Soils and Iodine Deficiency

  • Ron FugeEmail author


Iodine has long been known as an essential element for humans, and mammals in general, where it is concentrated in the thyroid gland. It is a component of the thyroid hormone thyroxine. Deprivation of iodine results in a series of iodine deficiency disorders (IDD), the most obvious of which is endemic goiter, a condition where the thyroid gland becomes enlarged in an attempt to be more efficient. Iodine deficiency during fetal development and in the first year of life can result in endemic cretinism, a disease which causes stunted growth and general development along with brain damage. However, while these two diseases are easily recognizable, perhaps the more insidious problem is that iodine deficiency impairs brain development in children even when there is no obvious physical effect. Many researchers have suggested that a relatively low degree of iodine deficiency during fetal development can result in a significant reduction of IQ in children. Indeed it has been suggested that iodine deficiency is the most common preventable cause of mental retardation (see Chaps. 8 and 9, this volume). For a detailed discussion of the problems resulting from iodine deficiency in humans the reader is referred to the many publications on the topic by Basil Hetzel (e.g. Hetzel 1987, 2001; Hetzel et al. 1990)


Iodine Deficiency Methyl Iodide Radioactive Iodine Iodine Content Endemic Goiter 
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Further Reading

  1. Al-Ajely KO (1985) Biogeochemical prospecting as an effective tool in the search for mineral deposits. Ph.D. thesis, University of Wales, AberystwythGoogle Scholar
  2. Amachi S, Fujii T, Shinoyama H, Muramatsu Y (2005) Microbial influences on the mobility and transformation of radioactive iodine in the environment. J Nucl Radiochem Sci 6:21–24Google Scholar
  3. Andersen S, Pedersen KM, Iversen F, Terpling S, Gustenhoff P, Petersen SB, Laurberg P (2008) Naturally occurring iodine in humic substances in drinking water in Denmark is bioavailable and determines population iodine intake. Br J Nutr 99:319–325Google Scholar
  4. Boussingault JB (1831) Recherches sur la cause qui produit le Goitre dans les Cordileres de la Novelle-Grenade. Ann Chim (Phys) 48:41–69Google Scholar
  5. Bowen HJM (1979) Environmental chemistry of the elements. Academic, LondonGoogle Scholar
  6. Cárdenas Quintana H, Gómez Bravo C, Pretell EA (2003) Iodine content of cattle milk from mountain and coast from Perú. Arch Latinoam Nutr 53:408–412 (in Spanish)Google Scholar
  7. Chameides WC, Davis DD (1980) Iodine: its possible role in tropospheric photochemistry. J Geophys Res 85:7383–7398CrossRefGoogle Scholar
  8. Councell TB, Landa ER, Lovley DR (1997) Microbial reduction of iodate. Water Air Soil Pollut 100:99–106CrossRefGoogle Scholar
  9. Davidsson L (1999) Are vegetarians an “at risk group” to iodine deficiency? Br J Nutr 81:3–4Google Scholar
  10. Dean GA (1963) The iodine content of some New Zealand drinking waters with a note on the contribution of sea spray to the iodine in rain. N Z J Sci 6:208–214Google Scholar
  11. Dissanayake CB, Chandrajith RLR (1996) Iodine in the environment and endemic Goitre in Sri Lanka. In: Appleton JD, Fuge R, McCall GJH (eds) Environmental geochemistry and health. Geological Society Special Publication, London 113: 201–211Google Scholar
  12. Duce RA, Zoller WH, Moyers JL (1973) Particulate and gaseous halogens in the Antarctic atmosphere. J Geophys Res 78:7802–7811CrossRefGoogle Scholar
  13. Dunn JT, van der Haar F (1990) A practical guide to the correction of iodine deficiency. International Council for the Control of Iodine Deficiency Disorders technical manual no. 3, The NetherlandsGoogle Scholar
  14. Fordyce FM, Stewart AG, Ge X, Jiang J-Y, Cave M (2003) Environmental controls in IDD: a case study in the Xinjiang Province of China, Technical report, CR/01/045N. British Geological Survey, NottinghamGoogle Scholar
  15. Fuge R (1987) Iodine in the environment: its distribution and relationship to human health. Trace Subst Environ Health 21:74–87Google Scholar
  16. Fuge R (1988) Sources of halogens in the environment, influences on human and animal health. Environ Geochem Health 10:51–61CrossRefGoogle Scholar
  17. Fuge R (1996) Geochemistry of iodine in relation to iodine deficiency diseases. In: Appleton JD, Fuge R, McCall GJH (eds) Environmental geochemistry and health. Geological Society Special Publication 113: 201–211Google Scholar
  18. Fuge R, Ander L (1998) Geochemical barriers and the distribution of iodine in the secondary environment: implications for radio-iodine. In: Nicholson K (ed) Energy and the environment: geochemistry of fossil, nuclear and renewable resources. MacGregor Science, Insch, pp 163–170Google Scholar
  19. Fuge R, Johnson CC (1986) The geochemistry of iodine-a review. Environ Geochem Health 8:31–54CrossRefGoogle Scholar
  20. Gabler HE, Heumann KG (1993) Determination of iodine species using a system of specifically prepared filters and IDMS. Fresnius J Anal Chem 345:53–59CrossRefGoogle Scholar
  21. Gaitan E, Cooksey RC, Legan J, Cruse JM, Lindsay RH, Hill J (1993) Antithyroid and goitrogenic effects of coal-water extracts from iodine-sufficient areas. Thyroid 3:49–53CrossRefGoogle Scholar
  22. Garland JA, Curtis H (1981) Emission of iodine from the sea surface in the presence of ozone. J Geophys Res 86:3183–3186CrossRefGoogle Scholar
  23. Gerzabek MH, Muramatsu Y, Strebl F, Yoshida S (1999) Iodine and bromine contents of some Austrian soils and relations to soil characteristics. J Plant Nutr Soil Sci 162:415–419CrossRefGoogle Scholar
  24. Goldschmidt VM (1954) Geochemistry. Oxford University Press, LondonGoogle Scholar
  25. Hetzel BS (1987) The biological effects of iodine deficiency and their public health significance. Neuro Toxicol 8:363–368Google Scholar
  26. Hetzel BS (2001) Iodine deficiency and the brain. Nutr Neurosci 2:375–384Google Scholar
  27. Hetzel BS, Potter BJ, Dullberg EM (1990) The iodine deficiency disorders, nature, pathogenesis and epidemiology. In: Bourne G (ed) World review of nutrition and dietetics, vol 62. Karger, Basel, pp 59–119Google Scholar
  28. Heumann KG, Gall M, Weiss H (1987) Geochemical investigations to explain iodine-overabundances in Antarctic meteorites. Geochim Cosmochim Acta 51:2541–2547CrossRefGoogle Scholar
  29. Heumann KG, Neubauer J, Reifenhauser H (1990) Iodine overabundances measured in the surface layers of an Antarctic stony and iron meteorite. Geochim Cosmochim Acta 54:2503–2506CrossRefGoogle Scholar
  30. Hou X, Hansen V, Aldahan A, Possnert G, Lind OC, Lujaniene G (2009) A review on speciation of iodine-129 in the environmental and biological samples. Anal Chim Acta 632:181–196CrossRefGoogle Scholar
  31. Hu QH, Moran JE, Gan JY (2012) Sorption, degradation, and transport of methyl iodide and other iodine species in geologic media. Appl Geochem 27:774–781CrossRefGoogle Scholar
  32. IAEA (1994) Handbook of parameter values for the prediction of radionuclide transfer in temperate environments, Technical report series, no. 364. International Atomic Energy Authority, ViennaGoogle Scholar
  33. Johnson CC (1980) The geochemistry of iodine and a preliminary investigation into its potential use as a pathfinder element in geochemical exploration. Ph.D. thesis, University of Wales, AberystwythGoogle Scholar
  34. Johnson CC, Strutt MH, Hmeurras M, Mounir (2002) Iodine in the environment of the high Atlas Mountains, Morocco. British Geological Survey Commissioned report CR/02/196N, NottinghamGoogle Scholar
  35. Kelly FC, Sneddon FW (1960) Prevalence and geographical distribution of endemic goitre. In: Endemic goitre. World Health Organization, Geneva, pp 27–233Google Scholar
  36. Kocher DC (1981) A dynamic model of the global iodine cycle and estimation of dose to the world population from release of I-129 to the environment. Environ Int 5:15–31CrossRefGoogle Scholar
  37. Krajcovicová-Kudlácková M, Bucková K, Klimes I, Seboková E (2003) Iodine deficiency in vegetarians and vegans. Ann Nutr Metab 47(5):183–185CrossRefGoogle Scholar
  38. Låg J, Steinnes E (1976) Regional distribution of halogens in Norwegian forest soils. Geoderma 16:317–325CrossRefGoogle Scholar
  39. Langer P (1960) History of goitre. In: Endemic goitre. World Health Organization, Geneva, pp 9–25Google Scholar
  40. Li M, Waite KV, Ma G, Eastman CJ (2006) Declining iodine content in milk and re-emergence of iodine deficiency in Australia. Med J Aust 184(6):307Google Scholar
  41. Lidiard HM (1995) Iodine in reclaimed upland soil of a farm in the Exmoor National Park, Devon, U.K., and its impact on livestock health. Appl Geochem 10:85–95CrossRefGoogle Scholar
  42. Lovelock JE, Maggs RJ, Wade RJ (1973) Halogenated hydrocarbons in and over the Atlantic. Nature 241:194–196CrossRefGoogle Scholar
  43. Moison TA, Dunstan WM, Udomkit A, Wong GTF (1994) The uptake of iodate by marine phytoplankton. J Phycol 30:580–587CrossRefGoogle Scholar
  44. Moore RM, Groszko W (1999) Methyl iodide distribution in the ocean and fluxes to the atmosphere. J Geophys Res 104:11163–11171CrossRefGoogle Scholar
  45. Muramatsu Y, Wedepohl KH (1998) The distribution of iodine in the earth’s crust. Chem Geol 147:201–216CrossRefGoogle Scholar
  46. Muramatsu Y, Yoshida S (1999) Effects of microorganisms on the fate of iodine in the soil environment. Geomicrobiol J 16:85–93CrossRefGoogle Scholar
  47. Muramatsu Y, Uchida S, Ohmomo Y (1993) Root-uptake of radioiodine by rice plants. J Radiat Res 34:214–220CrossRefGoogle Scholar
  48. Muramatsu Y, Yoshida S, Uchida S, Hasebe A (1996) Iodine desorption from rice paddy soil. Water Air Soil Pollut 86:359–371CrossRefGoogle Scholar
  49. Ng YC (1982) A review of transfer factors for assessing the dose from radionuclides in agricultural products. Nucl Saf 23:57–71Google Scholar
  50. Nordic Project Group (1995) Risk evaluation of essential trace elements–essential versus toxic levels of intake. Nordic Council of Ministers, Nord, Copenhagen, pp 18Google Scholar
  51. Perel’man AJ (1977) Geochemistry of elements in the supergene zone. Keterpress Enterprises, JerusalemGoogle Scholar
  52. Prister BS, Grigor’eva TA, Perevezentsev VM, Tikhomirov FA, Sal’nikov VG, Ternovskaya IM, Karabin T (1977) Behaviour of iodine in soils. Pochvovedenie 6:32–40 (in Russian)Google Scholar
  53. Rahn KA, Borys RD, Duce RA (1976) Tropospheric jalogen gases: inorganic and organic components. Science 192:549–550CrossRefGoogle Scholar
  54. Remer T, Neubert A, Manz F (1999) Increased risk of iodine deficiency with vegetarian nutrition. Br J Nutr 81:45–49Google Scholar
  55. Schmitz K, Aumann DC (1994) Why are the soil-to-pasture transfer factors, as determined by field-measurements for I-127 lower than for I-129. J Environ Radioact 24:91–100CrossRefGoogle Scholar
  56. Shacklette HJ, Boerngen JG (1984) Element concentrations in soils and other surficial materials of the conterminous United States, United States Geological Survey professional paper 1270. Denver, COGoogle Scholar
  57. Sheppard SC, Evenden WG (1995) Toxicity of soil iodine to terrestrial biota with implications for I-129. J Environ Radioact 27:99–116CrossRefGoogle Scholar
  58. Shimamoto YS, Takahashi Y, Terada Y (2011) Formation of organic iodine supplied as iodide in a soil-water system in Chiba, Japan. Environ Sci Technol 45:2086–2092CrossRefGoogle Scholar
  59. Takagi H, Iijima I, Iwashima K (1994) Determination of iodine with chemical forms in rain water with fractional sampling NAA. Bunseki Kagaku 43:905–909CrossRefGoogle Scholar
  60. Tan J (ed) (1989) The atlas of endemic diseases and their environments in the People’s Republic of China. Science Press, BeijingGoogle Scholar
  61. Tsukada H, Takeda A, Tagami K, Uchida S (2008) Uptake and distribution of iodine in rice plants. J Environ Qual 37:2243–2247CrossRefGoogle Scholar
  62. Vanderpas JB, Contempre B, Duale NL, Gossans W, Bebe NGO (1990) Iodine and selenium deficiency associated with cretinism in Northern Zaire. Am J Clin Nutr 52:1087–1093Google Scholar
  63. Vinogradov AP (1959) The geochemistry of rare and dispersed chemical elements in soils, 2nd edn. Consultants Bureau, New YorkGoogle Scholar
  64. Vinogradov AP, Lapp MA (1971) Use of iodine haloes to search for concealed mineralisation. Vestn Leningr Univ Ser Geolog Geogr 24:70–76 (in Russian)Google Scholar
  65. Whitehead DC (1974) The sorption of iodide by soil components. J Sci Food Agric 25:461–470CrossRefGoogle Scholar
  66. Whitehead DC (1984) The distribution and transformation of iodine in the environment. Environ Int 10:321–339CrossRefGoogle Scholar
  67. Wong GTF (1991) The marine geochemistry of iodine. Rev Aquat Sci 4:45–73Google Scholar
  68. Wong GTF, Cheng XH (1998) Dissolved organic iodine in marine waters: determination, occurrence and analytical implications. Mar Chem 59:271–281CrossRefGoogle Scholar
  69. Yamaguchi N, Nakano M, Takamatsu R, Tanida H (2010) Inorganic iodine incorporation into soil organic matter: evidence from iodine K-edge structure. J Environ Radioact 101:451–457CrossRefGoogle Scholar
  70. Yoshida S, Muramatsu Y (1995) Determination of organic, inorganic, and particulate iodine in the coastal atmosphere of Japan. J Radioanal Nucl Chem Artic 196:295–302CrossRefGoogle Scholar
  71. Yuita K (1994a) Overview and dynamics of iodine and bromine in the environment. 1. Dynamics of iodine and bromine in soil-plant system. Jpn Agric Res Q 28:90–99Google Scholar
  72. Yuita K (1994b) Overview and dynamics of iodine and bromine in the environment. 2. Iodine and bromine toxicity and environmental hazards. Jpn Agric Res Q 28:100–111Google Scholar
  73. Yuita K, Tanaka T, Abe C, Aso S (1991) Dynamics of iodine, bromine and chlorine in soil. 1. Effects of moisture, temperature and pH on the dissolution of the triad from soil. Soil Sci Plant Nutr 37:61–73CrossRefGoogle Scholar
  74. Zafiriou OC (1974) Photochemistry of halogens in the marine atmosphere. J Geophys Res 79:2730–2732CrossRefGoogle Scholar
  75. Zimmermann MB (2010) Symposium on ‘geographical and geological influences on nutrition’ iodine deficiency in industrialised countries. Proc Nutr Soc 69:133–143CrossRefGoogle Scholar

Copyright information

© Springer Science+Business Media Dordrecht 2013

Authors and Affiliations

  1. 1.Institute of Geography and Earth SciencesAberystwyth UniversityAberystwythUK

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