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Unihemispheric slow-wave sleep
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Sleep in which half the brain remains alert
A young house sparrow (Passer domesticus) exhibits unihemispheric slow-wave sleep.<br>Unihemispheric slow-wave sleep (USWS ) is sleep where one half of the brain rests while the other half remains alert. This is in contrast to normal sleep where both eyes are shut and both halves of the brain show unconsciousness. In USWS, also known as asymmetric slow-wave sleep , one half of the brain is in deep sleep, a form of non-rapid eye movement sleep and the eye corresponding to this half is closed while the other eye remains open. When examined by electroencephalography (EEG), the characteristic slow-wave sleep tracings are seen from one side while the other side shows a characteristic tracing of wakefulness.[1] The phenomenon has been observed in a number of terrestrial, aquatic and avian species.
Unique physiology, including the differential release of the neurotransmitter acetylcholine, has been linked to the phenomenon.[1] USWS offers a number of benefits, including the ability to rest in areas of high predation or during long migratory flights. The behaviour remains an important research topic because USWS is possibly the first animal behaviour which uses different regions of the brain to simultaneously control sleep and wakefulness.[2] The greatest theoretical importance of USWS is its potential role in elucidating the function of sleep by challenging various current notions. Researchers have looked to animals exhibiting USWS to determine if sleep must be essential; otherwise, species exhibiting USWS would have eliminated the behaviour altogether through evolution.[3]
The amount of time spent sleeping during the unihemispheric slow-wave stage is considerably less than the bilateral slow-wave sleep. In the past, aquatic animals, such as dolphins and seals, had to regularly surface in order to breathe and regulate body temperature. USWS might have been generated by the need to perform these vital activities simultaneously with sleep.[4]
On land, birds can switch between sleeping with both hemispheres to one hemisphere. Due to their poorly webbed feet and long wings, which are not completely waterproof, it is not energetically efficient for them to make rest stops or land on water, only to take flight again. Using unihemispheric slow-wave sleep, birds are able to maintain environmental awareness and aerodynamic control of wings while obtaining the necessary sleep they need to sustain attention during wakefulness. Their sleep is more asymmetric in flight than on land, and they sleep mostly while circling air currents during flight. The eye connected to the awake hemisphere of their brain is the one facing the direction of flight. Once they land, they pay off their sleep debt, as their REM sleep duration significantly decreases and slow-wave sleep increases.[5]
Despite the reduced sleep quantity, species having USWS do not present limits at a behavioral or healthy level. Cetaceans, such as dolphins, show preserved health as well as great memory skills. Indeed, cetaceans, seals, and birds compensate for the lack of complete sleep with efficient immune systems, preserved brain plasticity, thermoregulation, and restoration of brain metabolism.[4]
Physiology<br>[edit]
Polysomnogram demonstrating slow-wave sleep.<br>High amplitude EEG is highlighted in red.<br>Slow-wave sleep (SWS), also known as Stage 3, is characterized by a lack of movement and difficulty of arousal. Slow-wave sleep occurring in both hemispheres is referred to as bihemispheric slow-wave sleep (BSWS) and is common among most animals. Slow-wave sleep contrasts with rapid eye movement sleep (REM), which can only occur simultaneously in both hemispheres.[6] In most animals, slow-wave sleep is characterized by high amplitude, low frequency EEG readings. This is also known as the desynchronized state of the brain, or deep sleep.
In USWS, only one hemisphere exhibits the deep sleep EEG while the other hemisphere exhibits an EEG typical of wakefulness with a low amplitude and high frequency. There also exist instances in which hemispheres are in transitional stages of sleep, but they have not been the subject of study due to their ambiguous nature.[7] USWS represents the first known behavior in which one part of the brain controls sleep while another part controls wakefulness.[2]
Generally, when the whole amount of sleeping of each hemisphere is summed, both hemispheres get equal amounts of USWS. However, when every single session is taken into account, a large asymmetry of USWS episodes can be observed. This information suggests that at one time the neural circuit is more active in one hemisphere than on the other one...