Iodine deficiency

Iodine deficiency is a lack of the trace element iodine, an essential nutrient in the diet. It may result in metabolic problems such as goiter, sometimes as an endemic goiter as well as cretinism due to untreated congenital hypothyroidism, which results in developmental delays and other health problems. Iodine deficiency is an important global health issue, especially for fertile and pregnant women. It is also a preventable cause of intellectual disability.

Iodine deficiency
SpecialtyEndocrinology

Iodine is an essential dietary mineral for neurodevelopment among offsprings and toddlers.[1] The thyroid hormones thyroxine and triiodothyronine contain iodine. In areas where there is little iodine in the diet, typically remote inland areas where no marine foods are eaten, iodine deficiency is common. It is also common in mountainous regions of the world where food is grown in iodine-poor soil.

Prevention includes adding small amounts of iodine to table salt, a product known as iodized salt. Iodine compounds have also been added to other foodstuffs, such as flour, water and milk, in areas of deficiency.[2] Seafood is also a well known source of iodine.[3]

In the U.S., the use of iodine has decreased over concerns of overdoses since mid-20th century, and the iodine antagonists bromine, perchlorate and fluoride have become more ubiquitous.[4] In particular, around 1980 the practice of using potassium iodate as dough conditioner in bread and baked goods was gradually replaced by the use of other conditioning agents[5] such as bromide.

Iodine deficiency resulting in goiter occurs in 187 million people globally as of 2010 (2.7% of the population).[6] It resulted in 2700 deaths in 2013 up from 2100 deaths in 1990.[7]

Signs and symptoms

Goiter

A low amount of thyroxine (one of the two thyroid hormones) in the blood, due to lack of dietary iodine to make it, gives rise to high levels of thyroid stimulating hormone (TSH), which stimulates the thyroid gland to increase many biochemical processes; the cellular growth and proliferation can result in the characteristic swelling or hyperplasia of the thyroid gland, or goiter. In mild iodine deficiency, levels of triiodiothyronine (T3) may be elevated in the presence of low levels of levothyroxine, as the body converts more of the levothyroxine to triiodothyronine as a compensation. Some such patients may have a goiter, without an elevated TSH. The introduction of iodized salt since the early 1900s has eliminated this condition in many affluent countries; however, in Australia, New Zealand, and several European countries, iodine deficiency is a significant public health problem.[8] It is more common in developing countries. Public health initiatives to lower the risk of cardiovascular disease have resulted in lower discretionary salt use at the table. Additionally, there is a trend towards consuming more processed foods in western countries. The noniodized salt used in these foods means that people are less likely to obtain iodine from adding salt during cooking.

Goiter is said to be endemic when the prevalence in a population is > 5%, and in most cases goiter can be treated with iodine supplementation. If goiter is untreated for around five years, however, iodine supplementation or thyroxine treatment may not reduce the size of the thyroid gland because the thyroid is permanently damaged.

Congenital iodine deficiency syndrome

Congenital iodine deficiency syndrome, previously known as cretinism, is a condition associated with iodine deficiency and goiter, commonly characterised by mental deficiency, deafness, squint, disorders of stance and gait and stunted growth due to hypothyroidism. Paracelsus was the first to point out the relation between goitrous parents and their mentally disabled children.[9]

As a result of restricted diet, isolation, intermarriage, etc., as well as low iodine content in their food, children often had peculiar stunted bodies and retarded mental faculties, a condition later known to be associated with thyroid hormone deficiency. Diderot, in his 1754 Encyclopédie, described these patients as "crétins". In French, the term "crétin des Alpes" also became current, since the condition was observed in remote valleys of the Alps in particular. The word cretin appeared in English in 1779.

While reporting recent progress towards overcoming iodine-deficiency disorders worldwide, The Lancet noted: "According to World Health Organization, in 2007, nearly 2 billion individuals had insufficient iodine intake, a third being of school age." A conclusion was made that the single most preventable cause of intellectual disability is that of iodine deficiency.[10]

Fibrocystic breast changes

There is preliminary evidence that iodine deficiency enhances the sensitivity of breast tissue to estrogen.[11][12] In rats treated with estradiol, iodine deficiency has been shown to lead to changes similar to benign breast changes that are reversible by increased iodine in the diet.[11][12] In a few studies, iodine supplementation had beneficial effects (such as reducing the presence of breast cyst, fibrous tissue plaques and breast pain) in women with fibrocystic breast changes.[11][13]

Protective effects of iodine on breast cancer have been postulated from epidemiologic evidence and described in animal models.[14][15][16] In view of the antiproliferative properties of iodine in breast tissue, molecular iodine supplementation has been suggested as an adjuvant in breast cancer therapy.[16]

Risk factors

Following is a list of potential risk factors that may lead to iodine deficiency:[17]

  1. Low dietary iodine
  2. Selenium deficiency
  3. Pregnancy
  4. Exposure to radiation
  5. Increased intake/plasma levels of goitrogens, such as calcium
  6. Sex (higher occurrence in women)
  7. Smoking tobacco
  8. Alcohol (reduced prevalence in users)
  9. Oral contraceptives (reduced prevalence in users)
  10. Perchlorates
  11. Thiocyanates
  12. Age (for different types of iodine deficiency at different ages)

Pathophysiology

Iodine accounts for 65% of the molecular weight of T4 and 59% of the T3. There is a total of 15–20 mg of iodine in the human body which is primarily concentrated in thyroid tissue and hormones, but 30% of iodine is distributed in other tissues, including mammary glands, eyes, gastric mucosa, choroid plexus, arterial walls, the cervix, and salivary glands. In the cells of these tissues, iodide enters directly by sodium-iodide symporter (NIS).

  • Venturi S, Guidi A, Venturi M (1996). "[Extrathyroid iodine deficiency disorders: what is the real iodine requirement?]"". Le Basi Razionali della Terapia. 16: 267–275.
  • Pellerin P (1961). "La tecnique d'autoradiographie anatomique a la temperature de l'azote liquide". Path Biol. 232 (9): 233–252.

Diagnosis

Sequence of 123-iodide human scintiscans after an intravenous injection, (from left) after 30 minutes, 20 hours, and 48 hours. A high and rapid concentration of radio-iodide is evident in the periencephalic and cerebrospinal fluid (left), salivary glands, oral mucosa and the stomach. In the thyroid gland, I-concentration is more progressive, also in the reservoir (from 1% after 30 minutes, to 5.8% after 48 hours, of the total injected dose.[18]

The diagnostic workup of a suspected iodine deficiency includes signs and symptoms as well as possible risk factors mentioned above. A 24-hour urine iodine collection is a useful medical test, as approximately 90% of ingested iodine is excreted in the urine.[19] For the standardized 24-hour test, a 50 mg iodine load is given first, and 90% of this load is expected to be recovered in the urine of the following 24 hours. Recovery of less than 90% is taken to mean high retention, that is, iodine deficiency. The recovery may, however, be well less than 90% during pregnancy, and an intake of goitrogens can alter the test results.[20]

If a 24-hour urine collection is not practical, a random urine iodine-to-creatinine ratio can alternatively be used.[19] However, the 24-hour test is found to be more reliable.[21]

A general idea of whether a deficiency exists can be determined through a functional iodine test in the form of an iodine skin test. In this test, the skin is painted with an iodine solution: if the iodine patch disappears quickly, this is taken as a sign of iodine deficiency. However, no accepted norms exist on the expected time interval for the patch to disappear, and in persons with dark skin color the disappeance of the patch may be difficult to assess. If a urine test is taken shortly after, the results may be altered due to the iodine absorbed previously in a skin test.[20]

Treatment

Iodine supplements

Iodine deficiency is treated by ingestion of iodine salts, such as found in food supplements. Mild cases may be treated by using iodized salt in daily food consumption, or drinking more milk, or eating egg yolks, and saltwater fish. For a salt and/or animal product restricted diet, sea vegetables (kelp, hijiki, dulse, nori (found in sushi)) may be incorporated regularly into a diet as a good source of iodine.[19]

The recommended daily intake of iodine for adult women is 150–300 µg for maintenance of normal thyroid function; for men it is somewhat less at 150 µg.[19]

However, too high iodine intake, for example due to overdosage of iodine supplements, can have toxic side effects. It can lead to hyperthyroidism and consequently high blood levels of thyroid hormones (hyperthyroxinemia). In case of extremely high single-dose iodine intake, typically a short-term suppression of thyroid function (Wolff–Chaikoff effect) occurs.[22] Persons with pre-existing thyroid disease, elderly persons, fetuses and neonates, and patients with other risk factors are at a higher risk of experiencing iodine-induced thyroid abnormalities.[23] In particular, in persons with goiter due to iodine deficiency or with altered thyroid function, a form of hyperthyroidism called Jod-Basedow phenomenon can be triggered even at small or single iodine dosages, for example as a side effect of administration of iodine-containing contrast agents. In some cases, excessive iodine contributes to a risk of autoimmune thyroid diseases (Hashimoto's thyroiditis[24] and Graves' disease[25]).

Prognosis

With iodine supplementation, goiters caused by iodine deficiency decrease in size in very young children and pregnant women. Generally, however, long-standing goiters caused by iodine deficiency respond with only small amounts of shrinkage after iodine supplementation, and patients are at risk for developing hyperthyroidism.[19] Following the adoption of iodised salt in the United States in 1924, there was a gradual increase in average intelligence of 1 standard deviation, 15 points in iodine-deficient areas, 3.5 points nationally, but also an increase in deaths of older people in iodine-deficient areas due to hyperthyroidism.[26]

Epidemiology

Deaths due to iodine deficiency per million persons in 2012
  0-0
  1-1
  2-3
  4-18
Disability-adjusted life year for iodine deficiency per 100,000 inhabitants in 2004.[27]
  no data
  <50
  50-100
  100-150
  150-200
  200-250
  250-300
  300-350
  350-400
  400-450
  450-500
  500-750
  >750

Iodine deficiency resulting in goiter occurs 187 million people globally as of 2010 (2.7% of the population).[6] Certain areas of the world, due to natural deficiency and unavailability of iodine, are severely affected by iodine deficiency, which affects approximately two billion people worldwide. It is particularly common in the Western Pacific, South-East Asia and Africa. Among other nations affected by iodine deficiency, China and Kazakhstan have begun taking action, while Russia has not. Successful campaigns for the adoption of the use of iodized salt require education of salt producers and sellers and a communication campaign directed at the public. The cost of adding iodine to salt is negligible—"Only a few cents a ton."[28]

Iodine deficiency has largely been confined to the developing world for several generations, but reductions in salt consumption and changes in dairy processing practices eliminating the use of iodine-based disinfectants have led to increasing prevalence of the condition in Australia and New Zealand in recent years. A proposal to mandate the use of iodized salt in most commercial breadmaking was adopted there in October, 2009.[29] In a study of the United Kingdom published in 2011, almost 70% of test subjects were found to be iodine deficient.[30] The study's authors suggested an investigation regarding "evidence-based recommendations for iodine supplementation".[30]

It is well known that micronutrient deficiencies change the development of intelligence and iodine is no exception. Lacking in iodine during human development causes a fall, in average, of 12 IQ points in China.[31]

Scientists James Feyrer, Dimitra Politi, and David N. Weil have found in the U.S. that the proliferation of iodized salt increased IQ by 15 points in some areas. Journalist Max Nisen has stated that, with this type of salt becoming popular, that "the aggregate effect has been extremely positive."[32]

In iodine deficient or mildly iodine deficient areas in Europe, iodine deficiency is frequent during pregnancy despite the widespread use of iodised salt, posing risks to the neurodevelopment of foetuses.[33] In one study performed in a midly iodine-deficient area, iodine deficiency was found to be present in more than half of breastfeeding women; in contrast, the majority of their newborns had iodine excess, mostly due to neonatal exposure to iodine-containing disinfectants.[34] A 2014 meta-analysis found that iodine supplementation "improves some maternal thyroid indices and may benefit aspects of cognitive function in school-age children, even in marginally iodine-deficient areas."[35]

Deficient populations

In areas where there is little iodine in the diet, typically remote inland areas and semi-arid equatorial climates where no marine foods are eaten, iodine deficiency gives rise to hypothyroidism, symptoms of which are extreme fatigue, goiter, mental slowing, depression, weight gain, and low basal body temperatures.[36]

Iodine deficiency is the leading cause of preventable mental retardation, a result which occurs primarily when babies or small children are rendered hypothyroidic by a lack of the element. The addition of iodine to table salt has largely eliminated this problem in the wealthier nations, but as of March 2006, iodine deficiency remained a serious public health problem in the developing world.[37]

Iodine deficiency is also a problem in certain areas of Europe. In Germany it has been estimated to cause a billion dollars in health care costs per year.[13] A modelling analysis suggests universal iodine supplementation for pregnant women in England may save £199 (2013 UK pounds) to the health service per pregnant woman and save £4476 per pregnant woman in societal costs.[38]

Iodine deficiency was previously a common disease in Norway, because the content of iodine in the drinking water was low. Before 1950 goiter was a widespread disease caused by iodine deficiency.[39] Up to 80 per cent of the population were affected in inland areas. In the coastal communities, saltwater fish were an important part of the diet, and because of the sufficient amount of iodine in the sea, goiter did not occur so often as in the inland districts. From the 1950s, Norwegians started adding Iodine in the food to the dairy cows. Iodine is easily transferred to cow`s milk, since milk was an essential part of the Norwegian diet the incidence of goiter decreased in the population[39]

Since the 1990s the milk consumption has dropped. Data collections from the national dietary survey Nordkost 3 (Datacollcection from 2010-2011 among men and women from age 18-70) milk and milk products contributed an average of 37 per cent and seafood by 22 per cent.[39] The data among adults explained that men on average have an approximately adequate iodine intake while women appear to have too low iodine intake, one of the reasons is probably due to a large spread in fish intake and dairy products and most of the women did not take iodine supplements.[39]

In many countries around the world, iodized salt is the primary source of iodine, but it does not include Norway. In Norway, it is only permitted to enrich salt with five milligrams per kilogram, so the iodified salt in Norway is an insignificant source to iodine.[40] Approximately 60-80 per cent of the iodine intake in Norway comes from milk and dairy products, white(lean) fish and seafood is also an excellent source to iodine in the Norwegian diet.[40]

According to the Norwegian recommendations,[41] the iodine intake should be between 50-150 micrograms(μg) per day depending on the age, maternal iodine intake is estimated to 175-200 μg per day. The World Health Organization (WHO) recommendations are 250 μg iodine per day. The Norwegian directorate of health recommends at least two of three daily servings of dairy products should be from milk. Fish and fish products should be included two to three times per week.[39] Only white saltwater fish such as cod, saithe and haddock is excellent sources to Iodine. For people with allergies, vegetarians and others The Norwegian directorate of health recommends supplements with 100-150 μg iodine per day.[39]

Suboptimal iodine intake in Norways is still a national challenge. To prevent iodine deficiancy, further public interventions must be implemented internationally, in addition to providing information to the food industry, health care professionals and the general population to prevent the negative consequences of low iodine status among mothers and children.

Research

In view of large-scale epidemiological studies of iodine levels in populations, a method of capillary electrophoresis with UV detection of iodine has been proposed.[42]

See also

  • Basil Hetzel
  • Lugol's iodine
  • International Council for the Control of Iodine Deficiency Disorders

References

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  4. Meletis, C. D. (2011). "Iodine: Health Implications of Deficiency". Journal of Evidence-Based Complementary & Alternative Medicine. 16 (3): 190–194. doi:10.1177/2156587211414424. ISSN 1533-2101.
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  23. Leung, Angela M.; Braverman, Lewis E. (2013). "Consequences of excess iodine". Nature Reviews Endocrinology. 10 (3): 136–142. doi:10.1038/nrendo.2013.251. ISSN 1759-5029. PMC 3976240. PMID 24342882.
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  35. Taylor PN, Okosieme OE, Dayan CM, Lazarus JH (January 2014). "Therapy of endocrine disease: Impact of iodine supplementation in mild-to-moderate iodine deficiency: systematic review and meta-analysis". European Journal of Endocrinology (review). 170 (1): R1–R15. doi:10.1530/EJE-13-0651. PMID 24088547.
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  38. Monahan, Mark; Boelaert, Kristien; Jolly, Kate; Chan, Shiao; Barton, Pelham; Roberts, Tracy E (2015-01-01). "Costs and benefits of iodine supplementation for pregnant women in a mildly to moderately iodine-deficient population: a modelling analysis" (PDF). The Lancet Diabetes & Endocrinology. 3 (9): 715–722. doi:10.1016/s2213-8587(15)00212-0. PMID 26268911.
  39. "Fakta om jod" [Facts about iodine]. Folkehelseinstituttet (in Norwegian). Retrieved 2018-07-11.
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  41. "Anbefalinger om kosthold ernæring og fysisk aktivitet" (PDF). 2014.
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Further reading

  • Kotwal A, Priya R, Qadeer I (2007). "Goiter and other iodine deficiency disorders: A systematic review of epidemiological studies to deconstruct the complex web". Arch. Med. Res. 38 (1): 1–14. doi:10.1016/j.arcmed.2006.08.006. PMID 17174717.
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