What do tea, energy drinks, chocolate, cola,
and coffee have in common?
They all contain caffeine, the most popular
psychoactive drug in the world.
Almost everyone knows firsthand how effective
caffeine is at keeping you awake, but how
does it do it?
Listen in to this episode of Medicurio to
explore the history, mechanism, and surprising
medical uses of caffeine.
Humans and caffeine have had a long history
together.
The drinking of tea began almost 5000 years
ago in ancient China while the drinking of
coffee began around 1000 years ago in Arabia.
In both civilizations, caffeine became an
integral part of their cultures.
Tea and coffee arrived in Europe around the
same time in the 16th century and likely caused
a revolution of knowledge and technology in
Western civilization.
This was because before caffeine was introduced,
due to the unsanitary water conditions, Europeans
often drank weak beer and wine throughout
the day instead of water.
The alcohol sterilized any germs, but also
made people tipsy.
You can imagine how that would have affected
productivity of workers in Europe.
When coffee became popular, not only did it
allow people to work energetically, it also
popularized coffeehouses, where people had
serious discussions about current events over
a cup of coffee, resulting in philosophy,
science, and politics all advancing in leaps
and bounds.
Without caffeine, Western civilization may
very well be a lot less developed than it
is now.
It was in the 1800’s when caffeine was finally
isolated from coffee, leading to extensive
research on the drug.
Finally, in the 1960’s, scientists discovered
how caffeine prevents sleepiness.
But to understand its mechanism, first we
need to figure out what is going on inside
our brain to make us fall asleep.
Cells in our body such as neurons break down
a molecule called adenosine triphosphate for
energy.
One of its breakdown products is adenosine.
Therefore, as the brain uses up energy throughout
the day, adenosine levels steadily increase
inside the neurons, leading to some adenosine
exiting the neurons which can bind to adenosine
receptors to cause sleepiness.
This is a very useful mechanism: high adenosine
levels in the brain indicate that the brain
has been very active and needs to rest, so
adenosine will make you fall asleep.
Specifically, adenosine has two effects, depending
on what type of adenosine receptor it activates.
If adenosine activates an A1 receptor, which
are found on neurons that keep the brain awake,
those neurons become less active.
If adenosine activates an A2A receptor, which
are found on neurons that initiate sleep,
those neurons become more active.
The combined activation of these two receptors,
a weaker wake signal and a stronger sleep
signal, as well as a variety of other hormones,
are responsible for making you fall asleep.
During sleep, the brain can replenish its
energy reserves and begins to eliminate adenosine.
Eventually, not enough adenosine is left in
the brain to activate adenosine receptors,
so you wake up feeling refreshed.
The structures of caffeine and adenosine are
very similar, which means that caffeine can
also bind to adenosine receptors.
However, since adenosine and caffeine are
not exactly the same, caffeine cannot activate
those receptors.
All it does is compete with adenosine for
the receptors, making it more difficult for
adenosine to activate those receptors to cause
sleepiness.
This is how caffeine makes you feel more alert,
essentially by decreasing the sensitivity
of your neurons to adenosine.
Caffeine’s effect only lasts for two to
four hours though, depending on how fast your
body breaks down caffeine, which is mainly
determined by genetics.
Once your body breaks down the caffeine, adenosine
can once again bind easily to its receptors
to cause sleepiness.
If you ingest caffeine on a daily basis, you
may have started with drinking one cup of
coffee a day and eventually moved on to three
or four a day to have the the same feeling
of alertness.
This is known as caffeine tolerance and often
happens to people who are chronic coffee drinkers.
This may be due to your neurons synthesizing
more adenosine receptors to compensate for
the receptors blocked by caffeine.
Therefore, more caffeine is needed to block
those additional receptors.
If a chronic caffeine user suddenly stops
taking caffeine, since there are now so many
adenosine receptors, the sleep-inducing effects
of adenosine may intensify.
Therefore, some users may experience withdrawal
symptoms such as fatigue, drowsiness, difficulty
concentrating, and irritability, the opposite
of caffeine’s effects.
To avoid these unpleasant feelings, these
people will continue to take caffeine.
This results in a mild physical dependence
on the drug, but not severe enough to be classified
as a true “addiction”.
Caffeine is nowhere near as addictive and
life-ruining as other stimulants like cocaine
and methamphetamines.
These withdrawal symptoms can last up to a
week until the number of adenosine receptors
returns to normal, and you can minimize these
symptoms by slowly weaning yourself off of
caffeine rather than stopping abruptly.
Adenosine receptors are also found outside
the brain, particularly in the heart and kidneys.
Just like how activating A1 receptors in wake-stimulating
neurons decreases their activity, activating
A1 receptors in the heart and kidneys also
decreases their activity: the heart slows
down while less blood is filtered through
the kidneys, leading to less urine production.
Just like in the brain, activating A1 receptors
is a way to give these organs a rest as well,
as both heart beating and urine production
consume energy.
When these A1 receptors are blocked by caffeine,
the opposite occurs: heart rate increases
and more urine is produced, symptoms you may
experience after a few cups of coffee.
For people who have ingested a large amount
of caffeine, they may experience uncomfortable
symptoms such as headache, dizziness, and
insomnia from over-alertness, jitteriness
from higher heart rate, and dehydration from
increased urine production.
However, caffeine is generally a safe drug. It is very difficult to overdose on caffeine.
Here are the caffeine levels in common caffeine-containing
substances.
For caffeine to be lethal to an average adult,
10 grams of it must be ingested within a few
hours, which is the equivalent of around 100
cups of coffee.
A few words of caution though: children should
avoid caffeine, as it is still unknown what
kind of effects caffeine has on a developing
brain.
And if you are constantly using caffeine to
avoid sleep, STOP.
Adequate sleep and rest are important for
healthy brain function.
Aside from its stimulatory effects, caffeine
also has some medicinal effects, though its
mechanism there is not well understood.
Caffeine is commonly found mixed with NSAIDs
such as acetaminophen and aspirin because
caffeine can enhance their painkilling properties.
This is particularly useful in treating pain
from migraines.
Even more interesting is that recent research
has found that moderate daily caffeine intake
seems to prevent various neurodegenerative
diseases such as Alzheimer’s and Parkinson’s
disease.
It is truly exciting that such a common drug
like caffeine may be the key to preventing
the devastating neurodegenerative diseases
that are affecting so many people right now.
So the next time you drink a cup of coffee
or tea, realize that you are taking in a drug
that not only played a huge role in human
civilization in the past, but may be an important
medical drug in the future.
Thanks for watching, and see you next time
on Medicurio.
