-
It has filled countless diapers,
caused discomfort for any number
-
of airline passengers,
and it totally ruined the Dude’s rug,
-
which really tied the room together, man.
-
Anatomists call it micturition,
and I don’t know why
-
because the rest of us call it urination,
which seems like a fine word.
-
All mammals and most animals
urinate to remove toxins
-
and to help maintain water-volume
homeostasis, or blood pressure.
-
And while some of us spray it around
to attract mates or mark territory,
-
or deter predators; as far as I know,
only humans actually study pee.
-
In fact, we’ve been doing it
for thousands of years.
-
Even before Hippocrates extolled
the diagnostic virtues of pee-sniffing,
-
early Sumerian and Babylonian physicians
were making urine-related observations.
-
Medieval doctors as well diagnosed
diseases based on on smelling,
-
inspecting, even tasting urine samples.
-
And although they were often
totally off-base,
-
which makes me feel bad for those guys
who sipped urine for no reason;
-
they were kind of on to something.
-
Today, urological tests can help detect
a lot of ailments based on
-
the color, the smell, the clarity,
and chemical composition of a sample.
-
Freshly peed urine is usually about
95% water,
-
slightly acidic with a pH of around 6,
a little bit aromatic,
-
and usually somewhere
between clear and dark yellow in color
-
depending on your level of hydration.
-
Urine also contains over
3000 different chemical compounds,
-
and their varying levels of concentration
can tell us a lot about
-
what’s going on in the body.
-
For example,
if you give me a urine sample,
-
I will have no idea what to do with it.
-
But if you give it to a doctor
and they can see that
-
it’s cloudy with white blood cells,
that’s a good sign
-
you’ve got a urinary tract infection.
-
If it smells sweet
and contains a lot of glucose,
-
you might have diabetes.
-
If it looks pink,
then unless you’ve recently eaten beets,
-
you probably have
internal bleeding somewhere.
-
And if it is chocked full of proteins,
you could be pregnant,
-
or working out too hard,
or have high blood pressure,
-
or be headed to heart failure.
-
So as you can see, even if the most
thought you’ve given the subject is
-
to wonder if you should pee now
or wait until the end of the movie;
-
the whole process of producing, storing,
and eliminating pee
-
is no where near as simple as it may seem.
-
From osmotic pressure
to stretch receptors to hormones,
-
our circulatory, nervous,
and endocrine systems regulate
-
how much urine we produce,
what goes into it,
-
and when to get rid of it.
-
So join me
as we journey into the world of pee.
-
Wait, can we rephrase that?
-
[♪ Intro Music ♪]
-
All right, how about:
“let’s look at where your pee comes from.”
-
No, actually,
that doesn’t sound good either.
-
Let’s begin by looking at
what regulates the production of urine.
-
That works.
-
Last time, we discussed
how your kidneys filter your blood,
-
but the actual production of urine
can be affected
-
by a whole host of factors.
-
One thing that might have
crossed your mind last time
-
is that the production of urine
must by its very nature
-
be influenced by blood.
-
Specifically, its volume and its pressure.
-
Because, step one in pee-making
is the process of glomerular filtration
-
where blood is filtered
in the little blood-filled balls of yarn
-
that are the glomeruli.
-
So, just like water in a hose,
higher pressure in the blood
-
must push more plasma
out of the capillaries
-
and into the glomeruli.
-
But here’s a problem:
Your kidneys can only handle
-
so much filtrate at a time.
-
So they have to maintain
a constant rate of flow inside of them.
-
This is known as
the glomerular filtration rate,
-
or how much blood passes through
the glomeruli every minute.
-
And your kidneys have ways
of regulating this rate
-
despite changes in blood pressure.
-
If your blood pressure happens
to increase, for example,
-
the higher pressure causes the arterioles
leading to your glomeruli to stretch.
-
And then the smooth muscle
in the walls of the glomeruli
-
respond to this stretching stimulus
by constricting,
-
automatically reducing the amount
of blood flow into the glomeruli
-
and leaving the flow rate
relatively unchanged.
-
This kind of intrinsic control,
or autoregulation, is helpful
-
in controlling the filtration rate
through normal ranges of blood pressures.
-
But the kidneys mostly regulate
urine concentration
-
at the other end of the nephron tubules.
-
This kind of regulation
I’m sure you’re familiar with.
-
If you’ve ever had too much coffee
or gone on a bit of a bender,
-
you may have experienced the pleasure
of having to pee every five minutes.
-
That’s because your endocrine system
has a lot to say
-
about your bathroom breaks.
-
So you have some strong hormonal
mechanisms that affect
-
when and how often you go.
-
And as it happens,
both caffeine and alcohol inhibit
-
the release of one of these hormones
called antidiuretic hormone, or ADH;
-
which is secreted by
the posterior pituitary gland
-
to help the body retain water
and stay hydrated.
-
How ADH works is kind of complex,
but first let’s remember
-
that cell membranes are generally
not that permeable to water.
-
But in the parts of the nephron
that reabsorb water,
-
like the descending limb of the loop
of Henle,
-
water has to move easily through cells
from the filtrate to the blood.
-
This is possible because of
special protein channels
-
in their membranes called aquaporins
that are on both the apical,
-
or filtrate-facing side, and the basal
or capillary-facing side of the cells.
-
By contrast, the cells lining
the collecting duct
-
only have aquaporins on the basal side,
so not a lot of reabsorption
-
takes place there usually.
-
But ADH triggers those cells
to move aquaporins they have in storage
-
over to the apical side,
which allows more water
-
to leave the urine.
-
And since caffeine
and alcohol inhibit ADH,
-
that means no moving aquaporins,
which means very little
-
water reabsorption,
and ultimately tons of peeing,
-
and dehydration.
-
So, yeah, lots of factors
affect the production of urine.
-
But once it’s produced,
it doesn’t just leave the building.
-
It has to be moved and stored
until the time is right.
-
Once the urine leaves the kidneys,
it enters the ureters,
-
a pair of slender tubes that drop down
to the posterior urinary bladder.
-
Contrary to what you might think,
your ureters aren’t just passive tubes
-
and your pee doesn’t wind up
in your bladder because of gravity alone.
-
Rather like the small intestines,
each ureter features a layer
-
of smooth muscle that contracts
to move urine using peristalsis.
-
The frequency and strength
of these peristaltic waves varies
-
depending on how fast urine
is being produced;
-
and a series of valves prevent pee
from backing up
-
making sure that instead
it reaches the bladder.
-
The bladder is a hollow, collapsible sac
that temporarily stores urine.
-
Like the kidneys, it’s retroperitoneal,
located posterior to the pubic bone
-
and anterior to the rectum.
-
The bladder wall consists of 3 layers:
an inner mucosa
-
surrounded by a thick muscular layer
called the detrusor
-
wrapped in a fibrous,
protective outer membrane.
-
The inner mucosal layer
consists of transitional epithelium,
-
which allows the bladder to expand
so it can hold more urine.
-
A handy feature for social mammals
like us who prefer dry underwear
-
and peeing in private.
-
When it’s empty,
it collapses into a triangular shape,
-
folding up on itself
like a deflated balloon.
-
Then as urine accumulates,
the bladder thins and expands
-
into a pear-shape,
and all those folds disappear.
-
A full bladder can comfortably hold
around 500 mL of pee,
-
though it can usually expand
to hold a maximum of around one liter.
-
At that point, though,
you’re pushing your luck
-
because prolonged overdistention
could, in theory, lead to a burst bladder.
-
Although you’d probably
just pee your pants first.
-
But let’s assume for the sake
of polite conversation
-
that you have found an appropriate
location to relieve yourself.
-
Your urine enters the thin
but muscular urethra
-
by passing through the internal
urethral sphincter.
-
Now we don’t actually have voluntary
control over this particular sphincter,
-
but the autonomic nervous system
keeps it cinched up
-
whenever you’re not peeing
to prevent leakage.
-
Once the urine is through the sphincter,
it heads down
-
through the urogenital diaphragm
which includes the last stop:
-
the external urethral sphincter;
which is probably the one
-
that you’re familiar with
because it’s made of skeletal muscles
-
and is the one that you control
voluntarily.
-
Only now are we finally ready to explore
the act of micturition itself,
-
the actual excretion of urine, urination.
-
As the pee from your morning coffee
builds up,
-
it causes the bladder to push out,
activating the stretch receptors
-
in its walls.
-
The resulting nerve impulses zip along
afferent fibers
-
to the sacral region of the spinal cord,
along interneurons, and toward the brain;
-
eventually exciting
the parasympathetic neurons
-
and inhibiting the sympathetic system.
-
This tells the detrusor to contract
while the internal urethral sphincter
-
simultaneously opens,
and the external sphincter relaxes
-
so that the pee can flow out.
-
This, you may or not recall,
is kind of an acquired skill.
-
When you’re a baby,
those stretch-receptor impulses
-
trigger a simple spinal reflex
that coordinates this whole process,
-
and you have no real control over
when you pee.
-
But within a couple of years of birth,
your brain’s circuits have developed
-
the ability to override
simple reflexive urination
-
and to choose a different neural pathway.
-
So how’s that possible?
-
Well, an area of your brainstem
called the pons
-
contains two different centers
that lock down your urination control,
-
or lack of it.
-
There’s the pontine storage area,
which inhibits urination;
-
and the pontine micturition center,
which gives it the green light.
-
As your bladder fills up,
impulses triggered by stretch receptors
-
head to the pons
and other higher brain centers
-
that give you that conscious feeling
that you have to pee.
-
If your bladder isn’t full
and you’re too busy to find a bathroom,
-
it mostly activates
the pontine storage area
-
that keeps you from peeing by
inhibiting your parasympathetic activity
-
and increasing sympathetic output.
-
Of course, the longer you hold it,
the more your bladder fills up,
-
and eventually the need to pee
becomes too strong to ignore.
-
At which point the pontine
micturition center jumps into action,
-
overriding the previous orders,
and opening the sphincters
-
so you can finally tinkle.
-
And that’s how your own
personal waterworks works.
-
Whether you’re a baby in diapers,
or a grown-up science student,
-
or a guy who was sent to
“leave a message”
-
on Jeffrey Lebowski’s rug.
-
Today you learned
how the urinary system regulates
-
the production of urine by maintaining
a study glomerular flow rate.
-
We also talked about the anatomy
of storing and excreting urine
-
from the ureters to the urethra;
and we went over the nervous system’s role
-
in controlling the act of urination.
-
Thank you to our Headmaster
of Learning, Linnea Boyev,
-
and thank you to all of our Patreon
patrons whose monthly contributions
-
help make Crash Course possible,
not only for themselves, but for everyone.
-
If you like Crash Course and you want
to help us keep making videos like this,
-
and you want to get thanked
at the end of every episode
-
like I just did
for all of our Patreon patrons;
-
if that’s you,
then thank you so much.
-
You can go to patreon.com/crashcourse.
-
This episode was filmed
in the Doctor Cheryl C. Kinney
-
Crash Course Studio.
-
It was written by Kathleen Yale,
edited by Blake de Pastino,
-
and our consultant is Dr. Brandon Jackson.
-
It was directed by Nicholas Jenkins,
edited by Nicole Sweeney.
-
Our sound designer is Michael Aranda,
and the Graphics team is Thought Cafe.
-
[♪ Outro Music ♪]
