Towards large scale automated cage monitoring - Diurnal rhythm and impact of interventions on in-cage activity of C57BL/6J mice recorded 24/7 with a non-disrupting capacitive-based technique

Automated recording of laboratory animal's home cage behavior is receiving increasing attention since such non-intruding surveillance will aid in the unbiased understanding of animal cage behavior potentially improving animal experimental reproducibility. Here we investigate activity of group h...

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Bibliographic Details
Published in:PloS one 2019-02, Vol.14 (2), p.e0211063-e0211063
Main Authors: Pernold, Karin, Iannello, F, Low, B E, Rigamonti, M, Rosati, G, Scavizzi, F, Wang, J, Raspa, M, Wiles, M V, Ulfhake, B
Format: Article
Language:English
Subjects:
Analysis
Animal behavior
Animal experimentation
Animal research
Animal welfare
Animals
Automation
Behavior
Behavior, Animal - physiology
Biology and Life Sciences
Brain research
Cages
Circadian Rhythm - physiology
Data collection
Data processing
Design of experiments
Dielectric properties
Disruption
Diurnal
Electrodes
Engineering and Technology
Estrus
Experimental design
Factorial experiments
Female
Females
Gender
House mouse
Housing, Animal
Intelligence gathering
Laboratories
Male
Males
Medicin och hälsovetenskap
Mice
Monitoring
Neurosciences
Parametric analysis
Phenotypes
Physical Sciences
Recording
Reproducibility
Research and Analysis Methods
Rodents
Sensors
Sex differences
Social Sciences
Surveillance
Temporal variations
Variance analysis
Ventilation
Women
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Summary:Automated recording of laboratory animal's home cage behavior is receiving increasing attention since such non-intruding surveillance will aid in the unbiased understanding of animal cage behavior potentially improving animal experimental reproducibility. Here we investigate activity of group held female C57BL/6J mice (mus musculus) housed in standard Individually Ventilated Cages across three test-sites: Consiglio Nazionale delle Ricerche (CNR, Rome, Italy), The Jackson Laboratory (JAX, Bar Harbor, USA) and Karolinska Insititutet (KI, Stockholm, Sweden). Additionally, comparison of female and male C57BL/6J mice was done at KI. Activity was recorded using a capacitive-based sensor placed non-intrusively on the cage rack under the home cage collecting activity data every 250 msec, 24/7. The data collection was analyzed using non-parametric analysis of variance for longitudinal data comparing sites, weekdays and sex. The system detected an increase in activity preceding and peaking around lights-on followed by a decrease to a rest pattern. At lights off, activity increased substantially displaying a distinct temporal variation across this period. We also documented impact on mouse activity that standard animal handling procedures have, e.g. cage-changes, and show that such procedures are stressors impacting in-cage activity. These key observations replicated across the three test-sites, however, it is also clear that, apparently minor local environmental differences generate significant behavioral variances between the sites and within sites across weeks. Comparison of gender revealed differences in activity in the response to cage-change lasting for days in male but not female mice; and apparently also impacting the response to other events such as lights-on in males. Females but not males showed a larger tendency for week-to-week variance in activity possibly reflecting estrous cycling. These data demonstrate that home cage monitoring is scalable and run in real time, providing complementary information for animal welfare measures, experimental design and phenotype characterization.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0211063