♪ Aspirin might seem like the most generic,
boring pill ever. I mean, the patent for it expired literally
a hundred years ago. And we have all kinds of better over-the-counter
painkillers these days. But behind those tiny, cheap, plain-looking
pills is a story that changed medicine forever. Because aspirin isn’t just an old pill. It was the one of the first pills — or at
least, one of the first medicines we learned how to make ourselves. And we're still discovering new uses for it
today. So, the active ingredient in aspirin is a
compound called acetylsalicylic acid. But more than 3,000 years before we learned how to make it, doctors were using its original natural source, willow bark, as a medicine. Ancient Egyptians used willow and myrtle to treat fever and pain, some of the same symptoms we use modern-day aspirin for. And old school medical superstars like Hippocrates, Celsus, and Galen had come across the soothing effects of willow bark for treating inflammation. But it wasn’t until the 1700s that a British
reverend named Edward Stone made a crucial observation. During a particularly nasty outbreak of ague, a fever thought to be caused by malaria, Stone noticed that willow bark tasted an awful lot like Peruvian bark, the more common ague treatment of the time. Peruvian bark was good at relieving ague symptoms, but really expensive, and he thought willow might work as a cheaper alternative. So he spent the next few years collecting,
drying and powdering willow into a form that could be used to treat ague, eventually settling on a dosage of two scruples — which is a real unit of measure! It was about 2.5 grams of bark. His concoction wasn’t as powerful as Peruvian bark, which was a source of quinine a compound that actually kills the malaria parasite. But he did publish the first report of willow’s effects in a scientific journal, Philosophical Transactions. 35 years later, in 1826, a French researcher
isolated the active ingredient in willow bark: a yellowish crystal that was named salicin
a couple of years later. Around the same time, a much larger shift
was happening among scientists. For a long time, a lot of chemists thought
substances from living beings had some kind of vital force that made them different than non-living things an idea known as vitalism. A drop of human sweat would just be different than anything we could make in the lab. How? It just is! But in 1828, a German chemist named Friedrich Wohler showed otherwise when he synthesized urea, a substance found in both sweat and
urine — hence the name. This was the first time that someone made
an organic compound from inorganic materials in the lab. Wohler didn’t set out to disprove vitalism
— he was originally trying to make a totally different compound. But when he accidentally made urea instead, scientists began to think maybe living things weren’t so chemically different from non-living things. This event swung the doors wide open for experimentation into organic chemistry — the study of compounds usually found in living things. So for drugs like aspirin, the next few years
were one big progress party. In 1838, an Italian scientist named Raffaele
Piria synthesized a stronger form of the active ingredient in willow bark for the first time:
salicylic acid. This might not seem like that big of a deal,
especially compared to the neat and tidy synthesis in modern labs, but it marked an enormous
shift in our approach to drug development. Researchers weren’t just purifying what
they found in nature anymore they were actively working to change the chemical structure of compounds to develop more effective treatments. It’s one of the biggest differences between
old school and modern medicine. Salicylic acid might sound familiar if you’ve
used topical acne treatments, but it wasn’t quite modern-day aspirin yet. By 1876, a Scottish doctor had published a
positive review of salicylic acid’s effects on rheumatism in The Lancet, in a paper titled “Rheumatic Fever Treated by Salicylic Acid” It was no controlled, double blinded study
by any means, but the word was getting out that this stuff might turn into something
big. Except, there was a problem. Because that was only the first half of the
paper’s title. The second half was “Symptoms of Poisoning Produced by the Acid”. People weren’t actually being poisoned,
but it’s not hard to see why it looked like they were: salicylic acid worked for fever,
pain, and inflammation, but it also often caused gastritis, where the stomach lining becomes inflamed. Maybe a little bit ironic, considering the
medicine usually reduced inflammation, but it turns out the stomach lining doesn’t
really like being eroded, and that’s what the salicylic acid was doing. As you can probably imagine, this is not pleasant. It tends to lead to, like, nausea and vomiting. Meanwhile, something else was changing in the medical world. Researchers were starting to realize that
a lot of the chemical byproducts of dye manufacturing could be used in medicine. This is actually how some of the first pharmaceutical companies were born — they started out as dye manufacturers. The Bayer group in Germany was one of those dye companies that started branching out into medicine. And around the end of the nineteenth century, a couple of scientists at the Bayer group in Germany came up with a protocol to modify salicylic acid and make it less toxic. This is where the history of aspirin starts
to get a little controversial, because at least three different scientists all claimed
credit for the discovery. But either way, the process they came up with involved a reaction known as acetylation. It replaced one of salicylic acid’s hydroxyl
group — that’s an oxygen and hydrogen bonded to a carbon — with an acetyl group,
which is two carbons, one double-bonded to an oxygen and the other bonded to three hydrogens. The result was acetylsalicylic acid, the modern active ingredient in aspirin. The compound had technically been synthesized by a French chemist about 50 years earlier, but his version was impure and unstable. The reaction used by the chemists at Bayer
didn’t have those problems, and they ended up with a drug that reduced a lot of that
gastrointestinal irritation, at least compared to regular salicylic acid. Gastritis was still a side effect, but it
didn’t happen as often or as badly. And as far as industry was concerned, companies now had a reliable way to make a highly useful pill. It quickly became the world’s best selling
drug, in part because people were already used to taking salicylic compounds. This was just a safer and less toxic version. More positive medical reports kept coming
in, so aspirin continued to grow in popularity. And in 1915, it became available without a
prescription which made it the first synthetic, over the counter drug. This was about two years after Bayer stopped producing over-the-counter heroin, by the way, so for a while you could stroll into
any pharmacy and buy heroin but needed to get a prescription for aspirin. The times, they have changed. After aspirin became available over-the-counter, not much happened for a while. There were some legal changes when Bayer lost their trademark, which was part of Germany’s deal with the Allied powers after World War
I. But on the scientific side of things, there
wasn’t much progress for a few decades. Keep in mind that all this time, we really
had no idea how aspirin worked. We knew what it did, but not how. It took until around 1970 for British pharmacologist
Sir John Vane and his research team to figure that out. Their experiments involved inducing severe
allergic reactions in rabbit and guinea pig lungs, then studying both the chemicals produced during the allergic reaction and the effects of aspirin on those compounds. The team found that the allergic reactions
caused cells to produce more prostaglandins, a type of hormone. And aspirin seemed to inhibit that production. They were able to tie prostaglandins to fever, inflammation, and headaches, so this went a long way toward explaining how aspirin worked. A few years later, other scientists came across prostaglandins again. In 1976, researchers discovered cyclooxygenase, or the COX enzyme, which makes a few different biomarkers, including prostaglandins. And once you introduce it to aspirin, the
drug irreversibly binds to it. More COX binding, less prostaglandin, so less pain. The problem, though, is that there are multiple kinds of these enzymes, and they all do slightly different things. While COX-2 produces prostaglandins during inflammation, a COX-1 enzyme has the added duty of making prostaglandins to protect the lining of your stomach. And aspirin affects both COX-1 and COX- 2,
which is why it can act as a pain reliever, but also messes with the whole stomach lining thing. So doctors needed to find drugs that could
do the heavy lifting of aspirin, but without causing upset stomach. That’s where other NSAIDs, or non-steroidal anti-inflammatories, came in. As you might have guessed, their name comes from the fact that they reduce inflammation without being steroids. Pharmaceutical companies were after any drugs that would selectively inhibit COX-2 without touching COX-1. Acetaminophen seemed like a good alternative. We’d known about its pain-relief effects
for about a hundred years. But it’s not a proper NSAID. It reduces pain like one, but doesn’t do
anything for inflammation. Today, we have other actual NSAIDs, like ibuprofen, which can still irritate your stomach but seem to do it less than aspirin. Aspirin, though, is still extremely popular. That’s because, in addition to its pain
and fever reduction powers, it has benefits in preventing heart disease. It was a surgeon named Lawrence Craven — primarily an oral surgeon, oddly enough, not a cardiologist — who stumbled upon this idea in the early
1950s. Craven performed a lot of surgeries on tonsils and the adenoid glands, a pretty routine procedure by his standards. He’d usually do the surgery in the morning
and send the patient home in the afternoon, often prescribing aspirin chewing gum for
the pain. But he noticed that as the use of aspirin
gum increased, so did more oral bleeding. Craven was convinced that aspirin was preventing prothrombin, one of the factors in blood clotting. He even went as far as taking 12 aspirin a
day to give himself a nosebleed and show the blood thinning effects of the drug. Over the next few years, he prescribed aspirin to all of his patients who were at risk for a heart attack - mostly older, overweight men. His rationale was that rapid blood clotting
could cause in heart attacks in the arteries around the heart that experienced plaque buildup, or atherosclerosis. Craven thought aspirin would reduce coagulation, allowing blood to pass through the arteries smoothly, and reduce heart attacks. But really, all he had was anecdotal evidence and observations. Over the next few decades, multiple doctors and scientists would learn more about aspirin’s use as a blood thinner with much more rigorous science. And then, in the 1960s, researchers made a
game-changing discovery: aspirin had anti-platelet effects. Platelets are tiny cells in the blood that
help clots form, and aspirin acts as a blood thinner by keeping them from clumping together. That’s why they won’t let you donate platelets if you’ve taken aspirin in the last two days. So Craven’s speculation was actually pretty
close. Platelets bunch up around those atherosclerotic sites in blood vessels, causing heart attacks. Today, doctors will recommend low dose, daily aspirin for certain patients — it can reduce the chances of heart attacks in people who’ve already had a heart attack or stroke. And more recent research has shown that low doses of aspirin might help prevent other diseases, too — especially colorectal cancer. None of this means you, generic person, should start popping an extra pill with breakfast, unless your doctor tells you to. The risk of side effects isn’t generally
worth it, and we’re still learning more about which doses work and for whom. But one thing’s for sure: that old, boring,
little pill has come a long way since the early days of grinding up willow bark. Thanks for watching this episode of SciShow, which was brought to you by our patrons on Patreon! If you want to help us keep making episodes like this, just check out patreon.com/scishow. And if you’re as fascinated as I am by the
stories behind the science we have today, we have a whole, new History of Science series over at youtube.com/crashcourse. ♪
