Ecological and social pressures interfere with homeostatic sleep regulation in the wild

Loftus, Judith; Harel, Roi; Núñez, Chase L.; Crofoot, Margaret C.

doi:10.7554/elife.73695

Cited by 29 publications

(26 citation statements)

References 114 publications

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“…Now, in eLife, Carter Loftus, Roi Harel, Chase Núñez and Margaret Crofoot report on the use of animal-borne accelerometers to map the sleep patterns of a free-ranging group of baboons in Kenya ( Loftus et al, 2022 ). Collars, which also housed GPS loggers for high-resolution movement tracking, were fitted to 26 adults, yielding data for more than 500 nights.…”

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confidence: 99%

“…Amongst other applications, they are being used to chart activity profiles, to estimate energy expenditure, and to detect difficult-to-observe behaviours ( Yoda et al, 2001 ; Wilson et al, 2006 ; Watanabe and Takahashi, 2013 ). Yet, despite the success of a first wave of pioneering studies, the potential of accelerometers as ‘sleep detectors’ remains to be fully exploited (e.g., Miller et al, 2008 ; Samson et al, 2018 ; for additional references, see Loftus et al, 2022 ).…”

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Accelerometer-based analyses of animal sleep patterns

Watanabe

Rutz

2022

eLife

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Accelerometer-based analyses of animal sleep patterns

Watanabe

Rutz

2022

eLife

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“…For example, diurnal species are largely inactive at night (Isbell et al . 2017; but see Loftus et al . 2021), meaning that GPS devices are often switched off at night to conserve battery.…”

Section: Some Strategic Considerationsmentioning

confidence: 99%

“…It can be useful to vary GPS sampling across time to focus data collection on certain time windows over others. For example, diurnal species are largely inactive at night (Isbell et al 2017; but see Loftus et al 2021), meaning that GPS devices are often switched off at night to conserve battery. It can also be worthwhile to program devices to increase sampling frequency during periods when animals are more active (e.g., morning and/or evening), or decrease sampling frequency during seasons when conditions are less optimal for data collection (e.g., during breeding seasons, Box 2).…”

Section: Partitioning Sampling Effort In Timementioning

confidence: 99%

A guide to sampling design for GPS-based studies of animal societies

Klarevas‐Irby

Papageorgiou

et al. 2022

Preprint

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GPS-based tracking is a widely used automated data collection method for studying wild animals. Much like traditional observational methods, using GPS devices to study social animals requires making a number of decisions about sampling that can affect the robustness of a study's conclusions. For example, sampling fewer individuals per group across many distinct social groups may not be informative enough for inferring behavioural patterns at a finer social organizational scale, while sampling more individuals per group across fewer groups limits the ability to draw conclusions about populations. Here, we integrate previous insights from animal social network analysis with simulated and empirical data to provide quantitative recommendations when designing GPS-based tracking studies of animal societies. We outline the trade-offs faced by researchers, and how these trade-offs should vary across social organizational scales and social systems in relation to questions of interest, such as those defined within versus among groups, and spanning from cohesive, stable groups through to more open societies. We discuss three fundamental axes of sampling effort requiring consideration when deploying GPS devices to study animal societies: 1) Sampling coverage—the number and allocation of GPS devices among individuals in one or more social groups; 2) Sampling duration—the total amount of time over which devices collect data; 3) Sampling frequency—the temporal resolution at which GPS devices record data. Exploring each axis, we quantify the relationship between sampling effort and sampling error, giving recommendations on GPS sampling design to address research questions across social organizational scales and social systems—from group movement to social network structure and collective decision-making. In doing so, we also highlight practical limitations on deploying GPS tracking. Our study provides practical advice for empiricists to navigate their decision-making processes when designing GPS-based field studies of animal social behaviours, and highlights the importance of identifying the optimal deployment decisions for drawing informative and robust conclusions.

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“…Bio-logging has become a powerful approach for studying behavior, allowing scientists to collect data over expansive spatial and temporal scales and from inaccessible environments (Brown et al, 2013; Kays et al, 2015). This approach has generated important insights into behaviors that were previously difficult or impossible to study effectively, including migration (Jesmer et al, 2018), dispersal (Klarevas-Irby et al, 2021), energetics (Flack et al, 2020; Williams et al, 2014), sleep (Loftus et al, 2022; Rattenborg et al, 2016), and individual and collective decision-making (Flack et al, 2018; Strandburg-Peshkin et al, 2015, 2017).…”

Section: Introductionmentioning

confidence: 99%

Quantifying the movement, behavior, and environmental context of group-living animals using drones and computer vision

Koger

Deshpande

Kerby

et al. 2022

Preprint

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1. Methods for collecting animal behavior data in natural environments, such as direct observation and bio-logging, are typically limited in spatiotemporal resolution, the number of animals that can be observed, and information about animals' social and physical environments. 2. Video imagery can capture rich information about animals and their environments, but image-based approaches are often impractical due to the challenges of processing large and complex multi-image datasets and transforming resulting data, such as animals' locations, into geographic coordinates. 3. We demonstrate a new system for studying behavior in the wild that uses drone-recorded videos and computer vision approaches to automatically track the location and body posture of free-roaming animals in georeferenced coordinates with high spatiotemporal resolution embedded in contemporaneous 3D landscape models of the surrounding area. 4. We provide two worked examples in which we apply this approach to videos of gelada monkeys and multiple species of group-living African ungulates. We demonstrate how to track multiple animals simultaneously, classify individuals by species and age-sex class, estimate individuals' body postures (poses), and extract environmental features, including topography of the landscape and game trails. 5. By quantifying animal movement and posture, while simultaneously reconstructing a detailed 3D model of the landscape, our approach opens the door to studying the sensory ecology and decision-making of animals within their natural physical and social environments.

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Ecological and social pressures interfere with homeostatic sleep regulation in the wild

Cited by 29 publications

References 114 publications

Accelerometer-based analyses of animal sleep patterns

Accelerometer-based analyses of animal sleep patterns

A guide to sampling design for GPS-based studies of animal societies

Quantifying the movement, behavior, and environmental context of group-living animals using drones and computer vision

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