Abstract
Naturalistic behavior is highly complex and dynamic. Approaches aiming at understanding how neuronal ensembles generate behavior require robust behavioral quantification in order to correlate the neural activity patterns with behavioral motifs. Here, we present Variational Animal Motion Embedding (VAME), a probabilistic machine learning framework for discovery of the latent structure of animal behavior given an input time series obtained from markerless pose estimation tools.
To demonstrate our framework we perform unsupervised behavior phenotyping of APP/PS1 mice, an animal model of Alzheimer disease. Using markerless pose estimates from open-field exploration as input VAME uncovers the distribution of detailed and clearly segmented behavioral motifs. Moreover, we show that the recovered distribution of phenotype-specific motifs can be used to reliably distinguish between APP/PS1 and wildtype mice, while human experts fail to classify the phenotype based on the same video observations. We propose VAME as a versatile and robust tool for unsupervised quantification of behavior across organisms and experimental settings
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
↵†† kexin.luxem{at}dzne.de
↵¶ falko.fuhrmann{at}dzne.de
↵** johannes.kuersch{at}dzne.de
↵‡ stefan.remy{at}lin-magdeburg.de
↵# pavol.bauer{at}lin-magdeburg.de
Restructuring, Figure 2+3+4 updated, Table S1 + S2 updated, New Supplementary Figures
↵2 According to the usage documentation available within the MoSeq repository.