The Science of Birds - How Do Birds Sleep?
Episode Date: October 22, 2020SummaryWhen birds disappear at night, where do they go and what are they doing? Most of them are sleeping, of course. But sleep in birds differs greatly from what you and I do.In this episode, we disc...uss the most important functions of sleep in birds. Then we get into the evolution of sleep in birds.Along the way, we’ll talk about the similarities and differences of sleep between birds and mammals like us.Last, we cover where and how birds sleep, regarding location, posture, etc.Links to Some Things Mentioned in this EpisodeAvian Sleep Group at the Max Planck Institute for OrnithologyCommon Swifts Fly for 10 Months Without LandingThe bird-like dinosaur Mei Long (“Sleeping Dragon”)Link to this episode on the Science of Birds websiteErrors and ClarificationsI said that the fossil of the bird-like dinosaur Mei Long (“Sleeping Dragon”) was discovered in 2010. It was actually discovered in 2004. Support the show
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We see birds flapping around and hanging out all over the place in just about any natural habitat.
We often hear even more of them as they sing and call to each other.
But then as the sun sinks below the horizon and evening comes on, the birds disappear and go quiet.
These diurnal birds, the ones active in daylight, find places to settle in for the
night, places to sleep. I'm not sure why, but this nightly disappearing act amazes me.
But it makes perfect sense, of course, that all the birds I saw that day would get sleepy
and hide themselves away until the next morning. It's nothing miraculous. I guess what impresses
me is that I have only rarely come across a wild bird sleeping at night. My best example is when I
was leading a birding tour on the west coast of Mexico. My group and I were in a small boat cruising
through a crocodile-infested mangrove forest at night. In some places the mangrove branches
closed in overhead, interlacing, turning the channel into a dark tunnel. More than once,
I was thrilled when I saw a belted kingfisher perched on a branch, passing just inches over my head.
These birds were trying to sleep, but this loud boat full of apes had rudely awakened them.
They looked offended. But it was really cool to see where these kingfishers were tucked in for the night.
So all these sleeping birds are out there in the dark.
You and I have probably been surrounded by dozing birds
every time we've walked around a natural area at night.
I've fantasized about having heat vision goggles
that would allow me to see sleeping birds as little glowing blobs in the forest.
It turns out that other people had the same idea
and they actually did something about it.
In 2019, scientists in Australia published a study
where they surveyed forest birds at night using thermal cameras.
The surveys were conducted over several months.
This thermal technology allowed the researchers to detect the glowing infrared signals
from the warm bodies of 195 sleeping birds of 21 species.
The detection rate of this method was only one-third as good as it was during daytime hours.
So there's room for improvement, but still, this is really neat.
I might have to invest in one of those thermal cameras.
That might be dangerous, though, because if I could go birding at night and actually see where birds are sleeping, I might never get any sleep myself.
Hello and welcome. This is the Science of Birds. I am your host, Ivan Philipson.
The Science of Birds podcast is a lighthearted, guided exploration of bird biology for lifelong learners.
In this episode, we're taking a reasonably deep dive into how, when, and where birds sleep.
This is a bigger topic than you might think, and time's a waste in, so let's get into it.
What exactly is sleep?
If you're like me, you just take sleep for granted as the thing that happens for eight hours,
every night after you get in bed and lose consciousness.
Well, actually, if you're like me, sleep is that thing that happens to you only occasionally,
never lasting quite long enough on any given night.
Array for coffee.
Sleep is a recurring physiological state of the body and brain.
Scientists define it by either physiology or behavior.
Technical definitions of sleep, and there are several, include some combination of unconsciousness,
limited body movement, distinct brainwave patterns and eye movements, reduced response to external
stimuli, body posture, and a few other things. Some form of sleep is present in pretty much every
type of animal. Sleep-like states have been documented in everything from jellyfish and nematode
worms to bees, fish, and land vertebrates like you and me. And that includes birds, of course.
Sleep is driven by things that happen in the brain.
Chemical and electrical processes in the brain differ between waking and sleep.
Brain waves provide an important measure of these differences.
These waves are groovy rhythmic patterns made by millions of neurons communicating with each other.
Certain brainwave patterns dominate while an animal is awake and others occur during sleep.
Brain waves are commonly measured with an electroencephalogram, an eczephalogram, an
E-E-G. You've heard of R-E-M, which stands for rapid eye movement. During R-E-M or REM sleep,
our eyes wiggle back and forth and our brain waves oscillate rapidly. Most of our dreams
happen during REM sleep. Then we have slow wave sleep, SWS, during which, you guessed it, the brain
waves pulse more slowly. Slow wave sleep is what we call deep sleep. In humans,
REM and slow-wave sleep typically alternate over the course of a night.
Other mammals as well as birds have both REM and slow-wave sleep phases,
and there's evidence that some fish and reptile species display similar patterns.
The anatomy and physiology of the brain in relation to sleep is pretty complex,
so for today I'm not going to go into much more detail on that stuff.
Let's move on to why birds need sleep.
When a trait or behavior-like sleep is widespread across the animal kingdom,
we can infer why that might be.
It could be a primitive behavior that was present in the common ancestor of all these critters.
Or maybe the trait serves a really important function.
In that case, it might have evolved independently in each lineage.
Or, of course, the behavior could be both primitive and important.
We'll come back to the evolution stuff in a moment, but we do know that sleep serves a couple
critically important functions for birds.
First, sleep allows for healing, restoration, and the removal of wastes from the brain and
body.
Second, sleep allows for memory processing and consolidation.
Memory has many important functions in a bird's life.
For example, memory is crucial when a juvenile bird learns how to sing.
This is true for songbirds.
which account for about half of the world's 10,000 bird species.
Biologists have studied the relationship between sleep and memory in zebra finches.
These are perky little songbirds native to Australia.
They're used as model organisms in bird research.
In several lab studies, juvenile zebra finches were played a recorded Tudor song,
and this was the first song they ever heard.
This is how songbirds learn to sing.
they need to listen to a tutor first, whether a parent or another adult bird.
So these finches in the lab, they're 40 days old, and they have never heard the song of an adult up to this point.
Researchers found that brain patterns during sleep changed significantly after the juvenile finches heard this first song.
While asleep, their tiny brains lit up with bursts of neuron activity in the regions associated with singing.
So it seems like the recent memory of having heard an adult.
song is being processed in the sleeping brains of these young birds. The memory is being
consolidated. Hummingbirds and parrots also learn their songs. These bird groups are distantly
related to songbirds like the zebrafinch. As far as I know, biologists haven't yet figured out
if sleep is important for baby hummingbirds and parrots as they learn how to vocalize.
Chickens too are distant relatives of songbirds, but there is some data on them regarding
sleep in memory. Juvenile chickens, chicks, if you will, need to sleep in order to imprint
properly on their mother. Well, they'll visually imprint on anything that moves, really. Could
be a person, a dog, a bag of potato chips, whatever. In any case, this natural process is called
filial imprinting. Studies of chicks found that they were not very good at filial imprinting if they
didn't get some good sleep soon after seeing their mom or whoever for the first time. Now, I don't know about
you, but I'm picturing fuzzy yellow chicks huddled together and drifting off to sleep with their
tiny eyelids slowly closing. Cuteness Factor 1000. Other research shows that sleep is also important
for memory processing in adult birds. Adult zebra finches mentally replay their songs while they
sleep. These birds might be practicing in their sleep to maintain their refined songs. We don't
know this for sure, and research is ongoing.
And here's a puzzle.
It seems these practice songs that play in the Finch's brain during sleep are super
variable.
They're all over the place compared to the highly stereotyped song performed while awake.
Researchers aren't sure what this means.
Adult European starlings get clear memory benefits from sleep.
Unlike zebra finches, starlings are open-ended learners.
This means they can learn new songs or new,
song phrases throughout their lifetimes, not just when they're very young.
Starlings are way better at learning new song segments when they have had a chance to sleep
afterward. Those that heard songs in the morning and were tested later that day before getting
any sleep, well, they weren't so good at remembering new songs. The birds that had a good
night's sleep, however, were significantly better at reproducing the novel songs.
Despite what we know about the functions of sleep in birds and mammals, such as memory
consolidation, sleep is still a bit of a mystery. It's complex, and it varies a lot across species
and types of animals. We still don't know why sleep is so necessary. You know I can't get
through an episode without putting things into an evolutionary perspective. Sure, that's because
I have a background in evolutionary biology, but remember the famous quote by Theodosius Dobzhansky.
Nothing in biology makes sense except in the light of evolution.
Evolution is the unifying perspective of the biological sciences.
So, sleep, birds, what's the evolutionary deal?
Sleep as we know it in birds has similarities to sleep in mammals.
For example, both have REM and slow wave sleep.
These two animal lineages share a common ancestor 300 or so million years ago.
is sleep in birds and mammals similar because of their shared ancestry or did sleep evolve independently
in these two groups? Some biologists used to make the case that sleep evolved to be so similar
in birds and mammals because these animals are warm-blooded and have large complex brains.
REM and slow-wave sleep must serve necessary functions for such creatures. But since the complex
brain structures of birds and mammals are different and have evolved independently, it's
seemed sleep too probably evolved independently.
But in recent years, biologists have discovered that at least some reptiles and fish
have mammal and bird-like brain patterns during sleep.
Zebra fish, another model organism, no relation to zebra finches, have brain signatures during
sleep that look a lot like REM and slow wave sleep.
And you know, this makes me wonder if anyone has studied sleep in the zebra hound or the
zebra weasel or how about the good old zebra zebra but in all seriousness sleep patterns very much like rem and slow wave sleep have been recorded in the central bearded dragon a lizard from australia this means we need to consider the common ancestor of not just birds and mammals but also of fish and modern reptiles that wriggling ancestral creature lived more like 400 million years ago some features of sleep that we once thought were unique to human beings
humans, REM and slow wave sleep, might have existed in some form way back when vertebrates
hadn't even crawled onto land for the first time. Perhaps. But I think some biologists would
still argue that these aspects of sleep evolved independently through convergent or
parallel evolution in birds and mammals. Interestingly, research shows that ostriches, which
belong to an ancient group of birds, spend much more time in REM sleep than more recently evolved
birds. This is like what we see in the duck-billed platypus compared to more modern placental mammals.
There's also less of a distinction between REM and slow-wave sleep in these more primitive
animals, the ostrich and platypus. This suggests that the similarities we observe in sleep
between songbirds and mammals might have evolved on their own independently over hundreds of
millions of years.
I keep talking about how sleep is similar in birds and mammals, but there are several
major differences between what sleep is like for birds and what it's like for humans.
First, birds sleep in really short bouts. Instead of sleeping for eight hours at a time like
we do, or at least try to do, birds sleep only a few minutes at a time. But they repeat these
short bouts of sleep up to hundreds of times over 24 hours. In only a few short minutes, a
Bird goes through one or more full cycles of REM and slow wave sleep.
These alternate with maybe 10 seconds of REM and a couple minutes of slow wave sleep.
Only about 10% of their sleep is REM compared to the 25% that we need.
The second big difference between the way we sleep and the way bird sleep is that they can
sleep with only half their brain at a time.
You know the saying, sleep with one eye open, meaning be cautious and attentive even when
you're trying to sleep? Well, humans can't really do that, but birds can. Birds can let one half
or hemisphere of their brain fall asleep while the other half stays alert. This amazing ability is
called unihemispheric slow wave sleep. You've probably seen ducks adrift on a pond as they
sleep with their bills tucked under their feathers. Have you ever noticed one of those ducks having
one eye open and the other shut? That bird is sleeping with half of its brain while
staying vigilant with the other half. It's keeping an eye out for any signs of danger.
Ducks floating at the edge of a flock tend to keep their open eye facing out away from the center,
so they're looking in the direction where predators are more likely to sneak up.
Ducks in the middle of the group tend to feel more secure. They often allow themselves to close
both eyes and get some shut eye with their entire brains. Kind of changes the meaning of
sitting duck, doesn't it?
Unihemispheric slow-wave sleep has been documented in species across the avian tree of life,
from ducks and chickens to parakeets, falcons, and sparrows.
A few years ago, unihemispheric slow-wave sleep got some press
when a scientific paper was published about this phenomenon in frigate birds.
Researchers from the avian sleep group at the Max Planck Institute for Ornithology
were interested in how birds deal with sleep on multi-day non-stop.
flights. And by the way, I seriously love that there's an avian sleep group.
The bird of choice for this study was the great frigate bird. This seabird is a master of gliding
and soaring over the open ocean. Frigot birds routinely fly for days at a time without ever
landing on the sea surface. In fact, they can't swim or float and never land on water if they
can help it. The researchers connected tiny EEG devices to 15 female great frigate birds in the
the Galapagos Islands.
These devices measured the bird's brainwaves and were connected to little data logger
backpacks.
Data was collected on non-stop flights of up to 10 days.
This study had a couple of cool results.
First, it turns out that frigate birds do indeed use unihemispheric slow wave sleep
on their epic flights.
This was long predicted but never proven until this study.
Pretty awesome.
Second, these birds sleep less deeply and much less
often while flying than when perched on land.
This result surprised at the researchers.
While flying, the birds sleep about 45 minutes a day on average,
which is less than 10% of the time they sleep on land.
So even though frigate birds can cruise the skies using unihemispheric slow wave sleep,
they don't use it very often on these long flights.
It seems they need to be fully alert most of the time.
If you think frigate birds are impressive,
let me tell you about the common swift.
This species now holds the record for the longest uninterrupted flight.
They can stay in the air for ten months without ever landing.
They eat, drink, and mate while on the wing.
But scientists don't yet know how or how often they sleep.
These little swifts are too small to carry the data loggers used in the frigid bird study.
But as this technology continues to be miniaturized,
there's a good chance we'll someday have some data on that species.
Birds aren't alone in having the superpower of sleeping with one eye open.
We've known for a while that many marine mammals use unihemispheric slow wave sleep.
These include manatees, seals, sea lions, dolphins, and possibly some baleen whales.
There's even a wee bit of evidence of some asymmetry between the hemispheres of human brains during sleep.
One recent study showed that when a person sleeps in a little bit of.
an unfamiliar place for the first time, there is a weak but statistically significant difference
in responsiveness between the two halves of their brain, and they sleep less deeply overall.
You've probably had the experience of not getting much sleep in a strange bed.
I don't mean to suggest anything by that, so don't take that the wrong way.
Maybe this parallels what birds are doing, just not as dramatically.
Our ancient ancestors might have benefited from keeping one half of their brains a little more alert
when sleeping around the fire at a new campsite.
Like drowsing ducks on the lookout for danger,
they'd be faster to respond
when the proverbial saber-toothed tigers skulks into the firelight.
The third and last major difference I want to point out
between sleep in birds and humans slash mammals
is in seasonal changes.
Humans need the same amount of sleep each night,
whether it's summer, winter, whenever.
Birds, however, aren't on such an unchanging schedule.
Birds normally sleep a fair number of hours within a 24-hour cycle.
Diurnal birds sleep at night, nocturnal birds sleep during the day.
But during certain times of year, many species have wildly different sleep patterns.
These changes happen during migration and on the breeding grounds.
Species that migrate long distances every spring and fall rarely have the luxury of getting their normal nightly dose of zees while they migrate.
For example, Swains and Strush is a neotropical,
songbird that breeds in North America and spends the winter in Central or South America.
A 2006 laboratory-based study of this species shed some light on how it deals with sleep
during its long migration. Like many songbirds, Swainson's thrushes migrate at night. We don't know
how or if they sleep on these night flights. But at least in the lab conditions of this study,
thrushes in their migratory state slept at night only one-third as many hours as they
normally sleep when not migrating.
In this state, they also took a bunch of naps during the day.
That's probably the more interesting finding of the study.
These mini siestas last a few minutes each and appear to involve some regular sleep
and a few seconds of unihemispheric slow wave sleep.
It seems migrating Swainson's thrushes don't suffer from sleep deprivation
because they catch up on the rest they need during the day.
When humans don't get enough sleep, there are some lousy,
consequences. We get irritable, our cognitive ability is impaired, and we suffer lapses in memory.
When we're really sleep deprived, we can have hallucinations and even organ failure.
Birds, at least some of them, can deal with sleep deprivation so extreme that it might be
deadly to a human. And when you need to know about sleep deprivation in birds, who are you going to call
the avian sleep group? Scientists from the avian sleep group published a study in 2000.
on the pectoral sandpiper.
This shore bird breeds in the Arctic.
Males set up and defend territories for the purpose of mating with as many females as possible during the three-week breeding season.
In the 24-hour sunshine of the Arctic summer, these males display, chase, and fight for days or weeks at a time.
They sleep very little.
Unlike long-haul truckers, these feisty birds can't just use cocaine and loud music to stay alert.
Instead, they rely on a physiological ability to get by on very little sleep.
It's quite impressive.
This ability is an adaptation in the evolutionary sense.
The 2012 study revealed that the male pectoral sandpipers that slept the least
ended up having significantly more offspring that season.
Those birds got more of their genes into the next generation.
So this is a winning strategy in terms of natural selection.
For these sandpipers, the motto should be,
If you snooze, you lose.
We've talked about the functions of sleep in birds,
as well as some similarities and differences it has with sleep in mammals.
Now let's talk a little bit about where and how birds sleep.
They clearly must sleep.
At least most of them do most of the time.
Sleep has to be super important.
Otherwise, evolution would favor birds that just stay awake all the time.
Such birds could use the pectoral sandpiper playbook to make more babies and leave behind more genes.
And importantly, ever-wakeful birds would be far less vulnerable to predators.
The danger of being attacked by a predator while sleeping seems to be an enormously important factor in the sleeping behavior of birds.
This was demonstrated by a 2006 analysis of sleep data from 23 bird species across a wide
diversity of families. Species ranged from owls and turkeys to penguins, magpies, and sparrows.
The researchers tried to find any links, any correlations between sleep duration and quality
with variables such as body mass, brain mass, and metabolic rate.
In the end, the only significant relationship they found was between,
the amount of deep sleep a bird gets and a variable they called the sleep exposure index.
This index captured the amount of predation risk faced by a particular bird species
based on where it typically sleeps. What this analysis showed was that bird species that tend
to be more exposed to predators while they sleep get less slow wave sleep, less of what we think of
as deep sleep. This makes sense. When birds feel safe, such as when they sleep tucked into a burrow or
tree cavity, they can let their guard down and get some deep sleep. The trade-off between a bird's
need to sleep and its risk of being a midnight snack for a predator is apparent in many
situations. For example, migrating garden warblers that are well-fed and in good shape sleep
with their heads up and facing forward. With this posture, these birds are more alert and able to
react quickly if a house cat or other predator enters the scene. Conversely, garden warblers in poor
metabolic condition during a migratory stopover need to conserve more energy while they sleep.
They tuck their heads under the feathers on their backs. You've no doubt seen this common
sleeping posture in birds. But these little warblers are less alert and thus more vulnerable in this
position. It's a trade-off between energy conservation and the risk of being killed by a predator.
Research on pigeons gives us another example. In experimental conditions, pigeons on perches close to the
ground sleep less deeply than pigeons on high perches. The idea here is that sleeping closer to
the ground is riskier. So birds are out there sleeping in all sorts of places, some of which
are pretty safe and snug, while others leave birds exposed to danger. Some sleep on the ground
and depend on their camouflage plumage. Night jars and nighthawks are good examples of this. Other
birds sleep while hidden in grass or among rocks. Some sleep on the water, like the ducks
we were talking about earlier. And of course, many, many species sleep in trees or bushes.
Perching birds can sleep on a tree branch without falling because when their legs are folded
under them, tendons in their ankles automatically cause their toes to clench. No muscles are
involved or any conscious control. Now maybe you're wondering when I'm going to talk about
birds sleeping in their nests. The crazy thing is that birds do not sleep in their nests. This
seems counterintuitive, but it's true. Nests are built for protecting eggs and baby birds.
I'm sure there are some exceptions out there because, well, nature is crazy like that. There's
always variation. And lastly, I want to return briefly to sleeping posture. As I mentioned,
a near universal sleeping posture in birds is where they place their head on their back,
usually with the bill tucked under their scapular feathers. Ducks, swans, sparrows, penguins,
many types of birds do this. For birders trying to identify ducks on a pond, this head-tucking
thing can be kind of frustrating. This sleeping posture has apparently been a feature of birds
for over 125 million years. In 2010, a new bird-like dinosaur was discovered in China. Its fossil
was curled up in a sleeping position just like that of modern birds. This little dinosaur was
given the scientific name, Mai Long, which in Chinese means
sleeping dragon.
The birds that share the earth with us today are living dinosaurs.
There are more than 10,000 species.
At any given moment, there are billions of birds out there somewhere, sleeping and dreaming.
Man, I thought this was going to be a short episode.
But, as with so many things in biology, once you start researching a topic, you end up going
down the rabbit hole.
or maybe the burrowing owl hole.
And before you know it, you have an episode that is twice as long as you set out to make it.
Oh, well, I hope you enjoyed how it turned out.
I'm seriously honored that you took the time to learn something with me today.
Every time I make a new episode, I really hope to improve the Science of Birds podcast.
So I'd love to hear your thoughts or any comments you have about the show.
You can let me know by sending me an email to Ivan at Scienceofbirds.com.
If you love birds and you want to keep learning about their fascinating biology, please subscribe to the podcast.
You can do that pretty much with any app you use, Apple Podcasts, Spotify, Google Podcasts, and so on.
And you can see the show notes for this episode, which is episode 10 on the Science of Birds website, Scienceof Birds.com.
I'm Ivan Philipson, and I'll catch you next time. Peace.