GoKawiilLots of people die after overdosing on acetaminophen (paracetamol, often sold as Tylenol or Panadol). In the U.S., it’s estimated to cause 56,000 emergency department visits, 2,600 hospitalizations, and 500 deaths per year. Acetaminophen has a scarily narrow therapeutic window. The instructions on the package say it's okay to take up to four grams per day. If you take eight grams, your liver could fail and you could die. Meanwhile, it seems to be really hard to kill yourself by overdosing on ibuprofen (Advil, Nurofen, Motrin, Brufen). In 2006, Wood et al. searched the medical literature and found 10 documented cases in history. Nine of those cases involved complicating factors, and in the 10th, a woman took the equivalent of more than 500 standard (200mg) pills. So, for many years, if I needed a painkiller, I’d try to take ibuprofen rather than acetaminophen. My logic was that if eight grams of acetaminophen could kill my liver, then one gram was probably still hard on it. I’m fond of my liver and didn't want to cause it any unnecessary inconvenience. But guess what? My logic was wrong and what I was doing was stupid. I’m now convinced that for most people in most circumstances, acetaminophen is safer than ibuprofen, provided you use it as directed. I think most doctors agree with this. In fact, I think many doctors think it’s obvious. (Source: I asked some doctors; they said it was obvious.) Should this have been obvious to me? I figured it out by obsessively researching how those drugs work and making up a story about metabolic pathways and blood flow, and amino acid reserves. It’s a good story, one that revealed that my logic stemmed from an egregious lack of respect for biology and that I’m a big dummy (always a favorite subject). But if the clearest road to some piece of knowledge runs through metabolic pathways, then I don't think that knowledge counts as obvious. So how is a normal person meant to figure it out? Why doesn't the fact that acetaminophen is typically safer than ibuprofen appear on drug labels or government websites or WebMD? Are normal people supposed to figure it out, or has society decided that this is the kind of thing best left illegible? Note: You should not switch medications based on the uninformed ramblings of non-trustworthy pseudonymous internet people.
Jul Quanouai
How does ibuprofen work?
Ibuprofen inhibits the body’s production of the Cyclooxygenase (COX) enzyme. This in turn inhibits the formation of messenger molecules involved in inflammation, which leads to less physical inflammation and thus less pain. The same story is true for almost all over-the-counter painkillers, which is why they’re almost all considered “non-steroidal anti-inflammatory drugs,” or NSAIDs. This includes ibuprofen, aspirin, naproxen (Aleve), and a long list of related drugs. But it does not include acetaminophen.
How does acetaminophen work?
Nobody knows! Like ibuprofen, acetaminophen inhibits some COX enzymes. But it does so in a weird way that barely affects inflammation or messenger molecules, so it’s unclear if this matters for pain reduction. In the brain, acetaminophen is metabolized into a mysterious chemical called AM404. This activates the cannabinoid receptors and increases endocannabinoid signaling, which seems to reduce the subjective experience of pain. AM404 also activates the capsaicin receptor, which is associated with burning sensations that you’d normally expect to increase pain, but maybe some desensitization thing happens downstream? And maybe acetaminophen also interacts with serotonin or nitric oxide or does other stuff? How this all comes together to reduce pain is still somewhat a scientific mystery. Aside: When trying to understand painkillers, it’s natural to focus on chemistry and molecular biology. But the unknown physical origins of consciousness are always nearby, looming ominously.
What risks does ibuprofen have?
In an ideal world, the only thing ibuprofen would do is reduce inflammation in the part of your body that hurts. But that is not our world. When ibuprofen inhibits the COX enzymes, it does so throughout the body. And mostly, that is bad. For one, ibuprofen reduces production of mucus in the stomach. That might sound okay or even good. But stomach mucus is important. You need it to shield the lining of your stomach from your extremely acidic gastric juice. Having less mucus can lead to gastrointestinal problems or even ulcers. Ibuprofen also affects the heart. When ibuprofen inhibits the COX enzymes there, this in turn inhibits one chemical that prevents clotting and another that causes clotting. In balance, this seems to lead to more clotting, and an increased statistical risk of heart attacks . If you’re healthy, the risk of a heart attack from an occasional low dose of ibuprofen is probably zero. But if you have heart issues and take medium to large doses regularly for as little as a few days, this might be a serious concern. Ibuprofen also affects the kidneys. If you’re stressed, or cold, or dehydrated, or take stimulants, your body will constrict your blood vessels. That squeezes your kidneys’ intake tube, depriving them of blood. Your kidneys don’t like that, so they release signaling molecules to locally re-dilate the blood vessels. Trouble is, when ibuprofen inhibits COX enzymes in the kidneys, it inhibits those signaling molecules. If everything is normal, that’s okay, because the kidneys wouldn’t try to use those molecules anyway. But if your body has clamped down on the blood vessels, then the kidneys don’t have the tool they use to keep blood flowing, meaning they don’t get as much blood as they want. This is bad. There are many other less common side effects, including allergies, respiratory reactions in asthmatics, induced meningitis, and suppressed ovulation. If you take a lot of ibuprofen, this could hurt your liver. But the major concerns seem to be the stomach, the heart, and the kidneys.
What risks does acetaminophen have?
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