Your search keyword '"Niels Christian Rattenborg"' showing total 2 results

1. A comparison of continuous and intermittent EEG recordings in geese: How much data are needed to reliably estimate sleep-wake patterns?

Author

Peter Meerlo, Sjoerd J. van Hasselt, Theunis Piersma, Niels Christian Rattenborg, Simon Verhulst, Meerlo lab, Piersma group, and Verhulst lab

Subjects

medicine.medical_specialty, Aves [Birds], medicine.diagnostic_test, Cognitive Neuroscience, Sleep wake, Sleep, REM, Electroencephalography, General Medicine, Audiology, Sleep in non-human animals, Non-rapid eye movement sleep, Fragmented sleep, Behavioral Neuroscience, Electrophysiology, Sample size determination, Geese, medicine, Environmental science, Animals, Humans, Continuous recording, Wakefulness, Sleep

Abstract

Recent technological advancements allow researchers to measure electrophysiological parameters of animals, such as sleep, in remote locations by using miniature dataloggers. Yet, continuous recording of sleep might be constrained by the memory and battery capacity of the recording devices. These limitations can be alleviated by recording intermittently instead of continuously, distributing the limited recording capacity over a longer period. We assessed how reduced sampling of sleep recordings affected measurement precision of NREM sleep, REM sleep, and Wake. We analysed a dataset on sleep in barnacle geese that we resampled following 12 different recording schemes, with data collected for 1 min per 5 min up to 1 min per 60 min in steps of 5 min. Recording 1 min in 5 min still yielded precise estimates of hourly sleep-wake values (correlations of 0.9) while potentially extending the total recording period by a factor of 5. The correlation strength gradually decreased to 0.5 when recording 1 min per 60 min. For hourly values of Wake and NREM sleep, the correlation strength in winter was higher compared with summer, reflecting more fragmented sleep in summer. Interestingly for hourly values of REM sleep, correlations were unaffected by season. Estimates of total 24 h sleep-wake values were similar for all intermittent recording schedules compared to the continuous recording. These data indicate that there is a large safe range in which researchers can periodically record sleep. Increasing the sample size while maintaining precision can substantially increase the statistical power, and is therefore recommended whenever the total recording time is limited.

Published

2021

2. Pupillary behavior during wakefulness, non-REM sleep, and REM sleep in birds is opposite that of mammals

Author

Niels Christian Rattenborg, Bertrand Massot, Dolores Martinez-Gonzalez, Gianina Ungurean, and Paul-Antoine Libourel

Subjects

Male, genetic structures, Iris sphincter muscle, Sleep, REM, Biology, Non-rapid eye movement sleep, General Biochemistry, Genetics and Molecular Biology, Pupil, Arousal, Mice, medicine, Animals, Wakefulness, Iris (anatomy), Columbidae, Mammals, Electroencephalography, Sleep in non-human animals, eye diseases, medicine.anatomical_structure, Female, sense organs, Sleep, General Agricultural and Biological Sciences, Neuroscience, psychological phenomena and processes, Pupillometry

Abstract

Mammalian pupils respond to light1,2 and dilate with arousal, attention, cognitive workload, and emotions,3 thus reflecting the state of the brain. Pupil size also varies during sleep, constricting during deep non-REM sleep4-7 and dilating slightly during REM sleep.4-6 Anecdotal reports suggest that, unlike mammals, birds constrict their pupils during aroused states, such as courtship and aggression,8-10 raising the possibility that pupillary behavior also differs between mammals and birds during sleep. Here, we measured pupil size in awake pigeons and used their translucent eyelid to investigate sleep-state-dependent changes in pupil size. Male pigeons constricted their pupils during courtship and other male-female interactions but not while engaging in other waking behaviors. Unlike mouse pupils, the pigeons' pupils were dilated during non-REM sleep, while over 1,000 bursts of constriction and relaxation, which we call rapid iris movements (RIMs), occurred primarily during REM sleep. Consistent with the avian iris being composed largely of striated muscles,11-15 rather than smooth muscles, as in mammals, pharmacological experiments revealed that RIMs are mediated by nicotinic cholinergic receptors in the iris muscles. Despite receiving input from a parasympathetic nucleus, but consistent with its striated nature, the avian iris sphincter muscle behaves like skeletal muscles controlled by the somatic nervous system, constricting during courtship displays, relaxing during non-REM sleep, and twitching during REM sleep. We speculate that during wakefulness, pupillary constrictions are involved in social communication, whereas RIMs occurring during REM sleep might maintain the efficacy of this motor system and/or reflect the processing of associated memories.

Published

2021