Hypervitaminosis A

Hypervitaminosis A
Classification and external resources
Specialty endocrinology
ICD-10 E67.0
ICD-9-CM 278.2
DiseasesDB 13888
MedlinePlus 000350
eMedicine med/2382
Cod liver oil - a potentially toxic source of Vitamin A: Hypervitaminosis A can result from ingestion of too much vitamin A from diet, supplements, or prescription medications.

Hypervitaminosis A refers to the toxic effects of ingesting too much preformed vitamin A. Symptoms arise as a result of altered bone metabolism and altered metabolism of other fat-soluble vitamins. Hypervitaminosis A is believed to have occurred in early humans, and the problem has persisted throughout human history.

Toxicity results from ingesting too much preformed vitamin A from foods (such as fish or animal liver), supplements, or prescription medications and can be prevented by ingesting no more than the recommended daily amount.

Diagnosis can be difficult, as serum retinol is not sensitive to toxic levels of vitamin A, but there are effective tests available. Hypervitaminosis A is usually treated by stopping intake of the offending food(s), supplement(s), or medication. Most people make a full recovery.

High intake of provitamin carotenoids (such as beta carotene) from vegetables and fruits does not cause hypervitaminosis A, as conversion from carotenoids to the active form of vitamin A is regulated by the body to maintain an optimum level of the vitamin. Carotenoids themselves cannot produce toxicity.

Signs and symptoms

Symptoms may include:[1]

Causes

Hypervitaminosis A results from excessive intake of preformed vitamin A. A genetic variance in tolerance to vitamin A intake may occur.[22] Children are particularly sensitive to vitamin A, with daily intakes of 1500 IU/kg body weight reportedly leading to toxicity.[20]

Types of vitamin A

Sources of toxicity

Types of toxicity

Mechanism

Absorption and storage in the liver of preformed vitamin A occur very efficiently until a pathologic condition develops.[20]

Delivery to tissues

Absorption

When ingested, 70-90% of preformed vitamin A is absorbed and used.[20]

Storage

About 80% of the total body reserves of vitamin A are in the liver. Fat is another significant storage site, while the lung and kidneys may also be capable of storage.[20]

Transport

Once in the liver, retinol binds to retinol-binding protein (RBP) and is transported from the liver to tissues as the holo-RBP complex. The range of serum retinol concentrations under normal conditions is 1–3 μmol/l. Elevated amounts of retinyl ester (i.e., > 10% of total circulating vitamin A) in the fasting state have been used as markers for chronic hypervitaminosis A in humans. Candidate mechanisms for this increase include decreased hepatic uptake of vitamin A and the leaking of esters into the bloodstream from saturated hepatic stellate cells.[20]

Effects

Effects include increased bone turnover and altered metabolism of fat-soluble vitamins. More research is needed to fully elucidate the effects.

Increased bone turnover

Retinoic acid suppresses osteoblast activity and stimulates osteoclast formation in vitro,[23] resulting in increased bone resorption and decreased bone formation. It is likely to exert this effect by binding to specific nuclear receptors (members of the retinoic acid receptor or retinoid X receptor nuclear transcription family) which are found in every cell (including osteoblasts and osteoclasts).

This change in bone turnover is likely to be the reason for numerous effects seen in hypervitaminosis A, such as hypercalcemia and numerous bone changes such as bone loss that potentially leads to osteoporosis, spontaneous bone fractures, altered skeletal development in children, skeletal pain, radiographic changes,[20][23] and bone lesions.[29]

Altered fat-soluble vitamin metabolism

Vitamin A is fat-soluble and high levels have been reported affect metabolism of the other fat-soluble vitamins D,[23] E, and K.

The toxic effects of vitamin A might be related to altered vitamin D metabolism, concurrent ingestion of substantial amounts of vitamin D, or binding of vitamin A to receptor heterodimers. Antagonistic and synergistic interactions between these two vitamins have been reported, as they relate to skeletal health.

Stimulation of bone resorption by vitamin A has been reported to be independent of its effects on vitamin D.[23]

Diagnosis

Tests

Tests may include:[1]

Relevance of blood tests

Retinol concentrations are nonsensitive indicators

Assessing vitamin A status in persons with subtoxicity or toxicity is complicated because serum retinol concentrations are not sensitive indicators in this range of liver vitamin A reserves.[20] The range of serum retinol concentrations under normal conditions is 1–3 μmol/l and, because of homeostatic regulation, that range varies little with widely disparate vitamin A intakes[20]

Retinol esters have been used as markers

Retinyl esters can be distinguished from retinol in serum and other tissues and quantified with the use of methods such as high-performance liquid chromatography.[20]

Elevated amounts of retinyl ester (i.e., > 10% of total circulating vitamin A) in the fasting state have been used as markers for chronic hypervitaminosis A in humans and monkeys.[20] This increased retinyl ester may be due to decreased hepatic uptake of vitamin A and the leaking of esters into the bloodstream from saturated hepatic stellate cells.[20]

Prevention

Hypervitaminosis A can be prevented by not ingesting more than the US Institute of Medicine Daily Tolerable Upper Level of intake for Vitamin A. This level is for synthetic and natural retinol ester forms of vitamin A. Carotene forms from dietary sources are not toxic. The dose over and above the RDA is among the narrowest of the vitamins and minerals. Possible pregnancy, liver disease, high alcohol consumption, and smoking are indications for close monitoring and limitation of vitamin A administration.

Daily Tolerable Upper Level

Life stage group category Upper Level (μg/day)
Infants

0–6 months
7–12 months


600
600
Children

1–3 years
4–8 years


600
900
Males

9–13 years
14–18 years
19 – >70 years


1700
2800
3000
Females

9–13 years
14–18 years
19 – >70 years


1700
2800
3000
Pregnancy

<19 years
19 – >50 years


2800
3000
Lactation

<19 years
19 – >50 years


2800
3000

Treatment

In humans

If liver damage has progressed into fibrosis, synthesizing capacity is compromised and supplementation can replenish PC. However, recovery is dependent on removing the causative agent; stopping high Vitamin A intake.[30][31][32][33]

In animals

These treatments have been used to help treat or manage toxicity in animals. Although not considered part of standard treatment, they might be of some benefit to humans.

In vitro

These treatments help prevent toxic effects in vitro.

History

Vitamin A toxicity is known to be an ancient phenomenon; fossilized skeletal remains of early humans suggest bone abnormalities may have been caused by hypervitaminosis A.[20]

Vitamin A toxicity has long been known to the Inuit and has been known by Europeans since at least 1597 when Gerrit de Veer wrote in his diary that, while taking refuge in the winter in Nova Zemlya, he and his men became severely ill after eating polar bear liver.[45]

In 1913, Antarctic explorers Douglas Mawson and Xavier Mertz were both poisoned (and Mertz died) from eating the livers of their sled dogs during the Far Eastern Party.[46] Another study suggests, however, that exhaustion and diet change are more likely to have caused the tragedy.[47]

Other animals

Some Arctic animals demonstrate no signs of hypervitaminosis A despite having 10-20 times the level of vitamin A in their livers as other Arctic animals. These animals are top predators and include the polar bear, Arctic fox, bearded seal, and glaucous gull. This ability to efficiently store higher amounts of vitamin A may have contributed to their survival in the extreme environment of the Arctic.[48]

See also

References

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