Chapter 30 - Software tools for behavioral phenotyping of zebrafish across the life span

In this chapter, we address how one can detect and measure specific behaviors in zebrafish, from the embryonic stage to adulthood, and in various behavioral paradigms using automated, image-based analysis software. In the first section, we address the measurement of activity in embryos and heart rate in larvae. For the larval stage, we also show how software can analyze the fish's body shape and movement trajectory to measure activity and specific behaviors like avoidance and escape responses. Custom output variables address specific research questions and increase throughput. For adult zebrafish, we describe applications with the novel tank diving test, learning in the T-maze, aggressive behavior in mirror tests, and quantify shoaling behavior. The advantages of tracking in three dimensions relative to classic 2D tracking are also addressed. Finally, we discuss current limitations and directions for future development

An automated system for the recognition of various specific rat behaviours

The automated measurement of rodent behaviour is crucial to advance research in neuroscience and pharmacology. Rats and mice are used as models for human diseases; their behaviour is studied to discover and develop new drugs for psychiatric and neurological disorders and to establish the effect of genetic variation on behavioural changes. Such behaviour is primarily labelled by humans. Manual annotation is labour intensive, error-prone and subject to individual interpretation. We present a system for automated behaviour recognition (ABR) that recognises the rat behaviours ‘drink’, ‘eat’, ‘sniff’, ‘groom’, ‘jump’, ‘rear unsupported’, ‘rear wall’, ‘rest’, ‘twitch’ and ‘walk’. The ABR system needs no on-site training; the only inputs needed are the sizes of the cage and the animal. This is a major advantage over other systems that need to be trained with hand-labelled data before they can be used in a new experimental setup. Furthermore, ABR uses an overhead camera view, which is more practical in lab situations and facilitates high-throughput testing more easily than a side-view setup. ABR has been validated by comparison with manual behavioural scoring by an expert. For this, animals were treated with two types of psychopharmaca: a stimulant drug (Amphetamine) and a sedative drug (Diazepam). The effects of drug treatment on certain behavioural categories were measured and compared for both analysis methods. Statistical analysis showed that ABR found similar behavioural effects as the human observer. We conclude that our ABR system represents a significant step forward in the automated observation of rodent behaviour

An automated system for the recognition of various specific rat behaviours

The automated measurement of rodent behaviour is crucial to advance research in neuroscience and pharmacology. Rats and mice are used as models for human diseases; their behaviour is studied to discover and develop new drugs for psychiatric and neurological disorders and to establish the effect of genetic variation on behavioural changes. Such behaviour is primarily labelled by humans. Manual annotation is labour intensive, error-prone and subject to individual interpretation. We present a system for automated behaviour recognition (ABR) that recognises the rat behaviours ‘drink’, ‘eat’, ‘sniff’, ‘groom’, ‘jump’, ‘rear unsupported’, ‘rear wall’, ‘rest’, ‘twitch’ and ‘walk’. The ABR system needs no on-site training; the only inputs needed are the sizes of the cage and the animal. This is a major advantage over other systems that need to be trained with hand-labelled data before they can be used in a new experimental setup. Furthermore, ABR uses an overhead camera view, which is more practical in lab situations and facilitates high-throughput testing more easily than a side-view setup. ABR has been validated by comparison with manual behavioural scoring by an expert. For this, animals were treated with two types of psychopharmaca: a stimulant drug (Amphetamine) and a sedative drug (Diazepam). The effects of drug treatment on certain behavioural categories were measured and compared for both analysis methods. Statistical analysis showed that ABR found similar behavioural effects as the human observer. We conclude that our ABR system represents a significant step forward in the automated observation of rodent behaviour