Skip directly to search Skip directly to A to Z list Skip directly to navigation Skip directly to page options Skip directly to site content

Trace Elements: Selenium

Background

Selenium is a trace mineral essential to good health. The major dietary source of selenium is plant foods. Selenium concentrations in plants generally reflect the concentration of selenium in soils, but some meats and seafood can also contribute dietary selenium; in the United States, meats and bread are common sources. Depending on foodstuff origin, variation in its selenium content can be between 11- and 72-fold; thus, predicting dietary intake by relying on estimates from nutrient databases is difficult (Keck 2006).

Selenium functions through selenoproteins, several of which are oxidant-defense enzymes. For example, the selenium-dependent glutathione peroxidase defends the body against oxidative stress. Other selenium-associated proteins regulate the action of thyroid hormones and the oxidation-reduction status of vitamin C and other molecules (Institute of Medicine 2000). Most selenium in animal tissues is present as selenomethionine or selenocysteine.

Selenium deficiency in the United States is rare, but it is seen in other countries, most notably in China, where the concentration of selenium in soil is low. In the United States, most cases of selenium depletion or deficiency are associated with severe gastrointestinal problems, such as Crohn's disease, or with the surgical removal of part of the stomach, and are therefore a result of impaired selenium absorption (Kuroki 2003; Rannem 1992; Bjerre 1989).

By itself, selenium deficiency does not usually cause illness. Rather, it can make the body more susceptible to illnesses caused by other nutritional, biochemical, or infectious stresses (Beck 2003). Three specific diseases have been associated with selenium deficiency. Keshan disease occurs only in selenium-deficient children and is associated with an enlarged heart and poor heart function. Kashin-Beck disease is a disorder of the bones and joints of the hands and fingers, elbows, knees, and ankles of children and adolescents. Lastly, myxedematous endemic cretinism, a condition that results in mental retardation, occurs in infants born to mothers deficient in both selenium and iodine (Institute of Medicine 2000).

Chemists review selenium data.

Evidence is limited as to whether intakes of selenium greater than the amount needed to allow full expression of selenoproteins may have chemopreventive effects against cancer. Controlled intervention studies are needed to adequately evaluate selenium as a cancer chemopreventive agent (Institute of Medicine 2000).

Blood concentrations of selenium greater than 1,000 nanograms per milliliter (ng/mL) (12.7 micromoles per liter [μmol/L]) can result in a condition known as selenosis (Koller 1986). Manifestations of selenosis include gastrointestinal upset, hair loss, white blotchy nails, garlic-breath odor, fatigue, irritability, and mild nerve damage (Goldhaber 2003).

The National Academy of Sciences has established an estimated average requirement (EAR) for selenium that is based on the amount needed to maximize plasma glutathione peroxidase activity and prevent Keshan disease. The EAR is the average daily nutrient intake level estimated to meet the requirement of half of the healthy individuals in a particular life stage and sex group. The EAR for selenium for boys and girls 9–13 years old or 14–18 years old is 35 and 45 micrograms (μg) daily, respectively. For healthy children aged 1–3 years or 4–8 years, the currently recommended EAR for selenium is 17 and 23 μg daily, respectively. These values are extrapolated from adult values (Institute of Medicine 2000).

A diagnosis of selenium deficiency is confirmed by measuring concentrations of selenium in serum or plasma. Values less than 70 ng/mL or 0.8 μmol/L suggest synthesis of selenium-associated proteins has not yet reached a plateau and that selenium supplies are limited (Institute of Medicine 2000).

More information on selenium is available online:

Using serum selenium concentrations measured in the U.S. population in NHANES III (1988–1994), it appears that the diets of most U.S. residents provide the recommended amounts of selenium (Niskar 2003). The mean and median serum selenium concentrations were 1.58 μmol/L and 1.56 μmol/L, respectively. Serum selenium concentrations differed by age, sex, race, ethnicity, poverty-income ratio, and geographic region. In NHANES 2001–2002, less than 3 percent of survey participants had a dietary intake of selenium below the EAR (Moshfegh 2005).

 Top of Page

Selected Observations and Highlights


The following example observations are taken from the tables of 1999-2000 data contained in this report. Only data for children were available for the NHANES survey period covered in this report. Statements about categorical differences between demographic groups noted below are based on non-overlapping confidence limits from univariate analysis without adjusting for demographic variables (i.e., age, sex, race/ethnicity) or other determinants of these blood concentrations (i.e., dietary intake, supplement usage, smoking, BMI). A multivariate analysis may alter the size and statistical significance of these categorical differences. Furthermore, additional significant differences of smaller magnitude may be present despite their lack of mention here (e.g., if confidence limits slightly overlap or if differences are not statistically significant before covariate adjustment has occurred). For a selection of citations of descriptive NHANES papers related to these biochemical indicators of diet and nutrition, see Appendix E.


General Observations

  • Younger children (aged 3–5 years) have lower serum selenium concentrations than do older children (aged 6–11 years).
  • At least 90 percent of 3–11 year-old children have adequate serum concentrations of selenium.


Highlights

The majority of U.S. children (> 90 percent) have adequate serum concentrations of selenium (≥ 70 ng/mL). No evidence has surfaced of excessive exposure to selenium (> 1,000 ng/mL) in U.S. children.

 Top of Page

Tables

Serum selenium

 Top of Page

References

Beck MA, Levander O, Handy J. Selenium deficiency and viral infection. J Nutr. 2003;133:1463S-67S.

Bjerre B, von Schenck H, Sorbo B. Hyposelaemia: patients with gastrointestinal diseases are at risk. J Intern Med. 1989;225:85-8.

Goldhaber SB. Trace element risk assessment: essentiality vs. toxicity. Regul Toxicol Pharmacol. 2003;38:232-42.

Institute of Medicine, Food and Nutrition Board. Dietary Reference Intakes: vitamin C, vitamin E, selenium, and carotenoids. Washington, D.C.: National Academy Press; 2000.

Keck A-S, Finley JW. Database values do not reflect selenium contents of grain, cereals, and other foods grown or purchased in the upper Midwest of the United States. Nutr Res. 2006;26:17-22.

Koller LD, Exon JH. The two faces of selenium-deficiency and toxicity are similar in animals and man. Can J Vet Res. 1986;50:297-306.

Kuroki F, Matsumoto T, Lida M. Selenium is depleted in Crohn's disease on enteral nutrition. Dig Dis. 2003;21:266-70.

Moshfegh A, Goldman J, Cleveland L. What we eat in America, NHANES 2001–2002: usual nutrient intakes from food compared to dietary reference intakes. Washington, D.C.: U.S. Food and Drug Administration; 2005 [cited 2008]. Available from: http://www.ars.usda.gov/SP2UserFiles/Place/12355000/pdf/usualintaketables2001-02.pdf.

Niskar AS, Paschal DC, Kieszak SM, Flegal KM, Bowman B, Gunter EW, et al. Serum selenium levels in the US population: Third National Health and Nutrition Examination Survey, 1988–1994. Biol Trace Elem Res. 2003;91:1-10.

Rannem T, Ladefoged K, Hylander E, Hegnhoj J, Jarnum S. Selenium status in patients with Crohn's disease. Am J Clin Nutr. 1992;56:933-7.

 Top of Page

Related Links

* Links to non-Federal organizations found at this site are provided solely as a service to our users. These links do not constitute an endorsement of these organizations or their programs by CDC or the Federal Government, and none should be inferred. CDC is not responsible for the content of the individual organization Web pages found at these links.

 Top of Page
  • Page last reviewed: July 30, 2008
  • Page last updated: July 30, 2008
  • Content source:
Top