Everything Everywhere Daily: History, Science, Geography & More - Antibiotics

Episode Date: October 8, 2023

One of the biggest changes to humanity over the last 100 years has been the increase in life expectancies.  One of the biggest reasons for the increase in life spans has been the development and use ...of antibiotics.  Yet, the development of antibiotics was largely accidental, and they have become so ubiquitous it is actually becoming a problem.  Learn more about antibiotics, their discovery, and their future on this episode of Everything Everywhere Daily. Sponsors Newspapers.com Newspapers.com is like a time machine. Dive into their extensive online archives to explore history as it happened. With over 800 million digitized newspaper pages spanning three centuries, Newspapers.com provides an unparalleled gateway to the past, with papers from the US, UK, Canada, Australia and beyond. Use the code “EverythingEverywhere” at checkout to get 20% off a publisher extra subscription at newspapers.com. ButcherBox ButcherBox is the perfect solution for anyone looking to eat high-quality, sustainably sourced meat without the hassle of going to the grocery store. With ButcherBox, you can enjoy a variety of grass-fed beef, heritage pork, free-range chicken, and wild-caught seafood delivered straight to your door every month. ButcherBox.com/Daily  Subscribe to the podcast!  https://link.chtbl.com/EverythingEverywhere?sid=ShowNotes -------------------------------- Executive Producer: Charles Daniel Associate Producers: Peter Bennett & Cameron Kieffer   Become a supporter on Patreon: https://www.patreon.com/everythingeverywhere Update your podcast app at newpodcastapps.com Discord Server: https://discord.gg/UkRUJFh Instagram: https://www.instagram.com/everythingeverywhere/ Facebook Group: https://www.facebook.com/groups/everythingeverywheredaily Twitter: https://twitter.com/everywheretrip Website: https://everything-everywhere.com/ Learn more about your ad choices. Visit megaphone.fm/adchoices

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Starting point is 00:00:00 One of the biggest changes to humanity over the last 100 years has been the increase in life expectancies. And one of the biggest reasons for the increase in lifespans have been the development in use of antibiotics. Yet the development of antibiotics was often accidental, and now they've become so ubiquitous that it's actually becoming a problem. Learn more about antibiotics, their discovery and their future on this episode of Everything Everywhere Daily. What if your perceptions about the past were wrong? throughline is a podcast that takes you back in time to uncover the parts of the story that may have gone unnoticed. It effectively turned day into night.
Starting point is 00:00:50 And how it shaped the world now. Time travel with us every week on the ThruLine podcast from NPR. One of the reasons why it took antibiotics so long to be developed is that for most of human history, we had absolutely no idea what caused most diseases. civilizations and cultures around the world had different explanations for what caused diseases. In the West, they called it evil humors or miasmas. In the East, diseases may have been blamed on an imbalance of chi, and in other cultures it was simply due to the spirits and the gods.
Starting point is 00:01:26 The point being, no one really knew what caused diseases. The person who actually discovered the existence of microorganisms was Anthony Van Leeuwenhook. In the late 17th century, he used a self-designed microscope to observe the tiny life forms that existed in drops of water, in addition to observing other cells. However, Van Lee Wynhook never made the connection that some of these tiny organisms could be responsible for causing disease. Throughout the 18th and 19th centuries, even though significant advancements were being made in physics and chemistry, there was little progress being made on the cause of disease.
Starting point is 00:02:00 If you remember back to my episode on Ignaz Semmelweis, he discovered that doctors washing their hands would dramatically reduce fatalities in the maternity hospital where he worked. Despite such a simple remedy, there was enormous resistance to a suggestion because it didn't fit with the prevailing theory of disease. Likewise, when John Snow discovered the cause of the cholera epidemic in London, he didn't know what was causing cholera. He just knew that the source of the problem was a particular water pump. It wasn't until the later half of the 19th century that evidence began to mount for what became known as the germ theory of disease. Louis Pasteur of France and Robert Koch of Germany were the leading figures behind the acceptance.
Starting point is 00:02:40 of the germ theory of disease. The germ theory of disease is so important and received so little attention that I'm going to dedicate an entire episode to it in the future. Prior to the discovery that germs were the cause of many diseases, there were many ancient cultures that had stumbled upon treatments for diseases that attacked microbes, even though they didn't know it. There's chemical evidence of antibiotic tetracycoline that's been found in the bones in ancient nubia dating back to approximately the years 3 to 500.
Starting point is 00:03:08 The source of the tetracycling was believed to have come from beer. There have been traces of the chemical artemisinin, which is used to treat malaria, found in plants that have been used for centuries in traditional Chinese medicine. Through trial and air, many people found molds and plants that could treat infections or illnesses. These were effectively antibiotics insofar as the chemicals in the mold or plant could kill bacteria. It wasn't until the late 19th and early 20th centuries that the germ theory of disease finally led to the creation of antiseptics and antibiotics, that would target harmful bacteria. The very first antibiotic drug ever commercially released was arsphenomin, or compound 606. It was created in the lab of the Nobel Prize-winning research physician Paul Ehrlich in 1907.
Starting point is 00:03:53 After testing hundreds of arsenic-based compounds, a Japanese researcher named Sahashi-Rohata, working in Ehrlich's lab, discovered that this compound was able to attack the bacteria that caused syphilis without harming the patient. This is really the key when it comes to antibiotics. Finding a substance that can kill bacteria is relatively easy. The problem is that a bacteria is a cell, and our bodies are made up of cells. If you kill the bacteria but also kill your own cells, you've only made things worse. Arsphenomin was released to the public in 1911 under the name Salversan. Despite the success of Arsphenamine, there weren't many antibiotics released in the years after.
Starting point is 00:04:33 The process of having to test hundreds of chemicals to find something that could kill or inhibit the growth of bacteria, while at the same time not harming human cells was extremely difficult. However, there was an accidental breakthrough which occurred in 1928. A Scottish researcher by the name of Alexander Fleming was working at St. Mary's Hospital in London, England. He was studying various strains of the Staphylococcus ores bacteria. Before going on vacation with his family in August of 1928, he prepared several cultures of the bacteria and put them aside on his laboratory table before he left. When he returned on September 3rd, he and an assistant examined the samples and found that Juan had sat with its cover off the entire time.
Starting point is 00:05:14 That sample had a blue-green mold that had developed. The bacterial colony didn't grow near the mold, but grew normally further away. He figured that there must have been something in the mold that inhibited the growth of the bacteria. He took a sample of the mold, grew more of it, and found that it exhibited the same properties whenever he checked. He later created a broth out of the mold and was able to concentrate the substance that was inhibiting bacterial growth. He dubbed the new substance, taken from the penicillium fungi, penicillin. He later stated, when I woke up after dawn on September 28th, 1928, I certainly didn't plan to revolutionize all medicine by discovering the world's first antibiotic or bacteria
Starting point is 00:05:53 killer. But I suppose that is exactly what I did. End quote. Penicillin was a massive breakthrough. It was a naturally occurring antibiotic that worked on a wide range of bacteria, including Staphylococcus, Streptoccus, and diphtheria. While it didn't work on everything, it worked on many of the most common types of harmful bacteria that humans encountered. Fleming was awarded the Nobel Prize in Physiology in 1945, was knighted, and named one of the top 100 most important people of the 20th century by Time Magazine. While the discovery of penicillin was undoubtedly important,
Starting point is 00:06:29 it didn't make an impact on the lives of average people right away. He published his results in 1929, but he himself didn't see any immediate applications. It wasn't until 1939 that a team of researchers led by Howard Flory were able to grow, harvest, and purify penicillin from mold cultures. The United States Department of Agriculture then created a system for the mass production of penicillin. Testing done on animals found that penicillin had little to no negative impact. It became one of the strategic assets of the Allies in World War II.
Starting point is 00:07:01 It was considered to be a wonder drug that saved thousands, if not tens of thousands of lives. While work was being done on penicillin, another antibiotic was released in 1935. Named Prontacil, it was the first of a family of antibiotics known as sulfanimides. After the war, the quest was on to find more antibiotics that functioned similarly to penicillin, but worked against a wider variety of bacteria. The 1950s and 1960s saw the discovery of dozens of new antibiotics and is largely considered to be the golden age of antibiotics. For the most part, these antibiotics were extremely successful. They resulted in treatments for a wide variety of bacterial infections and diseases, many of which had plagued humanity for thousands of years. In no small part, antibiotics were responsible for the increase in lifespans throughout the world.
Starting point is 00:07:52 However, there was a problem. More and more antibiotics were being prescribed, and there were more and more antimicrobial and antiseptic products put out in the market. People began to associate the idea of germs and microbes generally with bad things. It turned out there were bad microbes, but there were also good microbes. Antibiotics and antibacterial agents usually can't distinguish between the two. One important discovery, which is still not totally understood, was the importance of the microbiome which lives in our digestive system. While we don't know exactly how, how our guts microbiome functions with the rest of our body, there is a general consensus that
Starting point is 00:08:28 it is really important. Taking heavy doses of antibiotics can wipe out much of your microbiome, which can cause problems. There was another problem as well, which might be an even bigger problem, evolution and natural selection. Bacteria can reproduce and evolve rapidly. If an antibiotic can kill 99.99% of bacteria, then there's still the question of the remaining 0.01%. The tiny number of bacteria it doesn't kill may be resistant to the antibiotic. The resistant bacteria will then multiply, and soon you are left with a bacteria that causes the same problem, but is now resistant to the antibiotic that previously worked. Moreover, bacteria aren't like large multicellular organisms.
Starting point is 00:09:13 It's possible for bacteria to engage in what is known as horizontal gene transfer. This is when one bacteria species shares parts of its genetic makeup with another bacterial species. You might think that the solution is just to throw more antibiotics at the problem. That might work initially, but over time it will just result in bacteria that are resistant to multiple types of antibiotics. Antibiotics have, in some respects, become a victim of their own success. They were often casually prescribed without a second thought. They were cheap and had few negative consequences. The result was that over time, more and more antibiotics have become ineffective as more strains of bacteria have become resistant.
Starting point is 00:09:54 Moreover, as so many people take antibiotics, including their use in animal agriculture, many of them pass through us and end up in the water supply, where a large number of bacteria can develop resistances to them. This overuse of antibiotics has been coupled with an increased use of antibacterial cleaning agents at home. The lack of early exposure to microbes by children might be responsible for compromised immune systems,
Starting point is 00:10:17 which never developed the ability to fight microbes, because they'd never encounter them. As bacteria are becoming more resistant, new antibiotics are not being developed as rapidly anymore. While there are many antibiotics on the market, most of them fall into just a few major categories. Between 1935 and 1968, there were 12 new antibiotic categories discovered,
Starting point is 00:10:39 but between 1969 and 2003, only two were discovered. An estimated 23,000 people a year, in just the United States, die annually now due to infection, by strains of bacteria that have developed resistance to antibiotics. In addition to trying to discover more antibiotics, one of the solutions is simply to use antibiotics more judiciously.
Starting point is 00:11:01 Stop over prescribing antibiotics and only use them when necessary for both humans and animals. People also need to stop dumping old antibiotics down the drain. Throwing antibiotics in the trash is a better solution than letting them get into the water supply. The development and widespread use of antibiotics was, One of the most important medical innovations of the 20th century. Millions of lives have been saved by their use. However, we now may be suffering from too much of a good thing. In order to continue to allow antibiotics to be effective,
Starting point is 00:11:33 we may have to use them less to ensure that when we do use them, they remain effective. The executive producer of Everything Everywhere Daily is Charles Daniel. The associate producers are Peter Bennett and Cameron Kiever. I wanted to give a big thanks to everyone who supports the show on Patreon. your support helps me put out a new show every day. And if you're interested in everything everywhere daily merchandise, Patreon is currently the only place where it's available.
Starting point is 00:12:01 And if you'd like to talk to other listeners of the show and get notified of future episodes and projects, please join my Facebook group or Discord server. Links to everything are in the show notes.

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