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Vitamins, Fat-Soluble Ads by Google Vitamins - Answers to all your questions about Vitamins, Antioxidants and more! (www.ivillage.co.uk) Human Growth Hormone -HGH - Get Leaner, Build Muscle, Lose Fat Buy Two Get One Free! Visit Today (www.HumanGrowthHormone.com) Now Vitamins Discounted - Free Shipping w/$50 purchase Complete Inventory, Order now! (www.supervits.com) Because they dissolve in fat, vitamins A, D, E, and K are called fat-soluble vitamins. They are absorbed from the small intestines, along with dietary fat, which is why fat malabsorption resulting from various diseases (e.g., cystic fibrosis, ulcerative colitis, Crohn's disease) is associated with poor absorption of these vitamins. Fat-soluble vitamins are primarily stored in the liver and adipose tissues. With the exception of vitamin K, fat-soluble vitamins are generally excreted more slowly than water-soluble vitamins, and vitamins A and D can accumulate and cause toxic effects in the body. Vitamin A Vitamin A was the first fat-soluble vitamin identified (in 1913). Vitamin A comprises the preformed retinoids, plus the precursor forms, the provitamin A carotenoids. Preformed retinoids is a collective term for retinol, retinal, and retinoic acid, all of which are biologically active. The provitamin A carotenoids include beta-carotene and others, which are converted to retinoids with varying degrees of efficiency. Retinoids are sensitive to heat, light, and oxidation by air. Beta-carotene is relatively more stable. Vitamin E helps protect vitamin A from oxidation. There is some loss of vitamin A with cooking, but only after boiling for a comparatively long period. Retinoids are converted to retinol in the intestines and transported with dietary fat to the liver, where it is stored. A special transport protein, retinolbinding protein (RBP), transports vitamin A from the liver to other tissues. Carotenoids are absorbed intact at a much lower absorption rate than retinol. Of all the carotenoids, beta-carotene has the highest potential vitamin-A activity. The active forms of vitamin A have three basic functions: vision, growth and development of tissues, and immunity. Vision. Vitamin A combines with a protein called opsin to form rhodopsin in the rod cells of the retina. When vitamin A is inadequate, the lack of rhodopsin makes it difficult to see in dim light. Growth and development of tissues. Vitamin A is involved in normal cell differentiation—a process through which embryonic cells transform into mature tissue cells with highly specific functions. Vitamin A supports male and female reproductive processes and bone growth. Immunity. Vitamin A is essential for immune function and vitamin-A deficiency is associated with decreased resistance to infections. The severity of some infections, such as measles and diarrhea, is reduced by vitamin-A supplementation among those who suffer from vitamin-A deficiency. FAT SOLUBLE VITAMINS Vitamin Functions Deficiency symptoms People at risk Sources Daily recommended intakes Toxicity SOURCE Wardlaw, Gordon M.; Hampl, Jeffrey S.; and Disilvestro, Robert A. (2004). Perspectives in Nutrition, 6th edition. New York: McGraw-Hill. Vitamin A Preformed retinoids and provitamin A carotinoids Vision in dim light and color vision, cell differentiation and growth, immunity Poor growth, night blindness, blindness, dry skin, Xerophthalmia Rare in United States but common in preschool children living in poverty in Preformed vitamin A: liver, fortified milk, fish liver oils Provitamin A: red, orange, dark green, and Infants: 400-500 mg RAE Children: 300-400 mg RAE Adolescents: 600900 mg RAE Adult men & women: 700-900 mg RAE Headache, vomiting, double vision, hair loss, dry mucous membranes, Vitamin Functions Deficiency symptoms People at risk Sources Daily recommended intakes Toxicity developing countries, alcoholics Pregnant women: 750-770 mg RAE Lactating women:1200-1300 mg RAE bone and joint pain, fractures, liver damage, hemorrhage, coma, teratogenic effects: spontaneous abortions, birth defects. Upper level is 3000 mg of preformed vitamin A based on risk of birth defects and liver toxicity. yellow vegetables, orange fruits Vitamin D Maintainence Rickets in Cholecalciferol of children, Ergocalciferol intracellular osteomalacia and in older adults extracellular calcium concentrations Dark skinned Vitamin individuals, fortified older adults, fish oils breastfed infants from vitamin D deficient mother Vitamin E Antioxidant, Tocopherols prevention of Tocotrienols propagation of free radicals Patients with fat malabsorption syndromes, smokers [overt deficiency is rare] Plant oils, Infants: 4-5 mg seeds, nuts, Children: 6-7 mg products made Adolescents:11-15 from oils mg Adult men & women: 15 mg Pregnant women: 15 mg Lactating women: 19 mg Those taking antibiotics for a long period of time; older adults with scant green vegetable intake Green vegetables, liver synthesis by intestinal microorganisms Hemolysis of red blood cells, degeneration of sensory neurons Vitamin K Synthesis of Hemorrhage, Phylloquinone blood clotting fractures Menaquinone factors and bone proteins D 0-50 years: 5 mg Calcification milk, 51-70 years: 10 mg, of soft >70 years: 15 mg tissues, growth restriction, excess calcium excretion via the kidney. Upper level is 50 mg based on the risk elevated blood calcium. Inhibition of vitamin K metabolism. Upper level is 1000 mg based on the risk of hemorrhage. Infants: 2-2.5 mg No upper Children: 30-55 level has mg Adolescents: been set 60-75 mg Adult men: 90 mg Adult women: 120 mg Pregnant/lactating women: 75-90 mg It has been suggested that beta-carotene and other carotenoids (also called phytochemicals) may function as antioxidants by neutralizing free radicals. Free radicals are unstable, highly reactive molecules that damage DNA, cause cell injury, and increase the risk of chronic disease. Beta-carotene has also been associated with reducing the risk of lung cancer. Lutein and zeaxanthin, yellow carotenoid pigments in corn and dark green leafy vegetables, may reduce the risk of macular degeneration and agerelated cataracts. Lycopene, a red carotenoid pigment in tomatoes, may help reduce the risk of prostrate cancer, cardiovascular disease, and skin damage from sunlight. Deficiency. Dietary deficiency of vitamin A is rare in North America and western Europe, but it is the leading cause of blindness in children worldwide. Newborn and premature infants, the urban poor, older adults, people with alcoholism or liver disease, and those with fat malabsorption syndrome are all at increased risk. One of the earliest symptoms of vitamin-A deficiency is night blindness. It is a temporary condition, but if left untreated it can cause permanent blindness. This degeneration is called xerophthalmia, and it usually occurs in children after they are weaned. Symptoms include dryness of the cornea and eye membranes due to lack of mucus production, which leaves the eye vulnerable to surface dirt and bacterial infections. Vitamin-A deficiency can cause follicular hyperkeratosis, a condition in which hair follicles become plugged with keratin, giving a bumpy appearance and a rough, dry texture to skin. In developing countries, the severity of infectious diseases such as measles is often correlated to the degree of vitamin-A deficiency. Providing large doses of vitamin A reduces the risk of dying from these infections. The age range of the target population for vitamin-A intervention programs is usually from birth to seven years. Administration of high-potency doses in the range of 15,000 to 60,000 micrograms (μg) are distributed to young children in targeted areas of the world to build up liver stores for up to six months. However, consumption of adequate food sources is the most important long-term solution to vitamin-A deficiency. Toxicity. Vitamin-A toxicity, called hypervitaminosis A, can result from long-term supplementation of two to four times the RDA for preformed vitamin A. Excess intake of preformed vitamin A is a teratogen, meaning it can cause birth defects. Birth defects associated with vitamin-A toxicity include cleft palate, heart abnormalities, and brain malfunction. Acute excess intake during pregnancy can also cause spontaneous abortions. Pregnant women should avoid prenatal supplements containing retinal, as well as medications made from retinoids, such as Accutane and Retin-A. Prolonged and excessive consumption of carotene-rich foods can lead to hypercarotenemia, a clinical condition characterized by deep orange discoloration of the skin and increased carotene levels in the blood. This condition is usually harmless. Vitamin D (Calciferol) In the seventeenth century, vitamin-D deficiency was so common in British children that it came to be known as "children's disease of the English." In Sunlight stimulates the synthesis of vitamin D, which regulates the body's absorption of calcium and therefore is essential to skeletal health. Just fifteen minutes in the sun several times weekly is sufficient. After that, sunscreen should be applied to avoid ultraviolet damage to the skin. [Photograph by Michael Keller. Corbis. Reproduced by permission.] the mid-1800s, cod liver oil became well known for treating this disease. In 1925, Elmer McCollum and coworkers determined that the "antirachitic" (antirickets) substance in cod liver oil was vitamin D. Because vitamin D is relatively stable in foods, many countries fortify milk with vitamin D to help prevent rickets. However, significant losses may result from fortified milk exposed to light. Vitamin D from foods is absorbed from the upper part of the small intestine, along with dietary fat, and transported to the liver. In the skin, ultraviolet (UV) radiation from the sun converts a cholesterol derivative to cholecalciferol, which enters the blood stream and is transported to the liver. In the liver, vitamin D is converted to calcidiol, an inactive form that circulates in blood. Kidneys take up calcidiol and convert it to an active hormone form of vitamin D called calcitriol. People with chronic kidney failure have very low levels of calcitriol and must be routinely treated with this form of the vitamin. The best-known function of active vitamin D is to help regulate blood levels of calcium and phosphorous. Vitamin D increases absorption of these minerals from the gastrointestinal (GI) tract. In combination with parathyroid hormone, it enhances their reabsorption from the kidneys and their mobilization from bones into the blood. Vitamin D helps maintain calcium levels even if dietary intakes are not optimal. Calcitriol affects growth of normal cells and some cancer cells. Adequate vitamin-D status has been linked to a reduced risk of developing breast, colon, and prostrate cancers. Deficiency. Long-term deficiency of vitamin D affects the skeletal system. In children, vitamin-D deficiency leads to rickets, a condition in which bones weaken and bow under pressure. Although vitamin-D fortification has reduced incidence of rickets in North America, it is sometimes seen in children with malabsorption syndrome and is still common in many parts of the world. In adults, vitamin-D deficiency causes osteomalacia, or "soft bones," increasing the risk for fractures in hip, spine, and other bones. Vitamin-D deficiency also contributes to osteoporosis. In elderly persons, vitamin-D supplementation reduces the risk of osteoporotic fractures. Infants are born with stores of vitamin D that last about six months. Breast milk contains very little vitamin D, however, and infants beyond six months of age who are exclusively breastfed must obtain vitamin D via exposure to sunlight or a supplement given under the guidance of a physician. Older adults are especially at risk for vitamin-D deficiency for several reasons. The skin, liver, and kidneys lose their capacity to synthesize and activate vitamin D with advancing age, and older adults typically drink little or no milk, a major dietary source of vitamin D. Older adults also rarely venture outdoors, and when they do, they apply sunscreen to exposed areas of the body, further contributing to the decline in vitamin-D synthesis in the skin. Sunscreens with a sun protection factor (SPF) of 8 and above prevent vitamin-D synthesis. Sunscreen should be applied only after enough time has elapsed to provide sufficient vitamin-D synthesis. Exposure to the sun does not cause vitamin-D toxicity, and for most people, exposing the hands, face, and arms on a clear summer day for fifteen minutes a few times a week should provide sufficient Vitamin D. Dark-skinned people require longer sunlight exposure because melanin, a skin pigment, is a natural sunscreen. Dietary recommendations assume that no vitamin D is available from exposure to sunlight. Thus, people who do not venture outdoors or who live in northern or predominantly cloudy climates need to pay attention to dietary sources. Plants are poor sources of vitamin D, so strict vegetarians must meet their vitamin-D needs through exposure to sunlight, fortification, or supplementation. Toxicity. Vitamin D is most likely to have toxic effects when consumed in excessive amounts through supplementation. Excess vitamin D raises blood calcium levels, resulting in calcium precipitation in soft tissues and stone formation in the kidneys, where calcium becomes concentrated in an effort to excrete it. Vitamin K In 1929, the Danish researcher Henrik Dam first noted that vitamin K played a critical role in blood clotting, and he named it vitamin "K" for "Koagulation." Vitamin K comprises a family of compounds known as quinones. These include phylloquinone from plants and the menaquinones from animal sources. Phylloquinone is the most biologically active form. Menaquinones are also synthesized by bacteria in the colon and absorbed, contributing about 10 percent of total vitamin-K needs. Vitamin-K absorption depends on normal consumption and digestion of dietary fat. It is primarily stored in the liver. Vitamin K helps in the activation of seven blood-clotting-factor proteins that participate in a series of reactions to form a clot that eventually stops the flow of blood. Vitamin K also participates in the activation of bone proteins, which greatly enhances their calcium-binding properties. Low levels of circulating vitamin K have been associated with low bone-mineral density. Thus, an adequate intake of vitamin K may help protect against hip fractures. Deficiency. A primary deficiency of vitamin K is rare, but a secondary deficiency may result from fat malabsorption syndrome. Prolonged use of antibiotics can destroy the intestinal bacteria that produce vitamin K, precipitating deficiency in individuals at risk. Newborn infants are born with a sterile intestinal tract and those who are breastfed, may run the risk of vitamin-K deficiency, since breast-milk production takes a few days to establish and breast milk is naturally low in this vitamin. To prevent hemorrhaging, all infants in North America receive injections of vitamin K within six hours of birth. Toxicity. High doses of vitamin K can reduce the effectiveness of anticoagulant drugs such as warfarin (Coumadin), which is used to prevent blood clotting. People taking these drugs should maintain a consistent daily intake of vitamin K. Megadose supplements of vitamin A and E can pose a risk to vitamin-K status. Vitamin A interferes with absorption of vitamin K, and large doses of vitamin E decrease vitamin K–dependent clotting factors, thus promoting bleeding. Toxicity from food is rare, because the body excretes vitamin K much more rapidly than other fat-soluble vitamins. Vitamin E The link between vitamin-E deficiency and reproductive failure in rats was first discovered in 1922 by Herbert Evans and Katherine Scott Bishop. The chemical name of vitamin E, tocopherol, is derived from toco, meaning "related to childbirth." Vitamin E comprises a family of eight naturally occurring compounds: four tocopherols and four tocotrienols, of which alpha-tocopherol is the only one to have vitamin-E activity in the human body. It is also the most common form of vitamin E in food. Vitamin E is highly susceptible to destruction by oxygen, metals, light, and deep-fat frying. As a result, prolonged food storage lowers the vitamin-E content of food. As with other fat-soluble vitamins, absorption of vitamin E requires adequate absorption of dietary fat. In addition, the percentage of absorption declines as the amount consumed is increased. Vitamin E is stored mainly in adipose tissue, while some is stored in the muscle. The remaining vitamin E is found in cell membranes in tissue. Vitamin E is an antioxidant and one of the body's primary defenders against oxidative damage caused by free radicals. Its activity is enhanced by other antioxidants such as vitamin C and the mineral selenium. Vitamin E interrupts free-radical chain reactions by getting oxidized, thus protecting cell membranes from free-radical attack. Scientists have implicated oxidative stress in the development of cancer, arthritis, cataracts, heart disease, and in the process of aging itself. However, it is not yet known whether supplementation with megadoses of vitamin E offers protection against heart disease and cancer beyond that provided by positive dietary and lifestyle changes. Deficiency. Due to the widespread use of vegetable oils, primary vitamin-E deficiency is rare. Most deficiencies occur in people with fat malabsorption syndrome. Smokers and adults on very low-fat diets are at increased risk of developing vitamin-E deficiency. Preterm infants are particularly susceptible to hemolytic anemia (anemia caused by the destruction of red blood cells) due to vitamin-E deficiency. These infants are born with limited stores of vitamin E, which are exhausted by rapid growth, and they are inefficient in absorbing vitamin E from the intestinal tract. Without vitamin E to protect against oxidation, the destruction of cell membranes causes red blood cells to burst. To prevent hemolytic anemia, special formulas and supplements containing vitamin E are prescribed for preterm infants. Toxicity. Large doses of vitamin E can counter the actions of vitamin K and decrease the production of vitamin K– dependent clotting factors, thus promoting serious hemorrhaging effects in adults. Individuals who are vitamin-K deficient or who are taking anticoagulant medications such as warfarin or aspirin are especially at risk from megadoses of vitamin E. SEE ALSO VITAMINS, WATER-SOLUBLE. Kiran B. Misra Bibliography Insel, Paul; Turner, Elaine R.; and Ross, Don (2002). Nutrition. Sudbury, MA: Jones and Bartlett. Wardlaw, Gordon M.; Hampl, Jeffrey S.; and Disilvestro, Robert A. (2004). Perspectives in Nutrition, 6th edition. New York: McGraw-Hill. Whitney, Eleanor Noss, and Rolfes, Sharon Rady (2002). Understanding Nutrition, 9th edition. Belmont, CA: Wadsworth/Thomson Learning. « Vegetarianism Vitamins, Water-Soluble » Search the Nutrition and Well-Being A to Z Copyright © 2007 - Advameg Inc. Go no. 9.315 Fat-Soluble Vitamins by J. Anderson and L. Young1 Quick Facts... Small amounts of vitamins A, D, E and K are needed to maintain good health. Foods that contain these vitamins will not lose them when cooked. The body does not need these every day and stores them in the liver when not used. Most people do not need vitamin supplements. Megadoses of vitamins A, D, E or K can be toxic and lead to health problems. Vitamins are essential nutrients your body needs in small amounts for various roles in the human body. Vitamins are divided into two groups: water-soluble (B-complex and C) and fat-soluble (A, D, E and K). Unlike water-soluble vitamins that need regular replacement in the body, fat-soluble vitamins are stored in the liver and fatty tissues, and are eliminated much more slowly than water-soluble vitamins. Because fat-soluble vitamins are stored for long periods, they generally pose a greater risk for toxicity than water-soluble vitamins when consumed in excess. Eating a normal, well-balanced diet will not lead to toxicity in otherwise healthy individuals. However, taking vitamin supplements that contain mega doses of vitamins A, D, E and K may lead to toxicity. Remember, the body only needs small amounts of any vitamin. While diseases caused by a lack of fat-soluble vitamins are rare in the United States, symptoms of mild deficiency can develop without adequate amounts of vitamins in the diet. Additionally, some health problems may decrease the absorption of fat, and in turn, decrease the absorption of vitamins A, D, E and K. Consult your doctor about this. Table 1 lists sources of fat-soluble vitamins, their basic functions in the body, major deficiency symptoms caused by a lack of these vitamins, and symptoms of over-consumption. Vitamin A Vitamin A, also called retinol, has many functions in the body. In addition to helping the eyes adjust to light changes, vitamin A plays an important role in bone growth, tooth development, reproduction, cell division and gene expression. Also, the skin, eyes and mucous membranes of the mouth, nose, throat and lungs depend on vitamin A to remain moist. The best way to ensure your body gets enough vitamin A is to eat a variety of foods. Vitamin A is supplied primarily by certain foods of animal origin like dairy products, fish and liver. Some foods of plant origin contain beta-carotene, an antioxidant that the body converts to vitamin A. Beta-carotene, or provitamin A, comes from fruits and vegetables. Carrots, pumpkin, winter squash, dark green leafy vegetables and apricots are rich sources of beta-carotene. The recommendation for vitamin A intake is expressed as micrograms (mcg) of retinol activity equivalents (RAE). Retinol activity equivalents account for the fact that the body converts only a portion of beta-carotene to retinol. One RAE equals 1 mcg of retinol or 12 mcg of beta-carotene (see Table 2). True vitamin A deficiency in the United States is rare. Night blindness and very dry, rough skin may indicate a lack of vitamin A. Other signs of possible vitamin A deficiency include decreased resistance to infections, faulty tooth development, and slower bone growth. In the United States, toxic or excess levels of vitamin A are of more concern than deficiencies. The tolerable upper intake level for adults is 3,000 mcg RAE. It would be difficult to reach this level consuming food alone. But some multivitamin supplements contain high doses of vitamin A. If you take a multivitamin, check the label to be sure the majority of vitamin A provided is in the form of beta-carotene, which appears to be safe. Symptoms of vitamin A toxicity include dry, itchy skin, headache, nausea, and loss of appetite. Signs of severe overuse over a short period of time include dizziness, blurred vision and slowed growth. Vitamin A toxicity also can cause severe birth defects and may increase the risk for hip fractures. Physicians sometimes recommend that young infants take vitamin supplements that contain vitamin A. However, toddlers and children need protection from too much vitamin A due to their smaller body size. Typical foods eaten in large amounts by toddlers and children usually contain sufficient amounts of vitamin A. Provide a variety of foods for your children, and if in doubt, check with a pediatrician or Registered Dietitian. Table 1: Vitamin facts. Vitamin Source Physiological Functions Deficiency Overconsumption A (retinol) (provitamin A, such as beta carotene) Vitamin A: liver, vitamin A fortified milk and dairy products, butter, whole milk, cheese, egg yolk. Provitamin A: carrots, leafy Helps to form skin and mucous membranes and keep them healthy, thus increasing resistance to infections; essential for night vision; promotes bones and tooth development. Beta carotene is an Mild: nausea, irritability, blurred vision. Severe: growth retardation, enlargement of liver and spleen, loss of hair, bone pain, increased pressure in skull, skin Mild: night blindness, diarrhea, intestinal infections, impaired vision. Severe: inflammation of eyes, green vegetables, antioxidant and may sweet potatoes, protect against cancer. pumpkins, winter squash, apricots, cantaloupe. keratinization of changes. skin and eyes. Blindness in children. D Vitamin Dfortified dairy products, fortified margarine, fish oils, egg yolk. Synthesized by sunlight action on skin. Promotes hardening of bones and teeth, increases the absorption of calcium. Severe: rickets in Mild: nausea, weight children; loss, irritability. osteomalacia in Severe: mental and adults. physical growth retardation, kidney damage, movement of calcium from bones into soft tissues. E Vegetable oil, margarine, butter, shortening, green and leafy vegetables, wheat germ, whole grain products, nuts, egg yolk, liver. Protects vitamins A and Almost C and fatty acids; impossible to prevents damage to cell produce without membranes. starvation; Antioxidant. possible anemia in low birthweight infants. K Dark green leafy Helps blood to clot. vegetables, liver; also made by bacteria in the intestine. Excessive bleeding. Nontoxic under normal conditions. Severe: nausea, digestive tract disorders. None reported. Vitamin D Vitamin D plays a critical role in the body’s use of calcium and phosphorous. It increases the amount of calcium absorbed from the small intestine and helps form and maintain bones. Children especially need adequate amounts of vitamin D to develop strong bones and healthy teeth. The primary food sources of vitamin D are milk and other dairy products fortified with vitamin D. Vitamin D is also found in oily fish (e.g., herring, salmon and sardines) as well as in cod liver oil. In addition to the vitamin D provided by food, we obtain vitamin D through our skin which makes vitamin D in response to sunlight. An Adequate Intake (AI) for has been established for vitamin D (see Table 2). The AIs for vitamin D appear as micrograms (mcg) of cholecalciferol. Ten mcg of cholecalciferol equals 400 International Units (IU). Symptoms of vitamin D deficiency in growing children include rickets (long, soft bowed legs) and flattening of the back of the skull. Vitamin D deficiency in adults is called osteomalacia, which results in muscular weakness and weak bones. These conditions are rare in the United States. The tolerable upper intake level for vitamin D is set at 50 mcg for people 1 year of age and older (see Table 3). High doses of vitamin D supplements coupled with large amounts of fortified foods may cause accumulations in the liver and produce signs of poisoning. Signs of vitamin D toxicity include excess calcium in the blood, slowed mental and physical growth, decreased appetite, nausea and vomiting. It is important that infants and young children do not consume excess amounts of vitamin D regularly. Children exposed to the sun for 5 to 10 minutes daily will produce enough vitamin D. However, if children live in inner cities, wear clothes that cover most of their skin or live in northern climates where little sun is seen in the winter, then vitamin D deficiency may occur. Rather than give children a supplement, add fortified foods to their diet, such as vitamin D fortified milk and other dairy products. Table 2: Dietary Reference Intakes (DRI) for fat soluble vitamins. Life Vitamin Vitamin Vitamin Vitamin Vitamin E Vitamin E (IU) Stage A A (IU) D D (IU) (mg a-TE3) Group (mcg1) (mcg2) Infants 0.0-0.5 400* 1333 5* 200 4* 6 0.5-1.0 500* 1666 5* 200 5* 7.5 Children 1-3 300 1000 5* 200 6 9 4-8 400 1333 5* 200 7 10.5 9-13 600 2000 5* 200 11 16.5 14-18 900 3000 5* 200 15 22.5 19-30 900 3000 5* 200 15 22.5 31-50 900 3000 5* 200 15 22.5 51-70 900 3000 10* 400 15 22.5 71+ 900 3000 15* 600 15 22.5 Females 9-13 600 2000 5* 200 11 16.5 14-18 700 2333 5* 200 15 22.5 19-30 700 2333 5* 200 15 22.5 31-50 700 2333 5* 200 15 22.5 51-70 700 2333 10* 400 15 22.5 71+ 700 2333 15* 600 15 22.5 Pregnant <18 750 2500 5* 200 15 22.5 19-30 770 2566 5* 200 15 22.5 31-50 770 5* 200 15 22.5 Males Lactating <18 1,300 4000 5* 200 19 28.8 19-30 1,300 4333 5* 200 19 28.8 31-50 1,300 4333 5* 200 19 28.8 *Indicates an Adequate Intake (AI). All other values are Recommended Dietary Allowance (RDA). 1As retinol activity equivalents (RAEs). 1 RAE = 1mcg retinol or 12 mcg beta-carotene. 2 As cholecalciferol. 10 mcg cholecalciferol = 400 IU of vitamin D. 3 As alpha-tocopherol equivalents. 1 mg of alpha-tocopherol = 1.5 IU of vitamin E. Vitamin E Vitamin E acts as an antioxidant, protecting vitamins A and C, red blood cells and essential fatty acids from destruction. Research from a decade ago suggested that taking antioxidant supplements, vitamin E in particular, might help prevent heart disease and cancer. However, newer findings indicate that people who take antioxidant supplements are not better protected against heart disease and cancer than non-supplement users. On the other hand, there are many studies that show a link between regularly eating antioxidant-rich fruits and vegetables and a lower risk for heart disease, cancer and several other diseases. The RDA for vitamin E is based on the most active and usable form called alpha-tocopherol (see Table 2). One milligram of alpha-tocopherol equals to 1.5 International Units (IU).About 60 percent of vitamin E in the diet comes from vegetable oil or products made with vegetable oils. Therefore, good food sources of vitamin E include vegetable oils and margarines. Vitamin E is also found in fruits and vegetables, grains, nuts, seeds and fortified cereals. Vitamin E deficiency is rare. Cases of vitamin E deficiency only occur in premature infants and people unable to absorb fats. The tolerable upper intake levels for vitamin E are shown in Table 3. Large doses of vitamin E pose a hazard to people who take blood-thinning medications. People taking statin drugs are also not advised to take supplemental vitamin E because it may interfere with how the medication works. Vitamin K Naturally produced by the bacteria in the intestines, vitamin K plays an essential role in normal blood clotting and helps promote bone health. Good food sources of vitamin K are green vegetables such as turnip greens, spinach, cauliflower, cabbage and broccoli, and certain vegetables oils including soybean oil, cottonseed oil, canola oil and olive oil. Animal foods, in general, contain limited amounts of vitamin K. To help ensure people receive sufficient amounts of vitamin K, an Adequate Intake (AI) has been established for each age group (see Table 2). Without sufficient amounts of vitamin K, hemorrhaging can occur. Deficiencies may appear in infants, or in people who take anticoagulants or antibiotic drugs. Newborn babies lack the intestinal bacteria to produce vitamin K and need a supplement for the first week. People on anticoagulant drugs (blood thinners) may become deficient in vitamin K, but should not change their vitamin K intake without consulting a physician because the effectiveness of the drug may be affected. People taking antibiotics may lack vitamin K temporarily because intestinal bacteria are sometimes killed as a result of longterm use of antibiotics. Also, people with chronic diarrhea may have problems absorbing sufficient amounts of vitamin K through the intestine and should consult their physician to determine if supplementation is necessary. Although a tolerable upper intake level has not been established for vitamin K, excessive amounts can cause the breakdown of red blood cells and liver damage. Large doses are not advised. Table 3. Tolerable upper intake levels (UL)*. Life Stage Vitamin A Vitamin Group (mcg) (mcg) Infants Children Males/Females Pregnant Lactating D Vitamin E (mg a-TE) 0.0-0.5 600 25 ND1 0.5-1.0 600 25 ND 1-3 600 50 200 4-8 900 50 300 9-13 1,700 50 600 14-18 2,800 50 800 19-70 3,000 50 1,000 >71 3,000 50 1,000 & <18 2,800 50 800 3,000 50 1,000 19-50 *A UL for vitamin K was 1ND = not determinable due to insufficient data. not established. Standards for Measuring Intake Vitamin requirements are expressed in small units. Most are given in milligrams (mg) or micrograms (mcg). When comparing vitamin amounts on labels, note whether values are in micrograms (mcg), milligrams (mg) or International Units (IU). Make sure you compare the same units. Dietary Reference Intakes (DRI) are dietary standards for desirable and/or safe vitamin intake levels published by the Food and Nutrition Board of the National Academy of Sciences National Research Council. DRIs include three sets of values: recommended dietary allowances (referred to as RDAs) which are intended to meet the nutrient needs of healthy individuals; tolerable upper intake levels (UL) which are designed to help people avoid harmful effects caused by consuming too much of a nutrient; and adequate intakes (AI), which are established when there is not enough scientific evidence to set an RDA and are based on diets known to be nutritionally adequate for U.S. and Canadian populations. Table 2 lists the recommended amounts of fat-soluble vitamins that individuals in the United States need daily for good health. Table 3 provides the tolerable upper intake levels. References Complete Book of vitamins and Minerals (2000). Publications International, Ltd. Facts About Dietary Supplements (2001). NIH Clinical Center. Available on www.cc.nih.gov/ccc/supplements/intro.html Insel, P. et al (2001). Nutrition. Sudbury, MA: Jones and Bartlett publishers. Dietary Reference intakes for Calcium, Phosphorus, Magnesium, Vitamin D and Fluoride. Washington, DC: National Academy Press, 1997. Dietary Reference Intakes for Vitamin C, Vitamin E, Selenium, and Carotenoids. Washington, DC: National Academy Press, 2000. Dietary Reference Intakes for Vitamin A, Vitamin K, Arsenic, Boron, Chromium, Copper, Iodine, Iron, Manganese, Molybdenum, Nickel, Silicon, Vanadium, and Zinc. Washington, DC: National Academy Press, 2001 J. Anderson, Colorado State University Extension food and nutrition specialist and professor, food science and human nutrition; and L. Young, M.S., former graduate student. 7/96. Revised 5/06. 1 Go to top of this page.