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Towards high-throughput phenotyping of complex patterned behaviors in rodents: focus on mouse self-grooming. Evan Kyzar , Siddharth Gaikwad , Mimi Pham, Jeremy Green, Andrew Roth, Yiqing Liang, Vikrant Kobla , Allan V. Kalueff. Introduction.
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Towards high-throughput phenotyping of complex patterned behaviors in rodents: focus on mouse self-grooming Evan Kyzar, SiddharthGaikwad, Mimi Pham, Jeremy Green, Andrew Roth, Yiqing Liang, Vikrant Kobla, Allan V. Kalueff
Introduction • Grooming is an important, evolutionarily conserved behavior observed in multiple taxa • Complex, highly organized behavior regulated by the basal ganglia and hypothalamus
Translational value • Due to its centrally-organized nature, self-grooming behavior is especially well-suited to research into basal ganglia disorders, autism, OCD, and AD/HD • Grooming behavior is also sensitive to anxiety, with more anxious animals generally exhibiting more robust grooming responses • Can be modulated by various behavioral, genetic, and pharmacological manipulations
Grooming research • Animal grooming has been studied extensively, especially in rodent models • Nonetheless, research has focused on ‘quantity’ endpoints such as frequency, duration, and latency • Little inquest has been made into the complex patterning of grooming behavior
Rodent grooming patterning • The typical grooming bout begins with paw licking followed by head and face grooming. Rodents then move on to grooming the body/leg area then culminate with tail and genital grooming • While endpoints such as total grooming duration can be both increased and decreased by stress, grooming patterning is more predictably sensitive to anxiety
Grooming analysis algorithm • Used to accurately describe alterations in rodent grooming syntax (Kalueff and Tuohimaa, 2004) Adapted from Berridge et al., 2004
Grooming analysis endpoints • Global measures – latency to first bout, frequency, duration • Regional distribution – frequency and duration of specific body area grooming (e.g. paws, body, tail, etc.) • Transitions – direction, or syntax, of each bout and the percentage of correct vs. incorrect transitions. A correct transition follows the stereotyped rodent grooming bout of paws to head to body to tail.
Abnormal grooming phenotypes • Sapap-3 mutant mice groom their facial regions excessively, similar to OCD and trichotillomania (Welch et al., 2004) • Hoxb8 mutant mice display excessive body grooming, often leading to hair loss (Chen et at. 2010)
Automated video-tracking • Recent technology has allowed for automated behavior detection in multiple animal models • Allows for rapid analysis of complex behavioral domains through the use of bioinformatics and efficient data processing • Useful in producing reliable, unbiased, and less variable results
So the question arises... How do we apply novel behavior recognition techniques to complex biological and behavioral phenomena such as self-grooming syntax?
Methods • 40 adult male C57BL/6J mice • Animals were individually placed in a clear observation cylinder for 5 min to examine grooming behavior • Subjects were manually observed and video-recorded from the front and side
Automated analysis • The videos were then analyzed using a custom-upgraded version of the HomeCageScan software (CleverSys, Inc., Reston, VA) • The software generated data on global endpoints (duration, frequency) but also data on the patterning of each grooming episode (paw licks, body/leg washing, etc.)
Experiment 1 • Designed to test the degree of agreement between manual and automated data • Mice (n=20) were individually tested in the observation cylinder for 5 min • Manual and HomeCageScan-generated data were compared using the ranked Spearman correlation test and the Mann-Whitney U-test
Results – Experiment 1 • Automated data is highly correlated to manual observations, both for total intra-bout transitions and for multiple specific transitions (e.g. head washes to body/leg wash)
Experiment 2 • Designed to determine the ability of automated systems to quantify different types of grooming • The experimental group (n=10) was gently misted with water before observation in the cylinder, to elicit a state of hyper-grooming
Results – Experiment 2 • Both manual observers and HomeCageScan detected differences in water-induced grooming when compared to novelty-induced grooming • Confirms the utility of automated methods in distinguishing different types of self-grooming activity
Results – Camera Comparison • Data from the front-view camera was compared to side-view data to establish the degree of agreement • The side-view camera detected only the small number of bouts “missed” by the front view camera as data generated from both cameras appears to be essentially identical (R = 0.92, p<0.05)
Summary • Data from each camera (side view vs. front view) was compared and revealed no significant differences. This suggests that a single camera setup is sufficient for grooming experimentation • This study has validated the use of software-driven techniques to study highly repetitive behaviors in rodents
Future directions • SERT and BDNF mutants • Social grooming • Other species (rats, primates, etc.) • Pharmacological manipulations • Basal ganglia research, autism, OCD, and AD/HD
Conclusion • This study aimed not to show the utility of a particular software to assess rodent grooming, but to demonstrate as a proof of concept a novel approach to quantify complex grooming phenotypes • Future studies into self-grooming behavior will elucidate many of the neural correlates of highly repetitive, centrally organized behavior
Acknowledgments • Special thanks to CleverSys, Inc. for personalized support and expert service • Sid Gaikwadand Mimi Pham for helping to run experiment and analyze videos • This study was supported by Tulane University Intramural and Pilot funds, Provost’s Scholarly Enrichment, Georges Lurcy, LA Board of Regents P-Fund granst and the NARSAD YI award
