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Podcast Transcript
Iodine is far more important than you might think. It was discovered accidentally, yet it can be found almost everywhere.
It’s something so small you only need a trace of it, yet without it, entire populations can suffer devastating health consequences.
It has been used as a medicine and a disinfectant, and is even a critical chemical in the production of many of the electronic devices that we use today.
Learn more about iodine and why this element matters so much on this episode of Everything Everywhere Daily.
Iodine might seem like a rather odd element to be doing an episode on, but as you’ll see, if it wasn’t for iodine, you and I wouldn’t be here.
The story of iodine begins in 1811 in Paris, during the Napoleonic Wars, in the workshop of a saltpeter manufacturer named Bernard Courtois. Saltpeter, or potassium nitrate, was essential for making gunpowder, and France needed enormous quantities of it to fuel Napoleon’s military campaigns.
Courtois produced saltpeter by extracting it from seaweed ash collected along the Brittany coast. One day, while cleaning his copper vats with sulfuric acid, he added too much acid and noticed something remarkable: a cloud of violet vapor rose from the mixture and condensed on cooler surfaces as dark, metallic-looking crystals.
Courtois was struck by the novelty of the substance but lacked the resources to investigate it fully. He shared samples with colleagues and fellow chemists, and within two years, the great French chemist Joseph Louis Gay-Lussac and the English chemist Humphry Davy had each independently confirmed that the violet colored substance was a new element.
Gay-Lussac named it “iode,” from the Greek word iodes, meaning violet-colored. The English adapted this to “iodine.”
Iodine is the 61st most abundant element in the Earth’s crust, making it relatively rare compared to many other elements. It belongs to the halogen group, the same chemical family as fluorine, chlorine, and bromine, and shares their tendency to form salts and react readily with other substances.
In nature, iodine does not appear in its pure elemental form; instead, it is almost always found as iodide ions chemically bonded to other elements.
The oceans are the largest reservoir of iodine on Earth. Over billions of years, rainwater has slowly leached iodine from inland rocks and soils, carrying it through rivers and streams into the sea.
As a result, seawater contains a modest but consistent concentration of iodide, and marine organisms, seaweeds, fish, shellfish, and sea vegetables, have evolved to concentrate iodine in their tissues at levels far higher than the surrounding water.
This is precisely why Bernard Courtois was able to extract so much iodine from seaweed ash in the first place.
The distribution of iodine on land, however, is very uneven. Coastal regions and floodplains that receive regular deposits of marine sediment tend to have iodine-rich soils, while mountainous inland areas, particularly those shaped by ancient glaciation, which stripped away the topsoil, are severely iodine-deficient.
The Himalayas, the Alps, the Andes, and the Great Lakes region of North America are all areas where iodine-poor soil yields iodine-poor crops and livestock. This geographic imbalance has had enormous consequences for human health throughout history.
More on that in a bit….
Concentrated deposits of iodine compounds are found in a handful of places around the world. Chile is by far the largest producer of iodine, thanks to vast deposits of caliche ore in the Atacama Desert, which contains iodate minerals.
Japan and the United States are also significant producers, obtaining iodine from ancient seawater trapped in rock formations, which are pumped to the surface and processed. These three countries together account for the overwhelming majority of the world’s iodine supply.
Iodine and its compounds have found their way into a surprisingly wide range of industrial applications. In the chemical industry, iodine serves as a catalyst in the production of a host of everyday plastics and synthetic fibers. Iodine compounds are used in the production of certain pharmaceuticals, dyes, and specialty chemicals.
One of the most important industrial uses of iodine is in the manufacture of polarizing films for liquid crystal displays. The thin filters in LCD screens used in televisions, computer monitors, and smartphones rely on iodine-treated polyvinyl alcohol films to control light polarization.
As the global demand for flat-panel displays exploded over the last several decades, this application became one of the dominant drivers of iodine consumption worldwide.
Iodine also plays a critical role in animal feed supplements. Livestock raised far from the sea are vulnerable to the same iodine deficiencies as humans, and the agricultural industry adds iodine compounds to feeds to ensure the health and productivity of cattle, pigs, and poultry.
Photography once relied heavily on silver iodide, a light-sensitive material, though the digital revolution has dramatically reduced demand for it. Iodine is also used in the manufacture of certain inks, colorants, and as a stabilizing agent in some industrial processes.
One of the most widely known uses of iodine outside of medicine is as an antiseptic and disinfectant, and understanding why it works in this capacity also helps explain why it can be toxic in large amounts.
Elemental iodine and its compounds are powerfully reactive, as are all halogen elements on the periodic table.
When iodine contacts a microorganism, it penetrates the cell and disrupts the organism’s internal chemistry, particularly attacking proteins, nucleic acids, and fatty acids in the cell membrane. This broad, non-selective chemical aggression is what makes iodine such an effective killer of bacteria, viruses, fungi, and protozoa.
Tincture of iodine, which is iodine dissolved in alcohol, was one of the earliest antiseptics used in surgery and wound care. Its use became widespread in the latter half of the nineteenth century as the germ theory of disease took hold.
Povidone-iodine, a modern formulation that slowly releases iodine and is less irritating to tissues, remains a standard surgical scrub and wound antiseptic used in hospitals around the world today.
Iodine tablets are also used to purify drinking water in wilderness survival situations and in humanitarian emergencies, killing pathogens reliably even in cloudy or cold water.
Now we get into the ultimate paradox of iodine. Iodine is a disinfectant that kills cells it comes in contact with. Yet, this same substance is also vital for human life.
The human body contains only 15 to 20 milligrams of iodine in total, but that tiny amount performs a function of outsized importance: it is the essential ingredient in the production of thyroid hormones.
The thyroid gland, a butterfly-shaped organ at the base of the throat, produces two primary hormones, thyroxine and triiodothyronine, which regulate metabolism throughout the body.
These hormones govern the rate at which cells consume energy, influence heart rate and body temperature, regulate the creation of proteins, and are critically involved in the development and function of the brain and nervous system.
Iodine is a structural component of both hormones; in fact, the numbers in their names refer directly to the number of iodine atoms each molecule contains. Without adequate dietary iodine, the thyroid cannot produce sufficient hormones, with serious and widespread consequences.
The most obvious outward sign of iodine deficiency is goiter, an abnormal enlargement of the thyroid gland. When the body does not receive enough iodine, the thyroid gland cannot synthesize sufficient thyroid hormone.
The pituitary gland, sensing this shortage, responds by releasing increasing amounts of thyroid-stimulating hormone to push the thyroid to work harder. Under this constant hormonal pressure, the thyroid tissue proliferates, and the gland grows larger and larger, sometimes to an extraordinary and visually dramatic degree.
A severe goiter can reach the size of a grapefruit or larger, creating a visible bulge on the front of the neck that is not merely cosmetic but can cause difficulty swallowing, breathing, and speaking.
Goiters were historically common in inland mountainous regions throughout world. In parts of the Alps, the Andes, and Central Africa, goiters were so common that they were simply considered a normal part of life.
Some historians have speculated that the swollen necks depicted in certain medieval and Renaissance artworks reflect this widespread condition. In the nineteenth century, before the cause was understood, goiter was sometimes called “Derbyshire neck” in England, “Himalayan disease,” or “mountain sickness,” reflecting its geographic clustering in iodine-poor upland regions.
But goiter is only the most visible sign of iodine deficiency. The broader consequences are perhaps even more serious. In pregnant women, iodine deficiency impairs the neurological development of the fetus, leading to a form of intellectual disability known historically as cretinism, a term now replaced by the more clinical phrase “iodine deficiency disorder.”
Children born to severely iodine-deficient mothers may have stunted growth, deafness, and significant cognitive impairment. Even mild to moderate iodine deficiency in children has been linked to lower IQ scores and reduced school performance.
The World Health Organization has identified iodine deficiency as the leading preventable cause of intellectual disability in the world.
The recognition that goiter was caused by iodine deficiency, a connection that became firmly established in the early twentieth century, led to one of the most successful public health campaigns in history: the iodization of table salt.
The idea was straightforward and elegant. Salt is consumed by virtually every human population in roughly predictable daily amounts. It is produced at a small number of centralized facilities, making it easy to fortify uniformly. And it is cheap.
By adding a tiny quantity of potassium iodide or potassium iodate to table salt, governments could ensure that even people living far from the sea in iodine-poor regions would receive enough iodine through their ordinary diet.
Switzerland was among the first countries to introduce iodized salt on a national scale, beginning in 1922, after surveys revealed that goiter and cretinism were rampant in the Alpine cantons.
The results were dramatic: rates of goiter fell precipitously within a generation. The United States followed in 1924, and over the subsequent decades, country after country adopted salt iodization programs.
Today, the WHO estimates that approximately 88 percent of the world’s population has access to iodized salt, and global levels of iodine deficiency disorder have been substantially reduced, though they have not been eliminated. Populations in parts of Sub-Saharan Africa and South Asia, as well as some isolated rural communities, remain at risk.
It is worth noting that not all salt is iodized. Sea salt, kosher salt, and many artisanal salts sold in the United States and elsewhere do not contain added iodine.
As consumer interest in specialty salts has grown and people have moved away from standard table salt, some nutritionists have expressed concern that iodine intake may be declining in certain populations.
The apparent paradox of iodine, how can the same substance be a vital nutrient, a powerful germ-killer, and a potential poison, can be explained by the foundational principle of toxicology: “the dose makes the poison.”
Nearly every substance known to science is harmful at some dose and beneficial or neutral at another. Water, oxygen, and vitamins A and D can all be lethal in large enough amounts.
In the bloodstream and thyroid gland, iodine exists primarily as iodide ions, a relatively mild, chemically stable form that the body actively transports, stores, and incorporates into hormone molecules in tightly regulated amounts.
The body requires only about 150 micrograms of iodine per day for an adult, an amount so small it would be virtually invisible to the naked eye.
Elemental iodine, the dark, crystalline form, is a different matter. In this form, iodine is highly reactive. When applied to a wound or a contaminated water supply, that reactivity is an asset. It kills pathogens indiscriminately and quickly.
But when ingested in significant quantities, elemental iodine exerts that same chemical effect on the tissues of the human body. It can irritate and burn the mouth, throat, esophagus, and stomach.
Iodine is a reminder that some of the most important forces in our lives are the ones we never notice. It is invisible in our food, required only in the tiniest amounts, yet its absence can affect entire populations, and its presence in fortified table salt has quietly improved the health of millions.
It is proof that sometimes, the smallest thing can have the biggest impact.
The Executive Producer of Everything Everywhere Daily is Charles Daniel. The Associate Producers are Austin Oetken and Cameron Kieffer.
I have a small correction that many of you have pointed out. In the previous show on the decision to drop the atomic bomb, I erroneously said that the bomb used on Hiroshima was dropped on January 6, when it was obviously August 6.
August was clearly in the script, and I have no idea how January came out of my mouth, but it did.
Today’s review comes from listener Jack3Pea from Apple Podcasts in the United Kingdom. They write:
Greetings from the Original Washington
After months of binging, I’ve finally listened to every single episode and can proudly say I’ve joined the Completionist Club! I might even be the first listener from Washington, England, the original Washington, where George Washington’s ancestors came from.
Gary has a unique way of making every topic-whether it’s obscure history, random facts, or global events-accessible and genuinely entertaining. No filler, no nonsense, just great storytelling in bite- sized episodes that leave you smarter every day.
If you’re on the fence about subscribing, don’t be. This is hands down the best daily podcast out there. Thanks, Gary, for the effort you put into every show, and keep them coming. From across the pond, you’ve got a loyal fan in the UK! Cheers, Jack
Thanks, Jack! Always glad to see more members of the completionist club across the pond. Make sure to check out the Pan Haggerty and Newcastle Brown Ale available at your local clubhouse.
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