methods and protocols 6(6): (Journal)
- Registered Authors
- Ruggiero, Florence
- Keywords
- 2D analysis, axon length, branching, development, motor neuron, quantification, zebrafish
- MeSH Terms
- none
- PubMed
- 38133136 Full text @ Methods Protoc
Citation
Nemoz-Billet, L., Brocard, J., Ruggiero, F., Bretaud, S. (2023) Quantitative Image Analysis of Axonal Morphology in In Vivo Model. Methods and protocols. 6(6):.
Abstract
Quantifying axonal branching is crucial for understanding neural circuit function, developmental and regeneration processes and disease mechanisms. Factors that regulate patterns of axonal arborization and tune neuronal circuits are investigated for their implication in various disorders in brain connectivity. The lack of a reliable and user-friendly method makes the quantitative analysis of axon morphology difficult. Specifically, methods to visualize and quantify the complex axon arborization are challenging to implement and apply practically. Our study was aimed at developing a robust but simple method of quantification that used ImageJ 2D analysis and compared it with Imaris visualization and analysis of 3D images. We used zebrafish fluorescent transgenic lines to perform in vivo imaging of developing motor neuron axons that adequately reflected the complexity of axonal networks. Our new method, developed on ImageJ, is easy and fast, giving access to new information such as collateral distribution along the axonal shaft. This study describes step-by-step procedures that can be easily applied to a variety of organisms and in vitro systems. Our study provides a basis for further exploration of neural circuits to gain new insights into neuronal disorders and potential therapeutic interventions.
Genes / Markers
Expression
Phenotype
Mutations / Transgenics
Human Disease / Model
Sequence Targeting Reagents
Fish
Orthology
Engineered Foreign Genes
Mapping