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Wikipedia

Vitamin A

November 03, 2023

This article is about the family of vitamers. For the form usually used as a supplement, see Retinol.

Vitamin A is a fat-soluble vitamin and an essential nutrient for animals. The term "vitamin A" encompasses a group of chemically related organic compounds that includes retinol, retinal (also known as retinaldehyde), retinoic acid, and several provitamin (precursor) carotenoids, most notably beta-carotene.[2][3][4][5] Vitamin A has multiple functions: it is essential for embryo development and growth, for maintenance of the immune system, and for vision, where it combines with the protein opsin to form rhodopsin – the light-absorbing molecule necessary for both low-light (scotopic vision) and color vision.[6]

Vitamin A
Retinol
Clinical data
AHFS/Drugs.comMonograph
License data
Routes of
administration		by mouth, IM[1]
Drug classvitamin
ATC code
Legal status
Legal status
Identifiers
  • (2E,4E,6E,8E)-3,7-dimethyl-9-(2,6,6-trimethylcyclohex-1-en-1-yl)nona-2,4,6,8-tetraen-1-ol
CAS Number
  • 68-26-8
  • mixture: 11103-57-4 Y
PubChem CID
  • 1071
IUPHAR/BPS
  • 4053
ChemSpider
  • 393012
UNII
  • G2SH0XKK91
  • mixture: 81G40H8B0T Y
ChEBI
  • CHEBI:17336
ChEMBL
  • ChEMBL986
ECHA InfoCard100.031.195
Chemical and physical data
FormulaC20H30O
Molar mass286.459 g·mol−1
3D model (JSmol)
  • Interactive image
Melting point62–64 °C (144–147 °F)
Boiling point137–138 °C (279–280 °F) (10−6 mm Hg)
  • OC/C=C(C)/C=C/C=C(C)/C=C/C1=C(C)/CCCC1(C)C
  • InChI=1S/C20H30O/c1-16(8-6-9-17(2)13-15-21)11-12-19-18(3)10-7-14-20(19,4)5/h6,8-9,11-13,21H,7,10,14-15H2,1-5H3/b9-6+,12-11+,16-8+,17-13+ Y
  • Key:FPIPGXGPPPQFEQ-OVSJKPMPSA-N

Vitamin A occurs as two principal forms in foods: A) retinol, found in animal-sourced foods, either as retinol or bound to a fatty acid to become a retinyl ester, and B) the carotenoids alpha-carotene, β-carotene, gamma-carotene, and the xanthophyll beta-cryptoxanthin (all of which contain β-ionone rings) that function as provitamin A in herbivore and omnivore animals which possess the enzymes that cleave and convert provitamin carotenoids to retinal and then to retinol.[7] Some carnivore species lack this enzyme. The other carotenoids have no vitamin activity.[5]

Dietary retinol is absorbed from the digestive tract via passive diffusion. Unlike retinol, β-carotene is taken up by enterocytes by the membrane transporter protein scavenger receptor B1 (SCARB1), which is upregulated in times of vitamin A deficiency.[5] Storage of retinol is in lipid droplets in the liver. A high capacity for long-term storage of retinol means that well-nourished humans can go months on a vitamin A- and β-carotene-deficient diet, while maintaining blood levels in the normal range.[3] Only when the liver stores are nearly depleted will signs and symptoms of deficiency show.[3] Retinol is reversibly converted to retinal, then irreversibly to retinoic acid, which activates hundreds of genes.[8]

Vitamin A deficiency is common in developing countries, especially in Sub-Saharan Africa and Southeast Asia. Deficiency can occur at any age but is most common in pre-school age children and pregnant women, the latter due to a need to transfer retinol to the fetus. Vitamin A deficiency is estimated to affect approximately one-third of children under the age of five around the world, resulting in hundreds of thousands of cases of blindness and deaths from childhood diseases because of immune system failure.[9] Reversible night blindness is an early indicator of low vitamin A status. Plasma retinol is used as a biomarker to confirm vitamin A deficiency. Breast milk retinol can indicate a deficiency in nursing mothers. Neither of these measures indicates the status of liver reserves.[5]

The European Union and various countries have set recommendations for dietary intake, and upper limits for safe intake. Vitamin A toxicity also referred to as hypervitaminosis A, occurs when there is too much vitamin A accumulating in the body. Symptoms may include nervous system effects, liver abnormalities, fatigue, muscle weakness, bone and skin changes, and others. The adverse effects of both acute and chronic toxicity are reversed after consumption of high dose supplements is stopped.[5]

Definition edit

Vitamin A is a fat-soluble vitamin, a category that also includes vitamins D, E and K. The vitamin encompasses several chemically related naturally occurring compounds or metabolites, i.e., vitamers, that all contain a β-ionone ring.[3] The primary dietary form is retinol, which may have a fatty acid molecule attached, creating a retinyl ester, when stored in the liver. Retinol – the transport and storage form of vitamin A – is interconvertible with retinal, catalyzed to retinal by retinol dehydrogenases and back to retinol by retinaldehyde reductases.[10]

retinal + NADPH + H+ ⇌ retinol + NADP+
retinol + NAD+ ⇌ retinal + NADH + H+

Retinal, (also known as retinaldehyde) can be irreversibly converted to all-trans-retinoic acid by the action of retinal dehydrogenase

retinal + NAD+ + H2O → retinoic acid + NADH + H+

Retinoic acid diffuses into the cell nucleus where it regulates more than 500 genes by binding directly to gene targets via retinoic acid receptors.[5]

In addition to retinol, retinal and retinoic acid, there are plant-, fungi- or bacteria-sourced carotenoids which can be metabolized to retinol, and are thus vitamin A vitamers.[11]

There are also what are referred to as 2nd, 3rd and 4th generation retinoids which are not considered vitamin A vitamers because they cannot be converted to retinol, retinal or all-trans-retinoic acid. Some are prescription drugs, oral or topical, for various indications. Examples are etretinate, acitretin, adapalene, bexarotene, tazarotene and trifarotene.[12][13]

Absorption, metabolism and excretion edit

Retinyl esters from animal-sourced foods (or synthesized for dietary supplements for humans and domesticated animals) are acted upon by retinyl ester hydrolases in the lumen of the small intestine to release free retinol. Retinol enters intestinal absorptive cells by passive diffusion. Absorption efficiency is in the range of 70 to 90%. Humans are at risk for acute or chronic vitamin A toxicity because there are no mechanisms to suppress absorption or excrete the excess in urine.[4] Within the cell, retinol is there bound to retinol binding protein 2 (RBP2). It is then enzymatically reesterified by the action of lecithin retinol acyltransferase and incorporated into chylomicrons that are secreted into the lymphatic system.

Unlike retinol, β-carotene is taken up by enterocytes by the membrane transporter protein scavenger receptor B1 (SCARB1). The protein is upregulated in times of vitamin A deficiency. If vitamin A status is in the normal range, SCARB1 is downregulated, reducing absorption.[5] Also downregulated is the enzyme beta-carotene 15,15'-dioxygenase (formerly known as beta-carotene 15,15'-monooxygenase) coded for by the BCMO1 gene, responsible for symmetrically cleaving β-carotene into retinal.[7] Absorbed β-carotene is either incorporated as such into chylomicrons or first converted to retinal and then retinol, bound to RBP2. After a meal, roughly two-thirds of the chylomicrons are taken up by the liver with the remainder delivered to peripheral tissues. Peripheral tissues also can convert chylomicron β-carotene to retinol.[5][14]

The capacity to store retinol in the liver means that well-nourished humans can go months on a vitamin A deficient diet without manifesting signs and symptoms of deficiency. Two liver cell types are responsible for storage and release: hepatocytes and hepatic stellate cells (HSCs). Hepatocytes take up the lipid-rich chylomicrons, bind retinol to retinol-binding protein 4 (RBP4), and transfer the retinol-RBP4 to HSCs for storage in lipid droplets as retinyl esters. Mobilization reverses the process: retinyl ester hydrolase releases free retinol which is transferred to hepatocytes, bound to RBP4, and put into blood circulation. Other than either after a meal or when consumption of large amounts exceeds liver storage capacity, more than 95% of retinol in circulation is bound to RBP4.[14]

Carnivores edit

Strict carnivores manage vitamin A differently than omnivores and herbivores. Carnivores are more tolerant of high intakes of retinol because those species have the ability to excrete retinol and retinyl esters in urine. Carnivores also have the ability to store more in the liver, due to a higher ratio of liver HSCs to hepatocytes compared to omnivores and herbivores. For humans, liver content can range from 20 to 30 μg/gram wet weight. Notoriously, polar bear liver is acutely toxic to humans because content has been reported in range of 2,215 to 10,400 μg/g wet weight.[15] As noted, in humans, retinol circulates bound to RBP4. Carnivores maintain R-RBP4 within a tight range while also having retinyl esters in circulation. Bound retinol is delivered to cells while the esters are excreted in the urine.[15] In general, carnivore species are poor converters of ionone-containing carotenoids, and pure carnivores such as felidae (cats) lack the cleaving enzyme entirely. They must have retinol or retinyl esters in their diet.[15]

Herbivores edit

Herbivores consume ionone-containing carotenoids and convert those to retinal. Some species, including cattle and horses, have measurable amounts of beta-carotene circulating in the blood, and stored in body fat, creating yellow fat cells. Most species have white fat and no beta-carotene in circulation.[15]

Activation and excretion edit

In the liver and peripheral tissues of humans, retinol is reversibly converted to retinal by the action of alcohol dehydrogenases, which are also responsible for the conversion of ethanol to acetaldehyde. Retinal is irreversibly oxidized to retinoic acid (RA) by the action of aldehyde dehydrogenases. RA regulates the activation or deactivation of genes. The oxidative degradation of RA is induced by RA - its presence triggers its removal, making for a short-acting gene transcription signal. This deactivation is mediated by a cytochrome P450 (CYP) enzyme system, specifically enzymes CYP26A1, CYP26B1 and CYP26C1. CYP26A1 is the predominant form in the human liver; all other human adult tissues contained higher levels of CYP26B1. CYP26C1 is expressed mainly during embryonic development. All three convert retinoic acid into 4-oxo-RA, 4-OH-RA and 18-OH-RA. Glucuronic acid forms water-soluble glucuronide conjugates with the oxidized metabolites, which are then excreted in urine and feces.[8]

Metabolic functions edit

Further information: Vitamin A deficiency

Other than for vision, the metabolic functions of vitamin A are mediated by all-trans-retinoic acid (RA). The formation of RA from retinal is irreversible. To prevent accumulation of RA it is oxidized and eliminated fairly quickly, i.e., has a short half-life. Three cytochromes catalyze the oxidation of retinoic acid. The genes for Cyp26A1, Cyp26B1 and Cyp26C1 are induced by high levels of RA, providing a self-regulating feedback loop.[16][17]

Vision and eye health edit

Vitamin A status involves eye health via two separate functions. Retinal is an essential factor in rod cells and cone cells in the retina responding to light exposure by sending nerve signals to the brain. An early sign of vitamin A deficiency is night blindness.[5] Vitamin A in the form of retinoic acid is essential to normal epithelial cell functions. Severe vitamin A deficiency, common in infants and young children in southeast Asia causes xerophthalmia characterized by dryness of the conjunctival epithelium and cornea. Untreated, xerophthalmia progresses to corneal ulceration and blindness.[18]

Vision edit

Main article: visual cycle

The role of vitamin A in the visual cycle is specifically related to the retinal compound. Retinol is converted by the enzyme RPE65 within the retinal pigment epithelium into 11-cis-retinal. Within the eye, 11-cis-retinal is bound to the protein opsin to form rhodopsin in rod cells and iodopsin in cone cells. As light enters the eye, the 11-cis-retinal is isomerized to the all-trans form. The all-trans-retinal dissociates from the opsin in a series of steps called photo-bleaching. This isomerization induces a nervous signal along the optic nerve to the visual center of the brain. After separating from opsin, the all-trans-retinal is recycled and converted back to the 11-cis-retinal form by a series of enzymatic reactions, which then completes the cycle by binding to opsin to reform rhodopsin in the retina.[5] In addition, some of the all-trans-retinal may be converted to all-trans-retinol form and then transported with an interphotoreceptor retinol-binding protein to the retinal pigmented epithelial cells. Further esterification into all-trans-retinyl esters allow for storage of all-trans-retinol within the pigment epithelial cells to be reused when needed. It is for this reason that a deficiency in vitamin A will inhibit the reformation of rhodopsin, and will lead to one of the first symptoms, night blindness.[5][19][20]

Night blindness edit

Main article: Nyctalopia

Vitamin A deficiency (VAD) caused night blindness is a reversible difficulty for the eyes to adjust to dim light. It is common in young children who have a diet inadequate in retinol and beta-carotene. A process called dark adaptation typically causes an increase in photopigment amounts in response to low levels of illumination. This increases light sensitivity by up to 100,000 times compared to normal daylight conditions. Significant improvement in night vision takes place within ten minutes, but the process can take up to two hours to reach maximal effect.[6] People expecting to work in a dark environment wore red-tinted goggles or were in a red light environment to not reverse the adaptation because red light does not deplete rhodopsin versus what occurs with yellow or green light.[20]

Xerophthalmia and childhood blindness edit

Main article: Xerophthalmia
 
Typical location of Bitot's spots

Xerophthalmia, caused by a severe vitamin A deficiency, is described by pathologic dryness of the conjunctival epithelium and cornea. The conjunctiva becomes dry, thick, and wrinkled. Indicative is the appearance of Bitot's spots, which are clumps of keratin debris that build up inside the conjunctiva. If untreated, xerophthalmia can lead to dry eye syndrome, corneal ulceration and ultimately to blindness as a result of cornea and retina damage. Although xerophthalmia is an eye-related issue, prevention (and reversal) are functions of retinoic acid having been synthesized from retinal rather than the 11-cis-retinal to rhodopsin cycle.[21]

Throughout southeast Asia, estimates are that more than half of children under the age of six years have subclinical vitamin A deficiency and night blindness, with progression to xerophthalmia being the leading cause of preventable childhood blindness.[21] Estimates are that each year there are 350,000 cases of childhood blindness due to vitamin A deficiency.[18] The causes are vitamin A deficiency during pregnancy, followed by low transfer of vitamin A during lactation and infant/child diets low in vitamin A or beta-carotene.[21][18] The prevalence of pre-school age children who are blind due to vitamin A deficiency is lower than expected from incidence of new cases only because childhood vitamin A deficiency significantly increases all-cause mortality.[18]

According to a 2017 Cochrane review, vitamin A deficiency, using serum retinol less than 0.70 µmol/L as a criterion, is a major public health problem affecting an estimated 190 million children under five years of age in low- and middle-income countries, primarily in Sub-Saharan Africa and Southeast Asia. In lieu of or in combination with food fortification programs, many countries have implemented public health programs in which children are periodically given very large oral doses of synthetic vitamin A, usually retinyl palmitate, as a means of preventing and treating VAD. Doses were 50,000 to 100,000 IU (International units) for children aged 6 to 11 months and 100,000 to 200,000 IU for children aged 12 months to five years, the latter typically every four to six months. In addition to a 24% reduction in all-cause mortality, eye-related results were reported. Prevalence of Bitot's spots at follow-up were reduced by 58%, night blindness by 68%, xerophthalmia by 69%.[22]

Gene regulation edit

RA regulates gene transcription by binding to nuclear receptors known as retinoic acid receptors (RARs; RARα, RARβ, RARγ) which are bound to DNA as heterodimers with retinoid "X" receptors (RXRs; RXRα, RXRβ, RXRγ). RARs and RXRs must dimerize before they can bind to the DNA. Expression of more than 500 genes is responsive to retinoic acid.[5] The process is that RAR-RXR heterodimers recognize retinoic acid response elements on DNA.[23] The receptors undergo a conformational change that causes co-repressors to dissociate from the receptors. Coactivators can then bind to the receptor complex, which may help to loosen the chromatin structure from the histones or may interact with the transcriptional machinery.[24] This response upregulates or downregulates the expression of target genes, including the genes that encode for the receptors themselves.[19] To prevent excess accumulation of RA it must be metabolized and eliminated. Three cytochromes (Cyp26A1, Cyp26B1 Cyp26C1) catalyze the oxidation of RA. The genes for these proteins are induced by high concentrations of RA, thus providing a regulatory feedback mechanism.[5]

Embryology edit

In vertebrates and invertebrate chordates, RA has a pivotal role during development. Altering levels of endogenous RA signaling during early embryology, both too low and too high, leads to birth defects,[25][26] including congenital vascular and cardiovascular defects.[27][28] Of note, fetal alcohol spectrum disorder encompasses congenital anomalies, including craniofacial, auditory, and ocular defects, neurobehavioral anomalies and mental disabilities caused by maternal consumption of alcohol during pregnancy. It is proposed that in the embryo there is competition between acetaldehyde, an ethanol metabolite, and retinaldehyde (retinal) for aldehyde dehydrogenase activity, resulting in a retenoic acid deficiency, and attributing the congenital birth defects to the loss of RA activated gene activation. In support of this theory, ethanol-induced developmental defects can be ameliorated by increasing the levels of retinol or retinal.[29] As for the risks of too much RA, the prescription drugs tretinoin (all-trans-retinoic acid) and isotretinoin (13-cis-retinoic acid), used orally or topically for acne treatment, come with warnings to not be used by pregnant women or women who are anticipating becoming pregnant, as they are known human teratogens.[30][31]

Immune functions edit

Vitamin A deficiency (VAD) has been linked to compromised resistance to infectious diseases.[32][33] In countries where early childhood VAD is common, vitamin A supplementation public health programs initiated in the 1980s were shown to reduce the incidence of diarrhea and measles, and all-cause mortality.[22][34][35] VAD also increases the risk of immune system over-reaction, leading to chronic inflammation in the intestinal system, stronger allergic reactions and autoimmune diseases.[32][33][36]

Lymphocytes and monocytes are types of white blood cells of the immune system.[37] Lymphocytes include natural killer cells, which function in innate immunity, T cells for adaptive cellular immunity and B cells for antibody-driven adaptive humoral immunity. Monocytes differentiate into macrophages and dendritic cells. Some lymphocytes migrate to the thymus where they differentiate into several types of T cells, in some instances referred to as "killer" or "helper" T cells and further differentiate after leaving the thymus. Each subtype has functions driven by the types of cytokines secreted and organs to which the cells preferentially migrate, also described as trafficking or homing.[38][39]

Reviews based on in vitro and animal research describe the role that retinoic acid (RA) has in the immune system. RA triggers receptors in bone marrow, resulting in generation of new white blood cells.[40] RA regulates proliferation and differentiation of white blood cells, the directed movement of T cells to the intestinal system, and to the up- and down-regulation of lymphocyte function.[32][33][34][35][36][41] If RA is adequate, T helper cell subtype Th1 is suppressed and subtypes Th2, Th17 and iTreg (for regulatory) are induced. Dendritic cells located in intestinal tissue have enzymes that convert retinal to all-trans-retinoic acid, to be taken up by retinoic acid receptors on lymphocytes. The process triggers gene expression that leads to T cell types Th2, Th17 and iTreg moving to and taking up residence in mesenteric lymph nodes and Peyer's patches, respectively outside and on the inner wall of the small intestine.[34][35] The net effect is a down-regulation of immune activity, seen as tolerance of food allergens, and tolerance of resident bacteria and other organisms in the microbiome of the large intestine.[32][33][36] In a vitamin A deficient state, innate immunity is compromised and pro-inflammatory Th1 cells predominate.[32][41]

Skin edit

Deficiencies in vitamin A have been linked to an increased susceptibility to skin infection and inflammation.[42] Vitamin A appears to modulate the innate immune response and maintains homeostasis of epithelial tissues and mucosa through its metabolite, retinoic acid (RA). As part of the innate immune system, toll-like receptors in skin cells respond to pathogens and cell damage by inducing a pro-inflammatory immune response which includes increased RA production.[42] The epithelium of the skin encounters bacteria, fungi and viruses. Keratinocytes of the epidermal layer of the skin produce and secrete antimicrobial peptides (AMPs). Production of AMPs resistin and cathelicidin, are promoted by RA.[42]

Units of measurement edit

As some carotenoids can be converted into vitamin A, attempts have been made to determine how much of them in the diet is equivalent to a particular amount of retinol, so that comparisons can be made of the benefit of different foods. The situation can be confusing because the accepted equivalences have changed over time

For many years, a system of equivalencies in which an international unit (IU) was equal to 0.3 μg of retinol (~1 nmol), 0.6 μg of β-carotene, or 1.2 μg of other provitamin-A carotenoids was used.[43] This relationship was alternatively expressed by the retinol equivalent (RE): one RE corresponded to 1 μg retinol, to 2 μg β-carotene dissolved in oil, to 6 μg β-carotene in foods, and to 12 μg of either α-carotene, γ-carotene, or β-cryptoxanthin in food.

Newer research has shown that the absorption of provitamin-A carotenoids is only half as much as previously thought. As a result, in 2001 the US Institute of Medicine recommended a new unit, the retinol activity equivalent (RAE). Each μg RAE corresponds to 1 μg retinol, 2 μg of β-carotene in oil, 12 μg of "dietary" beta-carotene, or 24 μg of the three other dietary provitamin-A carotenoids.[4]

Substance and its chemical environment (per 1 μg) IU (1989) μg RE (1989)[4] μg RAE (2001)[4]
Retinol 3.33 1 1
beta-Carotene, dissolved in oil 1.67 1/2 1/2
beta-Carotene, common dietary 1.67 1/6 1/12
0.83 1/12 1/24

Animal models have shown that at the enterocyte cell wall, β-carotene is taken up by the membrane transporter protein scavenger receptor class B, type 1 (SCARB1). Absorbed β-carotene is converted to retinal and then retinol. The first step of the conversion process consists of one molecule of β-carotene cleaved by the enzyme β-carotene-15, 15'-monooxygenase, which in humans and other mammalian species is encoded by the BCM01 gene,[7] into two molecules of retinal. When plasma retinol is in the normal range, gene expression for SCARB1 and BC01 are suppressed, creating a feedback loop that suppresses β-carotene absorption and conversion.[11] Absorption suppression is not complete, as receptor 36 is not downregulated.[11]

Dietary recommendations edit

The US National Academy of Medicine updated Dietary Reference Intakes (DRIs) in 2001 for vitamin A, which included Recommended Dietary Allowances (RDAs).[4] For infants up to 12 months there was not sufficient information to establish a RDA, so Adequate Intake (AI) is shown instead. As for safety, tolerable upper intake levels (ULs) were also established. For ULs, carotenoids are not added when calculating total vitamin A intake for safety assessments.[4]

Life stage group US RDAs or AIs
(μg RAE/day)[4]		 US Upper limits
(μg/day)[4]
Infants 0–6 months 400 (AI) 600
7–12 months 500 (AI) 600
Children 1–3 years 300 600
4–8 years 400 900
Males 9–13 years 600 1700
14–18 years 900 2800
>19 years 900 3000
Females 9–13 years 600 1700
14–18 years 700 2800
>19 years 700 3000
Pregnancy <19 years 750 2800
>19 years 770 3000
Lactation <19 years 1200 2800
>19 years 1300 3000

The European Food Safety Authority (EFSA) refers to the collective set of information as Dietary Reference Values, with Population Reference Intake (PRI) instead of RDA, and Average Requirement instead of EAR. AI and UL defined the same as in United States. For women and men of ages 15 and older, the PRIs are set respectively at 650 and 750 μg RE/day. PRI for pregnancy is 700 μg RE/day, for lactation 1300/day. For children of ages 1–14 years, the PRIs increase with age from 250 to 600 μg RE/day. These PRIs are similar to the US RDAs.[44] The EFSA reviewed the same safety question as the United States, and set ULs at 800 for ages 1–3, 1100 for ages 4–6, 1500 for ages 7–10, 2000 for ages 11–14, 2600 for ages 15–17 and 3000 μg/day for ages 18 and older for preformed vitamin A, i.e., not including dietary contributions from carotenoids.[45]

Safety edit

Vitamin A toxicity (hypervitaminosis A) occurs when too much vitamin A accumulates in the body. It comes from consumption of preformed vitamin A but not of carotenoids, as conversion of the latter to retinol is suppressed by the presence of adequate retinol.

Retinol safety edit

Main article: Hypervitaminosis A

There are historical reports of acute hypervitaminosis from Arctic explorers consuming bearded seal or polar bear liver, both very rich sources of stored retinol,[46] and there are also case reports of acute hypervitaminosis from consuming fish liver,[47] but otherwise there is no risk from consuming too much via commonly consumed foods. Only consumption of retinol-containing dietary supplements can result in acute or chronic toxicity.[5] Acute toxicity occurs after a single or short-term doses of greater than 150,000 μg. Symptoms include blurred vision, nausea, vomiting, dizziness and headache within 8 to 24 hours. For infants ages 0–6 months given an oral dose to prevent development of vitamin A deficiency, bulging skull fontanel was evident after 24 hours, usually resolved by 72 hours.[48] Chronic toxicity may occur with long-term consumption of vitamin A at doses of 25,000–33,000 IU/day for several months.[3] Excessive consumption of alcohol can lead to chronic toxicity at lower intakes.[2] Symptoms may include nervous system effects, liver abnormalities, fatigue, muscle weakness, bone and skin changes and others. The adverse effects of both acute and chronic toxicity are reversed after consumption is stopped.[4]

In 2001, for the purpose of determining ULs for adults, the US Institute of Medicine considered three primary adverse effects and settled on two: teratogenicity, i.e., causing birth defects, and liver abnormalities. Reduced bone mineral density was considered, but dismissed because the human evidence was contradictory.[4] During pregnancy, especially during the first trimester, consumption of retinol in amounts exceeding 4,500 μg/day increased the risk of birth defects, but not below that amount, thus setting a "No-Observed Adverse-Effect Level" (NOAEL). Given the quality of the clinical trial evidence, the NOAEL was divided by an uncertainty factor of 1.5 to set the UL for women of reproductive age at 3,000 μg/day of preformed vitamin A. For all other adults, liver abnormalities were detected at intakes above 14,000 μg/day. Given the weak quality of the clinical evidence, an uncertainty factor of 5 was used, and with rounding, the UL was set at 3,000 μg/day. Despite a US UL set at 3,000 μg, it is possible to buy over-the-counter dietary supplement products which are 7,500 μg (25,000 IU), with a label caution statement "Not intended for long term use unless under medical supervision."[49]

For children, ULs were extrapolated from the adult value, adjusted for relative body weight. For infants, several case studies reported adverse effects that include bulging fontanels, increased intracranial pressure, loss of appetite, hyperirritability and skin peeling after chronic ingestion of the order of 6,000 or more μg/day. Given the small database, an uncertainty factor of 10 divided into the "Lowest-Observed-Adverse-Effect Level" (LOAEL) led to a UL of 600 μg/day.[4]

β-carotene safety edit

No adverse effects other than carotenemia have been reported for consumption of β-carotene rich foods. Supplementation with β-carotene does not cause hypervitaminosis A.[11] Two large clinical trials (ATBC and CARET) were conducted in tobacco smokers to see if years of β-carotene supplementation at 20 or 30 mg/day in oil-filled capsules would reduce the risk of lung cancer.[50] These trials were implemented because observational studies had reported a lower incidence of lung cancer in tobacco smokers who had diets higher in β-carotene. Unexpectedly, this high-dose β-carotene supplementation resulted in a higher incidence of lung cancer and of total mortality.[11] Taking this and other evidence into consideration, the U.S. Institute of Medicine decided not to set a Tolerable Upper Intake Level (UL) for β-carotene.[11][50] The European Food Safety Authority, acting for the European Union, also decided not to set a UL for β-carotene.[45]

 
Carrots are a rich source of beta-carotene

Carotenosis edit

Carotenoderma, also referred to as carotenemia, is a benign and reversible medical condition where an excess of dietary carotenoids results in orange discoloration of the outermost skin layer. It is associated with a high blood β-carotene value. This can occur after a month or two of consumption of beta-carotene rich foods, such as carrots, carrot juice, tangerine juice, mangos, or in Africa, red palm oil. β-carotene dietary supplements can have the same effect. The discoloration extends to palms and soles of feet, but not to the white of the eye, which helps distinguish the condition from jaundice.[51] Consumption of greater than 30 mg/day for a prolonged period has been confirmed as leading to carotenemia.[11][52]

U.S. labeling edit

For U.S. food and dietary supplement labeling purposes, the amount in a serving is expressed as a percent of Daily Value (%DV). For vitamin A labeling purposes 100% of the Daily Value was set at 5,000 IU, but it was revised to 900 μg RAE on 27 May 2016.[53][54] A table of the old and new adult daily values is provided at Reference Daily Intake.

Sources edit

Food

μg RAE (2001)[4] per 100 g[55]

cod liver oil 30,000
beef liver (cooked) 4,970 — 21,145
chicken liver (cooked) 4,296
butter (stick) 684
cheddar cheese 316
egg (cooked) 140

Vitamin A is found in many foods.[55] Vitamin A in food exists either as preformed retinol – an active form of vitamin A – found in animal liver, dairy and egg products, and some fortified foods, or as provitamin A carotenoids, which are plant pigments digested into vitamin A after consuming carotenoid-rich plant foods, typically in red, orange, or yellow colors.[3] Carotenoid pigments may be masked by chlorophylls in dark green leaf vegetables, such as spinach. The relatively low bioavailability of plant-food carotenoids results partly from binding to proteins – chopping, homogenizing or cooking disrupts the plant proteins, increasing provitamin A carotenoid bioavailability.[3]

Vegetarian and vegan diets can provide sufficient vitamin A in the form of provitamin A carotenoids if the diet contains carrots, carrot juice, sweet potatoes, green leafy vegetables such as spinach and kale, and other carotenoid-rich foods. In the U.S., the average daily intake of β-carotene is in the range 2–7 mg.[56]

Some manufactured foods and dietary supplements are sources of vitamin A or beta-carotene.[3][4]

Despite the US setting an adult upper limit of 3,000 μg/day, some companies sell vitamin A as a dietary supplement with amounts of 7,500 μg/day. Two examples are WonderLabs and Pure Prescriptions.[57][58]

Fortification edit

Some countries require or recommend fortification of foods. As of January 2022, 37 countries, mostly in Sub-Saharan Africa, require food fortification of cooking oil, rice, wheat flour or maize (corn) flour with vitamin A, usually as retinyl palmitate or retinyl acetate. Examples include Pakistan, oil, 11.7 mg/kg and Nigeria, oil, 6 mg/kg; wheat and maize flour, 2 mg/kg.[59] An additional 12 countries, mostly in southeast Asia, have a voluntary fortification program. For example, the government of India recommends 7.95 mg/kg in oil and 0.626 mg/kg for wheat flour and rice. However, compliance in countries with voluntary fortification is lower than countries with mandatory fortification.[59] No countries in Europe or North America fortify foods with vitamin A.[59]

Food

μg RAE (2001)[4] per 100 g[55]

Sweet potato, baked, no added fat 957
Carrot, frozen, cooked, no added fat 843
Pumpkin, canned, cooked 767
Spinach, fresh, cooked, no added fat 341
Kale, fresh, cooked, no added fat 245

Separated from fortification via addition of synthetic vitamin A to foods, means of fortifying foods via genetic engineering have been explored. Research on rice began in 1982.[60] The first field trials of golden rice cultivars were conducted in 2004.[61] The result was "Golden Rice", a variety of Oryza sativa rice produced through genetic engineering to biosynthesize beta-carotene, a precursor of retinol, in the edible parts of rice.[62][63] In May 2018, regulatory agencies in the United States, Canada, Australia and New Zealand had concluded that Golden Rice met food safety standards.[64] On 21 July 2021, the Philippines became the first country to officially issue the biosafety permit for commercially propagating Golden Rice.[65][66] However, in April 2023, the Supreme Court of the Philippines issued a Writ of Kalikasan ordering the Department of Agriculture to stop the commercial distribution of genetically modified rice in the country.[67]

Vitamin A supplementation (VAS) edit

 
Vitamin A supplementation coverage rate (children ages 6–59 months), 2014[68]

Delivery of oral high-dose supplements remains the principal strategy for minimizing deficiency.[69] As of 2017, more than 80 countries worldwide are implementing universal VAS programs targeted to children 6–59 months of age through semi-annual national campaigns.[70] Doses in these programs are one dose of 50,000 or 100,000 IU for children aged 6 to 11 months and 100,000 to 200,000 IU for children aged 12 months to five years, every four to six months.[22]

Deficiency edit

Main article: Vitamin A deficiency

Primary causes edit

Vitamin A deficiency is common in developing countries, especially in Sub-Saharan Africa and Southeast Asia. Deficiency can occur at any age, but is most common in pre-school-age children and pregnant women, the latter due to a need to transfer retinol to the fetus. The causes are low intake of retinol-containing, animal-sourced foods and low intake of carotene-containing, plant-sourced foods. Vitamin A deficiency is estimated to affect approximately one third of children under the age of five around the world,[71] possibly leading to the deaths of 670,000 children under five annually.[72]

Between 250,000 and 500,000 children in developing countries become blind each year owing to vitamin A deficiency.[2] Vitamin A deficiency is "the leading cause of preventable childhood blindness", according to UNICEF.[9][73] It also increases the risk of death from common childhood conditions, such as diarrhea. UNICEF regards addressing vitamin A deficiency as critical to reducing child mortality, the fourth of the United Nations' Millennium Development Goals.[9]

During diagnosis, night blindness and dry eyes are signs of vitamin A deficiency that can be recognized without requiring biochemical tests. Plasma retinol is used to confirm vitamin A status. A plasma concentration of about 2.0 μmol/L is normal; less than 0.70 μmol/L (equivalent to 20 μg/dL) indicates moderate vitamin A deficiency, and less than 0.35 μmol/L (10 μg/dL) indicates severe vitamin A deficiency. Breast milk retinol of less than 8 μg/gram milk fat is considered insufficient.[5] One weakness of these measures is that they are not good indicators of liver vitamin A stores as retinyl esters in hepatic stellate cells. The amount of vitamin A leaving the liver, bound to retinol binding protein (RBP), is under tight control as long as there are sufficient liver reserves. Only when liver content of vitamin A drops below approximately 20 μg/gram will concentration in the blood decline.[4][74]

Secondary causes edit

There are causes for deficiency other than low dietary intake of vitamin A as retinol or carotenes. Adequate dietary protein and caloric energy are needed for a normal rate of synthesis of RBP, without which, retinol cannot be mobilized to leave the liver. Systemic infections can cause transient decreases in RBP synthesis even if protein-calorie malnutrition is absent. Chronic alcohol consumption reduces liver vitamin A storage.[4] Non-alcoholic fatty liver disease (NAFLD), characterized by the accumulation of fat in the liver, is the hepatic manifestation of metabolic syndrome. Liver damage from NAFLD reduces liver storage capacity for retinol and reduces the ability to mobilize liver stores to maintain normal circulating concentration.[75]

Animal requirements edit

All vertebrate and chordate species require vitamin A,[26] either as dietary carotenoids or preformed retinol from consuming other animals. Deficiencies have been reported in laboratory-raised and pet dogs, cats, birds, reptiles and amphibians,[76][77] also commercially raised chickens and turkeys.[78] Herbivore species such as horses, cattle and sheep can get sufficient β-carotene from green pasture to be healthy, but the content in pasture grass dry due to drought and long-stored hay can be too low, leading to vitamin A deficiency.[76] Omnivore and carnivore species, especially those toward the top of the food chain, can accrue large amounts of retinyl esters in their livers, or else excrete retinyl esters in urine as a means of dealing with surplus.[15] Before the era of synthetic retinol, cod liver oil, high in vitamins A and D, was a commonly consumed dietary supplement.[79][80] Invertebrates cannot synthesize carotenoids or retinol, and thus must accrue these essential nutrients from consumption of algae, plants or animals.[81][82][83]

Medical uses edit

Preventing and treating deficiency edit

Main article: Vitamin A deficiency

Recognition of its prevalence and consequences has led to governments and non-government organizations promoting vitamin A fortification of foods[59] and creating programs that administer large bolus-size oral doses of vitamin A to young children every four to six months.[70] In 2008, the World Health Organization estimated that vitamin A supplementation over a decade in 40 countries averted 1.25 million deaths due to vitamin A deficiency.[84] A Cochrane review reported that vitamin A supplementation is associated with a clinically meaningful reduction in morbidity and mortality in children ages six month to five years of age. All-cause mortality was reduced by 14%, and incidences[spelling?] of diarrhea by 12%.[22] However, a Cochrane review by the same group concluded there was insufficient evidence to recommend blanket vitamin A supplementation for infants one to six months of age, as it did not reduce infant mortality or morbidity.[48]

Oral retinoic acid edit

Orally consumed retinoic acid (RA), as all-trans-tretinoin or 13-cis-isotretinoin has been shown to improve facial skin health by switching on genes and differentiating keratinocytes (immature skin cells) into mature epidermal cells. RA reduces the size and secretion of the sebaceous glands, and by doing so reduces bacterial numbers in both the ducts and skin surface. It reduces inflammation via inhibition of chemotactic responses of monocytes and neutrophils. In the US, isotretinoin was released to the market in 1982 as a revolutionary treatment for severe and refractory acne vulgaris. It was shown that a dose of 0.5‑1.0 mg/kg body weight/day is enough to produce a reduction in sebum excretion by 90% within a month or two, but the recommended treatment duration is 4 to 6 months.[30] Isotretinoin is a known teratogen, with an estimated 20‑35% risk of physical birth defects to infants that are exposed to isotretinoin in utero, including numerous congenital defects such as craniofacial defects, cardiovascular and neurological malformations or thymic disorders. Neurocognitive impairments in the absence of any physical defects has been established to be 30‑60%. For these reasons, physician- and patient-education programs were initiated, recommending that for women of child-bearing age, contraception be initiated a month before starting oral (or topical) isotretinoin, and continue for a month after treatment ended.[30]

In addition to the approved use for treating acne vulgaris, researchers have investigated off-label applications for dermatological conditions, such as rosacea, psoriasis, and other conditions.[85] Rosacea was reported as responding favorably to doses lower than used for acne. Isotretinoin in combination with ultraviolet light was shown affective for treating psoriasis. Isotretinoin in combination with injected interferon-alpha showed some potential for treating genital warts. Isotretinoin in combination with topical fluorouracil or injected interferon-alpha showed some potential for treating precancerous skin lesions and skin cancer.[85]

Topical retinoic acid and retinol edit

 
Retinoids: Tretinoin is all-trans-retinoic acid; initial tradename: Retin-A. Isotretinoin is 13-cis-retinoic acid; initial tradename: Accutane. Etretinate and Acitretin, its non-esterified metabolite, are used orally to treat severe psoriasis.[12]

Retinoic acids tretinoin (all-trans-retinoic acid) and isotretinoin (13-cis-retinoic acid) are prescription topical medications used to treat moderate to severe cystic acne and acne not responsive to other treatments.[86][87][88][89] These are usually applied as a skin cream to the face after cleansing to remove make-up and skin oils. Tretinoin and isotretinoin act by binding to two nuclear receptor families within keratinocytes: the retinoic acid receptors (RAR) and the retinoid X receptors (RXR).[90] These events contribute to the normalization of follicular keratinization and decreased cohesiveness of keratinocytes, resulting in reduced follicular occlusion and microcomedone formation.[91] The retinoid-receptor complex competes for coactivator proteins of AP-1, a key transcription factor involved in inflammation.[90] Retinoic acid products also reduce sebum secretion, a nutrient source for bacteria, from facial pores.[citation needed]

These drugs are US-designated Pregnancy Category C (animal reproduction studies have shown an adverse effect on the fetus), and should not be used by pregnant women or women who are anticipating becoming pregnant.[31] Many countries established a physician- and patient- education pregnancy prevention policy.[92]

Trifarotene is a prescription retinoid for the topical treatment acne vulgaris.[13] It functions as a retinoic acid receptor (RAR)-γ agonist.[93]

Non-prescription topical products that have health claims for reducing facial acne, combating skin dark spots and reducing wrinkles and lines associated with aging often contain retinyl palmitate. The hypothesis is that this is absorbed and desterified to free retinol, then converted to retinaldehyde and further metabolized to all-trans-retinoic acid, whence it will have the same effects as prescription products with fewer side effects.[94] There is some ex vivo evidence with human skin that esterified retinol is absorbed and then converted to retinol.[95] In addition to esterified retinol, some of these products contain hydroxypinacolone retinoate, identified as esterified 9-cis-retinoic acid.[96]

Synthesis edit

Biosynthesis edit

Carotenoid synthesis takes place in plants, certain fungi, and bacteria. Structurally carotenes are tetraterpenes, meaning that they are synthesized biochemically from four 10-carbon terpene units, which in turn were formed from eight 5-carbon isoprene units. Intermediate steps are the creation of a 40-carbon phytoene molecule, conversion to lycopene via desaturation, and then creation of ionone rings at both ends of the molecule. β-carotene has a β-ionone ring at both ends, meaning that the molecule can be divided symmetrically to yield two retinol molecules. α-Carotene has a β-ionone ring at one end and an Ɛ-ionone ring at the other, so it has half the retinol conversion capacity.[11]

 
Vitamin A biosynthesis from β-carotene

In most animal species, retinol is synthesized from the breakdown of the plant-formed provitamin, β-carotene. First, the enzyme beta-carotene 15,15'-dioxygenase (BCO-1) cleaves β-carotene at the central double bond, creating an epoxide. This epoxide is then attacked by water creating two hydroxyl groups in the center of the structure. The cleavage occurs when these alcohols are oxidized to the aldehydes using NAD+. The resultant retinal is then quickly reduced to retinol by the enzyme retinol dehydrogenase.[5] Omnivore species such as dogs, wolves, coyotes and foxes in general are low producers of BCO-1. The enzyme is lacking in felids (cats), meaning that vitamin A requirements are met from the retinyl ester content of prey animals.[15]

Industrial synthesis edit

 
β-ionone ring

β-carotene can be extracted from fungus Blakeslea trispora, marine algae Dunaliella salina or genetically modified yeast Saccharomyces cerevisiae, starting with xylose as a substrate.[97] Chemical synthesis uses either a method developed by BASF[98][99] or a Grignard reaction utilized by Hoffman-La Roche.[100]

The world market for synthetic retinol is primarily for animal feed, leaving approximately 13% for a combination of food, prescription medication and dietary supplement use.[101] Industrial methods for the production of retinol rely on chemical synthesis. The first industrialized synthesis of retinol was achieved by the company Hoffmann-La Roche in 1947. In the following decades, eight other companies developed their own processes. β-ionone, synthesized from acetone, is the essential starting point for all industrial syntheses. Each process involves elongating the unsaturated carbon chain.[101] Pure retinol is extremely sensitive to oxidization and is prepared and transported at low temperatures and oxygen-free atmospheres. When prepared as a dietary supplement or food additive, retinol is stabilized as the ester derivatives retinyl acetate or retinyl palmitate. Prior to 1999, three companies, Roche, BASF and Rhone-Poulenc controlled 96% of global vitamin A sales. In 2001, the European Commission imposed total fines of 855.22 million euros on these and five other companies for their participation in eight distinct market-sharing and price-fixing cartels that dated back to 1989.[102] Roche sold its vitamin division to DSM in 2003. DSM and BASF have the major share of industrial production.[101] A biosynthesis alternative utilizes genetically engineered yeast species Saccharomyces cerevisiae to synthesize retinal and retinol, using xylose as a starting substrate. This was accompished by having the yeast first synthesize β-carotene and then the cleaving enzyme β-carotene 15,15'-dioxygenase to yield retinal.[103]

Research edit

Brain edit

Animal research (on mice), which is pre-clinical, also found Retinoid acid, the bioactive metabolite of vitamin A, to have an effect on brain areas responsible for memory and learning.[104]

Cancer edit

Meta-analyses of intervention and observational trials for various types of cancer report mixed results. Supplementation with β-carotene did not appear to decrease the risk of cancer overall, nor specific cancers including: pancreatic, colorectal, prostate, breast, melanoma, or skin cancer generally.[105] High-dose β-carotene supplementation unexpectedly resulted in a higher incidence of lung cancer and of total mortality in people who were cigarette smokers.[11]

For dietary retinol, no effects were observed for high dietary intake and breast cancer survival,[106] risk of liver cancer,[107] risk of bladder cancer[108] or risk of colorectal cancer,[109][110] although the last review did report lower risk for higher beta-carotene consumption.[110] In contrast, an inverse association was reported between retinol intake and relative risk of esophageal cancer,[111] gastric cancer,[112] ovarian cancer,[113] pancreatic cancer,[114] lung cancer,[115] melanoma,[116] and cervical cancer.[117] For lung cancer, an inverse association was also seen for beta-carotene intake, separate from the retinol results.[115] When high dietary intake was compared to low dietary intake, the decreases in relative risk were in the range of 15 to 20%. For gastric cancer, a meta-analysis of prevention trials reported a 29% decrease in relative risk from retinol supplementation at 1500 μg/day.[118]

Fetal alcohol spectrum disorder edit

Fetal alcohol spectrum disorder (FASD), formerly referred to as fetal alcohol syndrome, presents as craniofacial malformations, neurobehavioral disorders and mental disabilities, all attributed to exposing human embryos to alcohol during fetal development.[119][120] The risk of FASD depends on the amount consumed, the frequency of consumption, and the points in pregnancy at which the alcohol is consumed.[121] Ethanol is a known teratogen, i.e., causes birth defects. Ethanol is metabolized by alcohol dehydrogenase enzymes into acetaldehyde.[122][123] The subsequent oxidation of acetaldehyde into acetate is performed by aldehyde dehydrogenase enzymes. Given that retinoic acid (RA) regulates numerous embryonic and differentiation processes, one of the proposed mechanisms for the teratogenic effects of ethanol is a competition for the enzymes required for the biosynthesis of RA from vitamin A. Animal research demonstrates that in the embryo, the competition takes place between acetaldehyde and retinaldehyde for aldehyde dehydrogenase activity. In this model, acetaldehyde inhibits the production of retinoic acid by retinaldehyde dehydrogenase. Ethanol-induced developmental defects can be ameliorated by increasing the levels of retinol, retinaldehyde, or retinaldehyde dehydrogenase. Thus, animal research supports the reduction of retinoic acid activity as an etiological trigger in the induction of FASD.[119][120][124][125]

Malaria edit

Malaria and vitamin A deficiency are both common among young children in sub-Saharan Africa. Vitamin A supplementation to children in regions where vitamin A deficiency is common has repeatedly been shown to reduce overall mortality rates, especially from measles and diarrhea.[126] For malaria, clinical trial results are mixed, either showing that vitamin A treatment did not reduce the incidence of probable malarial fever, or else did not affect incidence, but did reduce slide-confirmed parasite density and reduced the number of fever episodes.[126] The question was raised as to whether malaria causes vitamin A deficiency, or vitamin A deficiency contributes to the severity of malaria, or both. Researchers proposed several mechanisms by which malaria (and other infections) could contribute to vitamin A deficiency, including a fever-induced reduction in synthesis of retinal-binding protein (RBP) responsible for transporting retinol from liver to plasma and tissues, but reported finding no evidence for a transient depression or restoration of plasma RBP or retinol after a malarial infection was eliminated.[126]

In history edit

 
Frederick Gowland Hopkins, 1929 Nobel Prize for Physiology or Medicine

In 1912, Frederick Gowland Hopkins demonstrated that unknown accessory factors found in milk, other than carbohydrates, proteins, and fats were necessary for growth in rats. Hopkins received a Nobel Prize for this discovery in 1929.[6][127] By 1913, one of these substances was independently discovered by Elmer McCollum and Marguerite Davis at the University of Wisconsin–Madison, and Lafayette Mendel and Thomas Burr Osborne at Yale University. McCollum and Davis ultimately received credit because they submitted their paper three weeks before Mendel and Osborne. Both papers appeared in the same issue of the Journal of Biological Chemistry in 1913.[128] The "accessory factors" were termed "fat soluble" in 1918, and later "vitamin A" in 1920. In 1919, Harry Steenbock (University of Wisconsin–Madison) proposed a relationship between yellow plant pigments (beta-carotene) and vitamin A. In 1931, Swiss chemist Paul Karrer described the chemical structure of vitamin A.[127] Retinoic acid and retinol were first synthesized in 1946 and 1947 by two Dutch chemists, David Adriaan van Dorp and Jozef Ferdinand Arens.[129][130]

 
George Wald, 1967 Nobel Prize for Physiology or Medicine

During World War II, German bombers would attack at night to evade British defenses. In order to keep the 1939 invention of a new on-board Airborne Intercept Radar system secret from Germany, the British Ministry of Information told newspapers an unproven claim that the nighttime defensive success of Royal Air Force pilots was due to a high dietary intake of carrots rich in beta-carotene, successfully convincing many people.[131]

In 1967, George Wald shared the Nobel Prize in Physiology and Medicine for his work on chemical visual processes in the eye.[132] Wald had demonstrated in 1935 that photoreceptor cells in the eye contain rhodopsin, a chromophore composed of the protein opsin and 11-cis-retinal. When struck by light, 11-cis-retinal undergoes photoisomerization to all-trans-retinal and via signal transduction cascade send a nerve signal to the brain. The all-trans-retinal is reduced to all-trans-retinol and travels back to the retinal pigment epithelium to be recycled to 11-cis-retinal and reconjugated to opsin.[6][133] Wald's work was the culmination of nearly 60 years of research. In 1877, Franz Christian Boll identified a light-sensitive pigment in the outer segments of rod cells of the retina that faded/bleached when exposed to light, but was restored after light exposure ceased. He suggested that this substance, by a photochemical process, conveyed the impression of light to the brain.[6] The research was taken up by Wilhelm Kühne, who named the pigment rhodopsin, also known as "visual purple." Kühne confirmed that rhodopsin is extremely sensitive to light, and thus enables vision in low-light conditions, and that it was this chemical decomposition that stimulated nerve impulses to the brain.[6] Research stalled until after identification of "fat-soluble vitamin A" as a dietary substance found in milkfat but not lard, would reverse night blindness and xerophthalmia. In 1925, Fridericia and Holm demonstrated that vitamin A deficient rats were unable to regenerate rhodopsin after being moved from a light to a dark room.[134]

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November 03, 2023
vitamin, this, article, about, family, vitamers, form, usually, used, supplement, retinol, soluble, vitamin, essential, nutrient, animals, term, vitamin, encompasses, group, chemically, related, organic, compounds, that, includes, retinol, retinal, also, known. This article is about the family of vitamers For the form usually used as a supplement see Retinol Vitamin A is a fat soluble vitamin and an essential nutrient for animals The term vitamin A encompasses a group of chemically related organic compounds that includes retinol retinal also known as retinaldehyde retinoic acid and several provitamin precursor carotenoids most notably beta carotene 2 3 4 5 Vitamin A has multiple functions it is essential for embryo development and growth for maintenance of the immune system and for vision where it combines with the protein opsin to form rhodopsin the light absorbing molecule necessary for both low light scotopic vision and color vision 6 Vitamin ARetinolClinical dataAHFS Drugs comMonographLicense dataUS DailyMed RetinolRoutes ofadministrationby mouth IM 1 Drug classvitaminATC codeA11CA01 WHO D10AD02 WHO R01AX02 WHO S01XA02 WHO Legal statusLegal statusUS OTCIdentifiersIUPAC name 2E 4E 6E 8E 3 7 dimethyl 9 2 6 6 trimethylcyclohex 1 en 1 yl nona 2 4 6 8 tetraen 1 olCAS Number68 26 8mixture 11103 57 4 YPubChem CID1071IUPHAR BPS4053ChemSpider393012UNIIG2SH0XKK91mixture 81G40H8B0T YChEBICHEBI 17336ChEMBLChEMBL986ECHA InfoCard100 031 195Chemical and physical dataFormulaC 20H 30OMolar mass286 459 g mol 13D model JSmol Interactive imageMelting point62 64 C 144 147 F Boiling point137 138 C 279 280 F 10 6 mm Hg SMILES OC C C C C C C C C C C C1 C C CCCC1 C CInChI InChI 1S C20H30O c1 16 8 6 9 17 2 13 15 21 11 12 19 18 3 10 7 14 20 19 4 5 h6 8 9 11 13 21H 7 10 14 15H2 1 5H3 b9 6 12 11 16 8 17 13 YKey FPIPGXGPPPQFEQ OVSJKPMPSA NVitamin A occurs as two principal forms in foods A retinol found in animal sourced foods either as retinol or bound to a fatty acid to become a retinyl ester and B the carotenoids alpha carotene b carotene gamma carotene and the xanthophyll beta cryptoxanthin all of which contain b ionone rings that function as provitamin A in herbivore and omnivore animals which possess the enzymes that cleave and convert provitamin carotenoids to retinal and then to retinol 7 Some carnivore species lack this enzyme The other carotenoids have no vitamin activity 5 Dietary retinol is absorbed from the digestive tract via passive diffusion Unlike retinol b carotene is taken up by enterocytes by the membrane transporter protein scavenger receptor B1 SCARB1 which is upregulated in times of vitamin A deficiency 5 Storage of retinol is in lipid droplets in the liver A high capacity for long term storage of retinol means that well nourished humans can go months on a vitamin A and b carotene deficient diet while maintaining blood levels in the normal range 3 Only when the liver stores are nearly depleted will signs and symptoms of deficiency show 3 Retinol is reversibly converted to retinal then irreversibly to retinoic acid which activates hundreds of genes 8 Vitamin A deficiency is common in developing countries especially in Sub Saharan Africa and Southeast Asia Deficiency can occur at any age but is most common in pre school age children and pregnant women the latter due to a need to transfer retinol to the fetus Vitamin A deficiency is estimated to affect approximately one third of children under the age of five around the world resulting in hundreds of thousands of cases of blindness and deaths from childhood diseases because of immune system failure 9 Reversible night blindness is an early indicator of low vitamin A status Plasma retinol is used as a biomarker to confirm vitamin A deficiency Breast milk retinol can indicate a deficiency in nursing mothers Neither of these measures indicates the status of liver reserves 5 The European Union and various countries have set recommendations for dietary intake and upper limits for safe intake Vitamin A toxicity also referred to as hypervitaminosis A occurs when there is too much vitamin A accumulating in the body Symptoms may include nervous system effects liver abnormalities fatigue muscle weakness bone and skin changes and others The adverse effects of both acute and chronic toxicity are reversed after consumption of high dose supplements is stopped 5 Contents 1 Definition 2 Absorption metabolism and excretion 2 1 Carnivores 2 2 Herbivores 2 3 Activation and excretion 3 Metabolic functions 3 1 Vision and eye health 3 1 1 Vision 3 1 2 Night blindness 3 1 3 Xerophthalmia and childhood blindness 3 2 Gene regulation 3 3 Embryology 3 4 Immune functions 3 5 Skin 4 Units of measurement 5 Dietary recommendations 5 1 Safety 5 1 1 Retinol safety 5 1 2 b carotene safety 5 1 3 Carotenosis 5 2 U S labeling 6 Sources 6 1 Fortification 6 2 Vitamin A supplementation VAS 7 Deficiency 7 1 Primary causes 7 2 Secondary causes 8 Animal requirements 9 Medical uses 9 1 Preventing and treating deficiency 9 2 Oral retinoic acid 9 3 Topical retinoic acid and retinol 10 Synthesis 10 1 Biosynthesis 10 2 Industrial synthesis 11 Research 11 1 Brain 11 2 Cancer 11 3 Fetal alcohol spectrum disorder 11 4 Malaria 12 In history 13 References 14 External linksDefinition editVitamin A is a fat soluble vitamin a category that also includes vitamins D E and K The vitamin encompasses several chemically related naturally occurring compounds or metabolites i e vitamers that all contain a b ionone ring 3 The primary dietary form is retinol which may have a fatty acid molecule attached creating a retinyl ester when stored in the liver Retinol the transport and storage form of vitamin A is interconvertible with retinal catalyzed to retinal by retinol dehydrogenases and back to retinol by retinaldehyde reductases 10 retinal NADPH H retinol NADP retinol NAD retinal NADH H Retinal also known as retinaldehyde can be irreversibly converted to all trans retinoic acid by the action of retinal dehydrogenase retinal NAD H2O retinoic acid NADH H Retinoic acid diffuses into the cell nucleus where it regulates more than 500 genes by binding directly to gene targets via retinoic acid receptors 5 In addition to retinol retinal and retinoic acid there are plant fungi or bacteria sourced carotenoids which can be metabolized to retinol and are thus vitamin A vitamers 11 There are also what are referred to as 2nd 3rd and 4th generation retinoids which are not considered vitamin A vitamers because they cannot be converted to retinol retinal or all trans retinoic acid Some are prescription drugs oral or topical for various indications Examples are etretinate acitretin adapalene bexarotene tazarotene and trifarotene 12 13 Absorption metabolism and excretion editRetinyl esters from animal sourced foods or synthesized for dietary supplements for humans and domesticated animals are acted upon by retinyl ester hydrolases in the lumen of the small intestine to release free retinol Retinol enters intestinal absorptive cells by passive diffusion Absorption efficiency is in the range of 70 to 90 Humans are at risk for acute or chronic vitamin A toxicity because there are no mechanisms to suppress absorption or excrete the excess in urine 4 Within the cell retinol is there bound to retinol binding protein 2 RBP2 It is then enzymatically reesterified by the action of lecithin retinol acyltransferase and incorporated into chylomicrons that are secreted into the lymphatic system Unlike retinol b carotene is taken up by enterocytes by the membrane transporter protein scavenger receptor B1 SCARB1 The protein is upregulated in times of vitamin A deficiency If vitamin A status is in the normal range SCARB1 is downregulated reducing absorption 5 Also downregulated is the enzyme beta carotene 15 15 dioxygenase formerly known as beta carotene 15 15 monooxygenase coded for by the BCMO1 gene responsible for symmetrically cleaving b carotene into retinal 7 Absorbed b carotene is either incorporated as such into chylomicrons or first converted to retinal and then retinol bound to RBP2 After a meal roughly two thirds of the chylomicrons are taken up by the liver with the remainder delivered to peripheral tissues Peripheral tissues also can convert chylomicron b carotene to retinol 5 14 The capacity to store retinol in the liver means that well nourished humans can go months on a vitamin A deficient diet without manifesting signs and symptoms of deficiency Two liver cell types are responsible for storage and release hepatocytes and hepatic stellate cells HSCs Hepatocytes take up the lipid rich chylomicrons bind retinol to retinol binding protein 4 RBP4 and transfer the retinol RBP4 to HSCs for storage in lipid droplets as retinyl esters Mobilization reverses the process retinyl ester hydrolase releases free retinol which is transferred to hepatocytes bound to RBP4 and put into blood circulation Other than either after a meal or when consumption of large amounts exceeds liver storage capacity more than 95 of retinol in circulation is bound to RBP4 14 Carnivores edit Strict carnivores manage vitamin A differently than omnivores and herbivores Carnivores are more tolerant of high intakes of retinol because those species have the ability to excrete retinol and retinyl esters in urine Carnivores also have the ability to store more in the liver due to a higher ratio of liver HSCs to hepatocytes compared to omnivores and herbivores For humans liver content can range from 20 to 30 mg gram wet weight Notoriously polar bear liver is acutely toxic to humans because content has been reported in range of 2 215 to 10 400 mg g wet weight 15 As noted in humans retinol circulates bound to RBP4 Carnivores maintain R RBP4 within a tight range while also having retinyl esters in circulation Bound retinol is delivered to cells while the esters are excreted in the urine 15 In general carnivore species are poor converters of ionone containing carotenoids and pure carnivores such as felidae cats lack the cleaving enzyme entirely They must have retinol or retinyl esters in their diet 15 Herbivores edit Herbivores consume ionone containing carotenoids and convert those to retinal Some species including cattle and horses have measurable amounts of beta carotene circulating in the blood and stored in body fat creating yellow fat cells Most species have white fat and no beta carotene in circulation 15 Activation and excretion edit In the liver and peripheral tissues of humans retinol is reversibly converted to retinal by the action of alcohol dehydrogenases which are also responsible for the conversion of ethanol to acetaldehyde Retinal is irreversibly oxidized to retinoic acid RA by the action of aldehyde dehydrogenases RA regulates the activation or deactivation of genes The oxidative degradation of RA is induced by RA its presence triggers its removal making for a short acting gene transcription signal This deactivation is mediated by a cytochrome P450 CYP enzyme system specifically enzymes CYP26A1 CYP26B1 and CYP26C1 CYP26A1 is the predominant form in the human liver all other human adult tissues contained higher levels of CYP26B1 CYP26C1 is expressed mainly during embryonic development All three convert retinoic acid into 4 oxo RA 4 OH RA and 18 OH RA Glucuronic acid forms water soluble glucuronide conjugates with the oxidized metabolites which are then excreted in urine and feces 8 Metabolic functions editFurther information Vitamin A deficiency Other than for vision the metabolic functions of vitamin A are mediated by all trans retinoic acid RA The formation of RA from retinal is irreversible To prevent accumulation of RA it is oxidized and eliminated fairly quickly i e has a short half life Three cytochromes catalyze the oxidation of retinoic acid The genes for Cyp26A1 Cyp26B1 and Cyp26C1 are induced by high levels of RA providing a self regulating feedback loop 16 17 Vision and eye health edit Vitamin A status involves eye health via two separate functions Retinal is an essential factor in rod cells and cone cells in the retina responding to light exposure by sending nerve signals to the brain An early sign of vitamin A deficiency is night blindness 5 Vitamin A in the form of retinoic acid is essential to normal epithelial cell functions Severe vitamin A deficiency common in infants and young children in southeast Asia causes xerophthalmia characterized by dryness of the conjunctival epithelium and cornea Untreated xerophthalmia progresses to corneal ulceration and blindness 18 Vision edit Main article visual cycle The role of vitamin A in the visual cycle is specifically related to the retinal compound Retinol is converted by the enzyme RPE65 within the retinal pigment epithelium into 11 cis retinal Within the eye 11 cis retinal is bound to the protein opsin to form rhodopsin in rod cells and iodopsin in cone cells As light enters the eye the 11 cis retinal is isomerized to the all trans form The all trans retinal dissociates from the opsin in a series of steps called photo bleaching This isomerization induces a nervous signal along the optic nerve to the visual center of the brain After separating from opsin the all trans retinal is recycled and converted back to the 11 cis retinal form by a series of enzymatic reactions which then completes the cycle by binding to opsin to reform rhodopsin in the retina 5 In addition some of the all trans retinal may be converted to all trans retinol form and then transported with an interphotoreceptor retinol binding protein to the retinal pigmented epithelial cells Further esterification into all trans retinyl esters allow for storage of all trans retinol within the pigment epithelial cells to be reused when needed It is for this reason that a deficiency in vitamin A will inhibit the reformation of rhodopsin and will lead to one of the first symptoms night blindness 5 19 20 Night blindness edit Main article Nyctalopia Vitamin A deficiency VAD caused night blindness is a reversible difficulty for the eyes to adjust to dim light It is common in young children who have a diet inadequate in retinol and beta carotene A process called dark adaptation typically causes an increase in photopigment amounts in response to low levels of illumination This increases light sensitivity by up to 100 000 times compared to normal daylight conditions Significant improvement in night vision takes place within ten minutes but the process can take up to two hours to reach maximal effect 6 People expecting to work in a dark environment wore red tinted goggles or were in a red light environment to not reverse the adaptation because red light does not deplete rhodopsin versus what occurs with yellow or green light 20 Xerophthalmia and childhood blindness edit Main article Xerophthalmia nbsp Typical location of Bitot s spotsXerophthalmia caused by a severe vitamin A deficiency is described by pathologic dryness of the conjunctival epithelium and cornea The conjunctiva becomes dry thick and wrinkled Indicative is the appearance of Bitot s spots which are clumps of keratin debris that build up inside the conjunctiva If untreated xerophthalmia can lead to dry eye syndrome corneal ulceration and ultimately to blindness as a result of cornea and retina damage Although xerophthalmia is an eye related issue prevention and reversal are functions of retinoic acid having been synthesized from retinal rather than the 11 cis retinal to rhodopsin cycle 21 Throughout southeast Asia estimates are that more than half of children under the age of six years have subclinical vitamin A deficiency and night blindness with progression to xerophthalmia being the leading cause of preventable childhood blindness 21 Estimates are that each year there are 350 000 cases of childhood blindness due to vitamin A deficiency 18 The causes are vitamin A deficiency during pregnancy followed by low transfer of vitamin A during lactation and infant child diets low in vitamin A or beta carotene 21 18 The prevalence of pre school age children who are blind due to vitamin A deficiency is lower than expected from incidence of new cases only because childhood vitamin A deficiency significantly increases all cause mortality 18 According to a 2017 Cochrane review vitamin A deficiency using serum retinol less than 0 70 µmol L as a criterion is a major public health problem affecting an estimated 190 million children under five years of age in low and middle income countries primarily in Sub Saharan Africa and Southeast Asia In lieu of or in combination with food fortification programs many countries have implemented public health programs in which children are periodically given very large oral doses of synthetic vitamin A usually retinyl palmitate as a means of preventing and treating VAD Doses were 50 000 to 100 000 IU International units for children aged 6 to 11 months and 100 000 to 200 000 IU for children aged 12 months to five years the latter typically every four to six months In addition to a 24 reduction in all cause mortality eye related results were reported Prevalence of Bitot s spots at follow up were reduced by 58 night blindness by 68 xerophthalmia by 69 22 Gene regulation edit RA regulates gene transcription by binding to nuclear receptors known as retinoic acid receptors RARs RARa RARb RARg which are bound to DNA as heterodimers with retinoid X receptors RXRs RXRa RXRb RXRg RARs and RXRs must dimerize before they can bind to the DNA Expression of more than 500 genes is responsive to retinoic acid 5 The process is that RAR RXR heterodimers recognize retinoic acid response elements on DNA 23 The receptors undergo a conformational change that causes co repressors to dissociate from the receptors Coactivators can then bind to the receptor complex which may help to loosen the chromatin structure from the histones or may interact with the transcriptional machinery 24 This response upregulates or downregulates the expression of target genes including the genes that encode for the receptors themselves 19 To prevent excess accumulation of RA it must be metabolized and eliminated Three cytochromes Cyp26A1 Cyp26B1 Cyp26C1 catalyze the oxidation of RA The genes for these proteins are induced by high concentrations of RA thus providing a regulatory feedback mechanism 5 Embryology edit In vertebrates and invertebrate chordates RA has a pivotal role during development Altering levels of endogenous RA signaling during early embryology both too low and too high leads to birth defects 25 26 including congenital vascular and cardiovascular defects 27 28 Of note fetal alcohol spectrum disorder encompasses congenital anomalies including craniofacial auditory and ocular defects neurobehavioral anomalies and mental disabilities caused by maternal consumption of alcohol during pregnancy It is proposed that in the embryo there is competition between acetaldehyde an ethanol metabolite and retinaldehyde retinal for aldehyde dehydrogenase activity resulting in a retenoic acid deficiency and attributing the congenital birth defects to the loss of RA activated gene activation In support of this theory ethanol induced developmental defects can be ameliorated by increasing the levels of retinol or retinal 29 As for the risks of too much RA the prescription drugs tretinoin all trans retinoic acid and isotretinoin 13 cis retinoic acid used orally or topically for acne treatment come with warnings to not be used by pregnant women or women who are anticipating becoming pregnant as they are known human teratogens 30 31 Immune functions edit Vitamin A deficiency VAD has been linked to compromised resistance to infectious diseases 32 33 In countries where early childhood VAD is common vitamin A supplementation public health programs initiated in the 1980s were shown to reduce the incidence of diarrhea and measles and all cause mortality 22 34 35 VAD also increases the risk of immune system over reaction leading to chronic inflammation in the intestinal system stronger allergic reactions and autoimmune diseases 32 33 36 Lymphocytes and monocytes are types of white blood cells of the immune system 37 Lymphocytes include natural killer cells which function in innate immunity T cells for adaptive cellular immunity and B cells for antibody driven adaptive humoral immunity Monocytes differentiate into macrophages and dendritic cells Some lymphocytes migrate to the thymus where they differentiate into several types of T cells in some instances referred to as killer or helper T cells and further differentiate after leaving the thymus Each subtype has functions driven by the types of cytokines secreted and organs to which the cells preferentially migrate also described as trafficking or homing 38 39 Reviews based on in vitro and animal research describe the role that retinoic acid RA has in the immune system RA triggers receptors in bone marrow resulting in generation of new white blood cells 40 RA regulates proliferation and differentiation of white blood cells the directed movement of T cells to the intestinal system and to the up and down regulation of lymphocyte function 32 33 34 35 36 41 If RA is adequate T helper cell subtype Th1 is suppressed and subtypes Th2 Th17 and iTreg for regulatory are induced Dendritic cells located in intestinal tissue have enzymes that convert retinal to all trans retinoic acid to be taken up by retinoic acid receptors on lymphocytes The process triggers gene expression that leads to T cell types Th2 Th17 and iTreg moving to and taking up residence in mesenteric lymph nodes and Peyer s patches respectively outside and on the inner wall of the small intestine 34 35 The net effect is a down regulation of immune activity seen as tolerance of food allergens and tolerance of resident bacteria and other organisms in the microbiome of the large intestine 32 33 36 In a vitamin A deficient state innate immunity is compromised and pro inflammatory Th1 cells predominate 32 41 Skin edit Deficiencies in vitamin A have been linked to an increased susceptibility to skin infection and inflammation 42 Vitamin A appears to modulate the innate immune response and maintains homeostasis of epithelial tissues and mucosa through its metabolite retinoic acid RA As part of the innate immune system toll like receptors in skin cells respond to pathogens and cell damage by inducing a pro inflammatory immune response which includes increased RA production 42 The epithelium of the skin encounters bacteria fungi and viruses Keratinocytes of the epidermal layer of the skin produce and secrete antimicrobial peptides AMPs Production of AMPs resistin and cathelicidin are promoted by RA 42 Units of measurement editAs some carotenoids can be converted into vitamin A attempts have been made to determine how much of them in the diet is equivalent to a particular amount of retinol so that comparisons can be made of the benefit of different foods The situation can be confusing because the accepted equivalences have changed over timeFor many years a system of equivalencies in which an international unit IU was equal to 0 3 mg of retinol 1 nmol 0 6 mg of b carotene or 1 2 mg of other provitamin A carotenoids was used 43 This relationship was alternatively expressed by the retinol equivalent RE one RE corresponded to 1 mg retinol to 2 mg b carotene dissolved in oil to 6 mg b carotene in foods and to 12 mg of either a carotene g carotene or b cryptoxanthin in food Newer research has shown that the absorption of provitamin A carotenoids is only half as much as previously thought As a result in 2001 the US Institute of Medicine recommended a new unit the retinol activity equivalent RAE Each mg RAE corresponds to 1 mg retinol 2 mg of b carotene in oil 12 mg of dietary beta carotene or 24 mg of the three other dietary provitamin A carotenoids 4 Substance and its chemical environment per 1 mg IU 1989 mg RE 1989 4 mg RAE 2001 4 Retinol 3 33 1 1beta Carotene dissolved in oil 1 67 1 2 1 2beta Carotene common dietary 1 67 1 6 1 12alpha Carotene common dietary gamma Carotene common dietary beta Cryptoxanthin common dietary 0 83 1 12 1 24Animal models have shown that at the enterocyte cell wall b carotene is taken up by the membrane transporter protein scavenger receptor class B type 1 SCARB1 Absorbed b carotene is converted to retinal and then retinol The first step of the conversion process consists of one molecule of b carotene cleaved by the enzyme b carotene 15 15 monooxygenase which in humans and other mammalian species is encoded by the BCM01 gene 7 into two molecules of retinal When plasma retinol is in the normal range gene expression for SCARB1 and BC01 are suppressed creating a feedback loop that suppresses b carotene absorption and conversion 11 Absorption suppression is not complete as receptor 36 is not downregulated 11 Dietary recommendations editThe US National Academy of Medicine updated Dietary Reference Intakes DRIs in 2001 for vitamin A which included Recommended Dietary Allowances RDAs 4 For infants up to 12 months there was not sufficient information to establish a RDA so Adequate Intake AI is shown instead As for safety tolerable upper intake levels ULs were also established For ULs carotenoids are not added when calculating total vitamin A intake for safety assessments 4 Life stage group US RDAs or AIs mg RAE day 4 US Upper limits mg day 4 Infants 0 6 months 400 AI 6007 12 months 500 AI 600Children 1 3 years 300 6004 8 years 400 900Males 9 13 years 600 170014 18 years 900 2800 gt 19 years 900 3000Females 9 13 years 600 170014 18 years 700 2800 gt 19 years 700 3000Pregnancy lt 19 years 750 2800 gt 19 years 770 3000Lactation lt 19 years 1200 2800 gt 19 years 1300 3000The European Food Safety Authority EFSA refers to the collective set of information as Dietary Reference Values with Population Reference Intake PRI instead of RDA and Average Requirement instead of EAR AI and UL defined the same as in United States For women and men of ages 15 and older the PRIs are set respectively at 650 and 750 mg RE day PRI for pregnancy is 700 mg RE day for lactation 1300 day For children of ages 1 14 years the PRIs increase with age from 250 to 600 mg RE day These PRIs are similar to the US RDAs 44 The EFSA reviewed the same safety question as the United States and set ULs at 800 for ages 1 3 1100 for ages 4 6 1500 for ages 7 10 2000 for ages 11 14 2600 for ages 15 17 and 3000 mg day for ages 18 and older for preformed vitamin A i e not including dietary contributions from carotenoids 45 Safety edit Vitamin A toxicity hypervitaminosis A occurs when too much vitamin A accumulates in the body It comes from consumption of preformed vitamin A but not of carotenoids as conversion of the latter to retinol is suppressed by the presence of adequate retinol Retinol safety edit Main article Hypervitaminosis A There are historical reports of acute hypervitaminosis from Arctic explorers consuming bearded seal or polar bear liver both very rich sources of stored retinol 46 and there are also case reports of acute hypervitaminosis from consuming fish liver 47 but otherwise there is no risk from consuming too much via commonly consumed foods Only consumption of retinol containing dietary supplements can result in acute or chronic toxicity 5 Acute toxicity occurs after a single or short term doses of greater than 150 000 mg Symptoms include blurred vision nausea vomiting dizziness and headache within 8 to 24 hours For infants ages 0 6 months given an oral dose to prevent development of vitamin A deficiency bulging skull fontanel was evident after 24 hours usually resolved by 72 hours 48 Chronic toxicity may occur with long term consumption of vitamin A at doses of 25 000 33 000 IU day for several months 3 Excessive consumption of alcohol can lead to chronic toxicity at lower intakes 2 Symptoms may include nervous system effects liver abnormalities fatigue muscle weakness bone and skin changes and others The adverse effects of both acute and chronic toxicity are reversed after consumption is stopped 4 In 2001 for the purpose of determining ULs for adults the US Institute of Medicine considered three primary adverse effects and settled on two teratogenicity i e causing birth defects and liver abnormalities Reduced bone mineral density was considered but dismissed because the human evidence was contradictory 4 During pregnancy especially during the first trimester consumption of retinol in amounts exceeding 4 500 mg day increased the risk of birth defects but not below that amount thus setting a No Observed Adverse Effect Level NOAEL Given the quality of the clinical trial evidence the NOAEL was divided by an uncertainty factor of 1 5 to set the UL for women of reproductive age at 3 000 mg day of preformed vitamin A For all other adults liver abnormalities were detected at intakes above 14 000 mg day Given the weak quality of the clinical evidence an uncertainty factor of 5 was used and with rounding the UL was set at 3 000 mg day Despite a US UL set at 3 000 mg it is possible to buy over the counter dietary supplement products which are 7 500 mg 25 000 IU with a label caution statement Not intended for long term use unless under medical supervision 49 For children ULs were extrapolated from the adult value adjusted for relative body weight For infants several case studies reported adverse effects that include bulging fontanels increased intracranial pressure loss of appetite hyperirritability and skin peeling after chronic ingestion of the order of 6 000 or more mg day Given the small database an uncertainty factor of 10 divided into the Lowest Observed Adverse Effect Level LOAEL led to a UL of 600 mg day 4 b carotene safety edit No adverse effects other than carotenemia have been reported for consumption of b carotene rich foods Supplementation with b carotene does not cause hypervitaminosis A 11 Two large clinical trials ATBC and CARET were conducted in tobacco smokers to see if years of b carotene supplementation at 20 or 30 mg day in oil filled capsules would reduce the risk of lung cancer 50 These trials were implemented because observational studies had reported a lower incidence of lung cancer in tobacco smokers who had diets higher in b carotene Unexpectedly this high dose b carotene supplementation resulted in a higher incidence of lung cancer and of total mortality 11 Taking this and other evidence into consideration the U S Institute of Medicine decided not to set a Tolerable Upper Intake Level UL for b carotene 11 50 The European Food Safety Authority acting for the European Union also decided not to set a UL for b carotene 45 nbsp Carrots are a rich source of beta caroteneCarotenosis edit Carotenoderma also referred to as carotenemia is a benign and reversible medical condition where an excess of dietary carotenoids results in orange discoloration of the outermost skin layer It is associated with a high blood b carotene value This can occur after a month or two of consumption of beta carotene rich foods such as carrots carrot juice tangerine juice mangos or in Africa red palm oil b carotene dietary supplements can have the same effect The discoloration extends to palms and soles of feet but not to the white of the eye which helps distinguish the condition from jaundice 51 Consumption of greater than 30 mg day for a prolonged period has been confirmed as leading to carotenemia 11 52 U S labeling edit For U S food and dietary supplement labeling purposes the amount in a serving is expressed as a percent of Daily Value DV For vitamin A labeling purposes 100 of the Daily Value was set at 5 000 IU but it was revised to 900 mg RAE on 27 May 2016 53 54 A table of the old and new adult daily values is provided at Reference Daily Intake Sources editFood mg RAE 2001 4 per 100 g 55 cod liver oil 30 000beef liver cooked 4 970 21 145chicken liver cooked 4 296butter stick 684cheddar cheese 316egg cooked 140Vitamin A is found in many foods 55 Vitamin A in food exists either as preformed retinol an active form of vitamin A found in animal liver dairy and egg products and some fortified foods or as provitamin A carotenoids which are plant pigments digested into vitamin A after consuming carotenoid rich plant foods typically in red orange or yellow colors 3 Carotenoid pigments may be masked by chlorophylls in dark green leaf vegetables such as spinach The relatively low bioavailability of plant food carotenoids results partly from binding to proteins chopping homogenizing or cooking disrupts the plant proteins increasing provitamin A carotenoid bioavailability 3 Vegetarian and vegan diets can provide sufficient vitamin A in the form of provitamin A carotenoids if the diet contains carrots carrot juice sweet potatoes green leafy vegetables such as spinach and kale and other carotenoid rich foods In the U S the average daily intake of b carotene is in the range 2 7 mg 56 Some manufactured foods and dietary supplements are sources of vitamin A or beta carotene 3 4 Despite the US setting an adult upper limit of 3 000 mg day some companies sell vitamin A as a dietary supplement with amounts of 7 500 mg day Two examples are WonderLabs and Pure Prescriptions 57 58 Fortification edit Some countries require or recommend fortification of foods As of January 2022 37 countries mostly in Sub Saharan Africa require food fortification of cooking oil rice wheat flour or maize corn flour with vitamin A usually as retinyl palmitate or retinyl acetate Examples include Pakistan oil 11 7 mg kg and Nigeria oil 6 mg kg wheat and maize flour 2 mg kg 59 An additional 12 countries mostly in southeast Asia have a voluntary fortification program For example the government of India recommends 7 95 mg kg in oil and 0 626 mg kg for wheat flour and rice However compliance in countries with voluntary fortification is lower than countries with mandatory fortification 59 No countries in Europe or North America fortify foods with vitamin A 59 Food mg RAE 2001 4 per 100 g 55 Sweet potato baked no added fat 957Carrot frozen cooked no added fat 843Pumpkin canned cooked 767Spinach fresh cooked no added fat 341Kale fresh cooked no added fat 245Separated from fortification via addition of synthetic vitamin A to foods means of fortifying foods via genetic engineering have been explored Research on rice began in 1982 60 The first field trials of golden rice cultivars were conducted in 2004 61 The result was Golden Rice a variety of Oryza sativa rice produced through genetic engineering to biosynthesize beta carotene a precursor of retinol in the edible parts of rice 62 63 In May 2018 regulatory agencies in the United States Canada Australia and New Zealand had concluded that Golden Rice met food safety standards 64 On 21 July 2021 the Philippines became the first country to officially issue the biosafety permit for commercially propagating Golden Rice 65 66 However in April 2023 the Supreme Court of the Philippines issued a Writ of Kalikasan ordering the Department of Agriculture to stop the commercial distribution of genetically modified rice in the country 67 Vitamin A supplementation VAS edit nbsp Vitamin A supplementation coverage rate children ages 6 59 months 2014 68 Delivery of oral high dose supplements remains the principal strategy for minimizing deficiency 69 As of 2017 more than 80 countries worldwide are implementing universal VAS programs targeted to children 6 59 months of age through semi annual national campaigns 70 Doses in these programs are one dose of 50 000 or 100 000 IU for children aged 6 to 11 months and 100 000 to 200 000 IU for children aged 12 months to five years every four to six months 22 Deficiency editMain article Vitamin A deficiency Primary causes edit Vitamin A deficiency is common in developing countries especially in Sub Saharan Africa and Southeast Asia Deficiency can occur at any age but is most common in pre school age children and pregnant women the latter due to a need to transfer retinol to the fetus The causes are low intake of retinol containing animal sourced foods and low intake of carotene containing plant sourced foods Vitamin A deficiency is estimated to affect approximately one third of children under the age of five around the world 71 possibly leading to the deaths of 670 000 children under five annually 72 Between 250 000 and 500 000 children in developing countries become blind each year owing to vitamin A deficiency 2 Vitamin A deficiency is the leading cause of preventable childhood blindness according to UNICEF 9 73 It also increases the risk of death from common childhood conditions such as diarrhea UNICEF regards addressing vitamin A deficiency as critical to reducing child mortality the fourth of the United Nations Millennium Development Goals 9 During diagnosis night blindness and dry eyes are signs of vitamin A deficiency that can be recognized without requiring biochemical tests Plasma retinol is used to confirm vitamin A status A plasma concentration of about 2 0 mmol L is normal less than 0 70 mmol L equivalent to 20 mg dL indicates moderate vitamin A deficiency and less than 0 35 mmol L 10 mg dL indicates severe vitamin A deficiency Breast milk retinol of less than 8 mg gram milk fat is considered insufficient 5 One weakness of these measures is that they are not good indicators of liver vitamin A stores as retinyl esters in hepatic stellate cells The amount of vitamin A leaving the liver bound to retinol binding protein RBP is under tight control as long as there are sufficient liver reserves Only when liver content of vitamin A drops below approximately 20 mg gram will concentration in the blood decline 4 74 Secondary causes edit There are causes for deficiency other than low dietary intake of vitamin A as retinol or carotenes Adequate dietary protein and caloric energy are needed for a normal rate of synthesis of RBP without which retinol cannot be mobilized to leave the liver Systemic infections can cause transient decreases in RBP synthesis even if protein calorie malnutrition is absent Chronic alcohol consumption reduces liver vitamin A storage 4 Non alcoholic fatty liver disease NAFLD characterized by the accumulation of fat in the liver is the hepatic manifestation of metabolic syndrome Liver damage from NAFLD reduces liver storage capacity for retinol and reduces the ability to mobilize liver stores to maintain normal circulating concentration 75 Animal requirements editAll vertebrate and chordate species require vitamin A 26 either as dietary carotenoids or preformed retinol from consuming other animals Deficiencies have been reported in laboratory raised and pet dogs cats birds reptiles and amphibians 76 77 also commercially raised chickens and turkeys 78 Herbivore species such as horses cattle and sheep can get sufficient b carotene from green pasture to be healthy but the content in pasture grass dry due to drought and long stored hay can be too low leading to vitamin A deficiency 76 Omnivore and carnivore species especially those toward the top of the food chain can accrue large amounts of retinyl esters in their livers or else excrete retinyl esters in urine as a means of dealing with surplus 15 Before the era of synthetic retinol cod liver oil high in vitamins A and D was a commonly consumed dietary supplement 79 80 Invertebrates cannot synthesize carotenoids or retinol and thus must accrue these essential nutrients from consumption of algae plants or animals 81 82 83 Medical uses editPreventing and treating deficiency edit Main article Vitamin A deficiency Recognition of its prevalence and consequences has led to governments and non government organizations promoting vitamin A fortification of foods 59 and creating programs that administer large bolus size oral doses of vitamin A to young children every four to six months 70 In 2008 the World Health Organization estimated that vitamin A supplementation over a decade in 40 countries averted 1 25 million deaths due to vitamin A deficiency 84 A Cochrane review reported that vitamin A supplementation is associated with a clinically meaningful reduction in morbidity and mortality in children ages six month to five years of age All cause mortality was reduced by 14 and incidences spelling of diarrhea by 12 22 However a Cochrane review by the same group concluded there was insufficient evidence to recommend blanket vitamin A supplementation for infants one to six months of age as it did not reduce infant mortality or morbidity 48 Oral retinoic acid edit Orally consumed retinoic acid RA as all trans tretinoin or 13 cis isotretinoin has been shown to improve facial skin health by switching on genes and differentiating keratinocytes immature skin cells into mature epidermal cells RA reduces the size and secretion of the sebaceous glands and by doing so reduces bacterial numbers in both the ducts and skin surface It reduces inflammation via inhibition of chemotactic responses of monocytes and neutrophils In the US isotretinoin was released to the market in 1982 as a revolutionary treatment for severe and refractory acne vulgaris It was shown that a dose of 0 5 1 0 mg kg body weight day is enough to produce a reduction in sebum excretion by 90 within a month or two but the recommended treatment duration is 4 to 6 months 30 Isotretinoin is a known teratogen with an estimated 20 35 risk of physical birth defects to infants that are exposed to isotretinoin in utero including numerous congenital defects such as craniofacial defects cardiovascular and neurological malformations or thymic disorders Neurocognitive impairments in the absence of any physical defects has been established to be 30 60 For these reasons physician and patient education programs were initiated recommending that for women of child bearing age contraception be initiated a month before starting oral or topical isotretinoin and continue for a month after treatment ended 30 In addition to the approved use for treating acne vulgaris researchers have investigated off label applications for dermatological conditions such as rosacea psoriasis and other conditions 85 Rosacea was reported as responding favorably to doses lower than used for acne Isotretinoin in combination with ultraviolet light was shown affective for treating psoriasis Isotretinoin in combination with injected interferon alpha showed some potential for treating genital warts Isotretinoin in combination with topical fluorouracil or injected interferon alpha showed some potential for treating precancerous skin lesions and skin cancer 85 Topical retinoic acid and retinol edit nbsp Retinoids Tretinoin is all trans retinoic acid initial tradename Retin A Isotretinoin is 13 cis retinoic acid initial tradename Accutane Etretinate and Acitretin its non esterified metabolite are used orally to treat severe psoriasis 12 Retinoic acids tretinoin all trans retinoic acid and isotretinoin 13 cis retinoic acid are prescription topical medications used to treat moderate to severe cystic acne and acne not responsive to other treatments 86 87 88 89 These are usually applied as a skin cream to the face after cleansing to remove make up and skin oils Tretinoin and isotretinoin act by binding to two nuclear receptor families within keratinocytes the retinoic acid receptors RAR and the retinoid X receptors RXR 90 These events contribute to the normalization of follicular keratinization and decreased cohesiveness of keratinocytes resulting in reduced follicular occlusion and microcomedone formation 91 The retinoid receptor complex competes for coactivator proteins of AP 1 a key transcription factor involved in inflammation 90 Retinoic acid products also reduce sebum secretion a nutrient source for bacteria from facial pores citation needed These drugs are US designated Pregnancy Category C animal reproduction studies have shown an adverse effect on the fetus and should not be used by pregnant women or women who are anticipating becoming pregnant 31 Many countries established a physician and patient education pregnancy prevention policy 92 Trifarotene is a prescription retinoid for the topical treatment acne vulgaris 13 It functions as a retinoic acid receptor RAR g agonist 93 Non prescription topical products that have health claims for reducing facial acne combating skin dark spots and reducing wrinkles and lines associated with aging often contain retinyl palmitate The hypothesis is that this is absorbed and desterified to free retinol then converted to retinaldehyde and further metabolized to all trans retinoic acid whence it will have the same effects as prescription products with fewer side effects 94 There is some ex vivo evidence with human skin that esterified retinol is absorbed and then converted to retinol 95 In addition to esterified retinol some of these products contain hydroxypinacolone retinoate identified as esterified 9 cis retinoic acid 96 Synthesis editBiosynthesis edit Carotenoid synthesis takes place in plants certain fungi and bacteria Structurally carotenes are tetraterpenes meaning that they are synthesized biochemically from four 10 carbon terpene units which in turn were formed from eight 5 carbon isoprene units Intermediate steps are the creation of a 40 carbon phytoene molecule conversion to lycopene via desaturation and then creation of ionone rings at both ends of the molecule b carotene has a b ionone ring at both ends meaning that the molecule can be divided symmetrically to yield two retinol molecules a Carotene has a b ionone ring at one end and an Ɛ ionone ring at the other so it has half the retinol conversion capacity 11 nbsp Vitamin A biosynthesis from b caroteneIn most animal species retinol is synthesized from the breakdown of the plant formed provitamin b carotene First the enzyme beta carotene 15 15 dioxygenase BCO 1 cleaves b carotene at the central double bond creating an epoxide This epoxide is then attacked by water creating two hydroxyl groups in the center of the structure The cleavage occurs when these alcohols are oxidized to the aldehydes using NAD The resultant retinal is then quickly reduced to retinol by the enzyme retinol dehydrogenase 5 Omnivore species such as dogs wolves coyotes and foxes in general are low producers of BCO 1 The enzyme is lacking in felids cats meaning that vitamin A requirements are met from the retinyl ester content of prey animals 15 Industrial synthesis edit nbsp b ionone ringb carotene can be extracted from fungus Blakeslea trispora marine algae Dunaliella salina or genetically modified yeast Saccharomyces cerevisiae starting with xylose as a substrate 97 Chemical synthesis uses either a method developed by BASF 98 99 or a Grignard reaction utilized by Hoffman La Roche 100 The world market for synthetic retinol is primarily for animal feed leaving approximately 13 for a combination of food prescription medication and dietary supplement use 101 Industrial methods for the production of retinol rely on chemical synthesis The first industrialized synthesis of retinol was achieved by the company Hoffmann La Roche in 1947 In the following decades eight other companies developed their own processes b ionone synthesized from acetone is the essential starting point for all industrial syntheses Each process involves elongating the unsaturated carbon chain 101 Pure retinol is extremely sensitive to oxidization and is prepared and transported at low temperatures and oxygen free atmospheres When prepared as a dietary supplement or food additive retinol is stabilized as the ester derivatives retinyl acetate or retinyl palmitate Prior to 1999 three companies Roche BASF and Rhone Poulenc controlled 96 of global vitamin A sales In 2001 the European Commission imposed total fines of 855 22 million euros on these and five other companies for their participation in eight distinct market sharing and price fixing cartels that dated back to 1989 102 Roche sold its vitamin division to DSM in 2003 DSM and BASF have the major share of industrial production 101 A biosynthesis alternative utilizes genetically engineered yeast species Saccharomyces cerevisiae to synthesize retinal and retinol using xylose as a starting substrate This was accompished by having the yeast first synthesize b carotene and then the cleaving enzyme b carotene 15 15 dioxygenase to yield retinal 103 Research editBrain edit Animal research on mice which is pre clinical also found Retinoid acid the bioactive metabolite of vitamin A to have an effect on brain areas responsible for memory and learning 104 Cancer edit Meta analyses of intervention and observational trials for various types of cancer report mixed results Supplementation with b carotene did not appear to decrease the risk of cancer overall nor specific cancers including pancreatic colorectal prostate breast melanoma or skin cancer generally 105 High dose b carotene supplementation unexpectedly resulted in a higher incidence of lung cancer and of total mortality in people who were cigarette smokers 11 For dietary retinol no effects were observed for high dietary intake and breast cancer survival 106 risk of liver cancer 107 risk of bladder cancer 108 or risk of colorectal cancer 109 110 although the last review did report lower risk for higher beta carotene consumption 110 In contrast an inverse association was reported between retinol intake and relative risk of esophageal cancer 111 gastric cancer 112 ovarian cancer 113 pancreatic cancer 114 lung cancer 115 melanoma 116 and cervical cancer 117 For lung cancer an inverse association was also seen for beta carotene intake separate from the retinol results 115 When high dietary intake was compared to low dietary intake the decreases in relative risk were in the range of 15 to 20 For gastric cancer a meta analysis of prevention trials reported a 29 decrease in relative risk from retinol supplementation at 1500 mg day 118 Fetal alcohol spectrum disorder edit Fetal alcohol spectrum disorder FASD formerly referred to as fetal alcohol syndrome presents as craniofacial malformations neurobehavioral disorders and mental disabilities all attributed to exposing human embryos to alcohol during fetal development 119 120 The risk of FASD depends on the amount consumed the frequency of consumption and the points in pregnancy at which the alcohol is consumed 121 Ethanol is a known teratogen i e causes birth defects Ethanol is metabolized by alcohol dehydrogenase enzymes into acetaldehyde 122 123 The subsequent oxidation of acetaldehyde into acetate is performed by aldehyde dehydrogenase enzymes Given that retinoic acid RA regulates numerous embryonic and differentiation processes one of the proposed mechanisms for the teratogenic effects of ethanol is a competition for the enzymes required for the biosynthesis of RA from vitamin A Animal research demonstrates that in the embryo the competition takes place between acetaldehyde and retinaldehyde for aldehyde dehydrogenase activity In this model acetaldehyde inhibits the production of retinoic acid by retinaldehyde dehydrogenase Ethanol induced developmental defects can be ameliorated by increasing the levels of retinol retinaldehyde or retinaldehyde dehydrogenase Thus animal research supports the reduction of retinoic acid activity as an etiological trigger in the induction of FASD 119 120 124 125 Malaria edit Malaria and vitamin A deficiency are both common among young children in sub Saharan Africa Vitamin A supplementation to children in regions where vitamin A deficiency is common has repeatedly been shown to reduce overall mortality rates especially from measles and diarrhea 126 For malaria clinical trial results are mixed either showing that vitamin A treatment did not reduce the incidence of probable malarial fever or else did not affect incidence but did reduce slide confirmed parasite density and reduced the number of fever episodes 126 The question was raised as to whether malaria causes vitamin A deficiency or vitamin A deficiency contributes to the severity of malaria or both Researchers proposed several mechanisms by which malaria and other infections could contribute to vitamin A deficiency including a fever induced reduction in synthesis of retinal binding protein RBP responsible for transporting retinol from liver to plasma and tissues but reported finding no evidence for a transient depression or restoration of plasma RBP or retinol after a malarial infection was eliminated 126 In history edit nbsp Frederick Gowland Hopkins 1929 Nobel Prize for Physiology or MedicineIn 1912 Frederick Gowland Hopkins demonstrated that unknown accessory factors found in milk other than carbohydrates proteins and fats were necessary for growth in rats Hopkins received a Nobel Prize for this discovery in 1929 6 127 By 1913 one of these substances was independently discovered by Elmer McCollum and Marguerite Davis at the University of Wisconsin Madison and Lafayette Mendel and Thomas Burr Osborne at Yale University McCollum and Davis ultimately received credit because they submitted their paper three weeks before Mendel and Osborne Both papers appeared in the same issue of the Journal of Biological Chemistry in 1913 128 The accessory factors were termed fat soluble in 1918 and later vitamin A in 1920 In 1919 Harry Steenbock University of Wisconsin Madison proposed a relationship between yellow plant pigments beta carotene and vitamin A In 1931 Swiss chemist Paul Karrer described the chemical structure of vitamin A 127 Retinoic acid and retinol were first synthesized in 1946 and 1947 by two Dutch chemists David Adriaan van Dorp and Jozef Ferdinand Arens 129 130 nbsp George Wald 1967 Nobel Prize for Physiology or MedicineDuring World War II German bombers would attack at night to evade British defenses In order to keep the 1939 invention of a new on board Airborne Intercept Radar system secret from Germany the British Ministry of Information told newspapers an unproven claim that the nighttime defensive success of Royal Air Force pilots was due to a high dietary intake of carrots rich in beta carotene successfully convincing many people 131 In 1967 George Wald shared the Nobel Prize in Physiology and Medicine for his work on chemical visual processes in the eye 132 Wald had demonstrated in 1935 that photoreceptor cells in the eye contain rhodopsin a chromophore composed of the protein opsin and 11 cis retinal When struck by light 11 cis retinal undergoes photoisomerization to all trans retinal and via signal transduction cascade send a nerve signal to the brain The all trans retinal is reduced to all trans retinol and travels back to the retinal pigment epithelium to be recycled to 11 cis retinal and reconjugated to opsin 6 133 Wald s work was the culmination of nearly 60 years of research In 1877 Franz Christian Boll identified a light sensitive pigment in the outer segments of rod cells of the retina that faded bleached when exposed to light but was restored after light exposure ceased He suggested that this substance by a photochemical process conveyed the impression of light to the brain 6 The research was taken up by Wilhelm Kuhne who named the pigment rhodopsin also known as visual purple Kuhne confirmed that rhodopsin is extremely sensitive to light and thus enables vision in low light conditions and that it was this chemical decomposition that stimulated nerve impulses to the brain 6 Research stalled until after identification of fat soluble vitamin A as a dietary substance found in milkfat but not lard would reverse night blindness and xerophthalmia In 1925 Fridericia and Holm demonstrated that vitamin A deficient rats were unable to regenerate rhodopsin after being moved from a light to a dark room 134 References edit a b Vitamin A The American Society of Health System Pharmacists Archived from the original on 30 December 2016 Retrieved 8 December 2016 a b c Vitamin A Fact Sheet for Health Professionals Office of Dietary Supplements US National Institutes of Health March 2021 Retrieved 8 August 2021 a b c d e f g h Vitamin A Micronutrient Information Center Linus Pauling Institute Oregon State University Corvallis 1 July 2016 Retrieved 21 December 2021 a b c d e f g h i j k l m n o p q Institute of Medicine 2001 Vitamin A Dietary Reference Intakes for Vitamin A Vitamin K Arsenic Boron Chromium Copper Iodine Iron Manganese Molybdenum Nickel Silicon Vanadium and Zinc Food and Nutrition Board of the Institute of Medicine pp 82 161 ISBN 0 309 07290 5 a b c d e f g h i j k l m n o p Blaner WS 2020 Vitamin A In BP Marriott DF Birt VA Stallings AA Yates eds Present Knowledge in Nutrition Eleventh Edition London United Kingdom Academic Press Elsevier pp 73 92 ISBN 978 0 323 66162 1 a b c d e f Wolf G June 2001 The discovery of the visual function of vitamin A The Journal of Nutrition 131 6 1647 50 doi 10 1093 jn 131 6 1647 PMID 11385047 a b c Wu L Guo X Wang W Medeiros DM Clarke SL Lucas EA Smith BJ Lin D November 2016 Molecular aspects of b b carotene 9 10 oxygenase 2 in carotenoid metabolism and diseases Exp Biol Med Maywood 241 17 1879 87 doi 10 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and signaling during early organogenesis Cell 134 6 921 31 doi 10 1016 j cell 2008 09 002 PMC 2632951 PMID 18805086 Stipanuk MH 2006 Biochemical Physiological and Molecular Aspects of Human Nutrition 2nd ed Philadelphia Saunders ISBN 9781416002093 Metzler MA Sandell LL December 2016 Enzymatic Metabolism of Vitamin A in Developing Vertebrate Embryos Nutrients 8 12 812 doi 10 3390 nu8120812 PMC 5188467 PMID 27983671 a b Marletaz F Holland LZ Laudet V Schubert M 2006 Retinoic acid signaling and the evolution of chordates Int J Biol Sci 2 2 38 47 doi 10 7150 ijbs 2 38 PMC 1458431 PMID 16733532 Pawlikowski B Wragge J Siegenthaler JA July 2019 Retinoic acid signaling in vascular development Genesis 57 7 8 e23287 doi 10 1002 dvg 23287 PMC 6684837 PMID 30801891 Wang S Moise AR July 2019 Recent insights on the role and regulation of retinoic acid signaling during epicardial development Genesis 57 7 8 e23303 doi 10 1002 dvg 23303 PMC 6682438 PMID 31066193 Shabtai Y Fainsod A April 2018 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PMC 4426035 PMID 25808452 a b c Guo Y Brown C Ortiz C Noelle RJ January 2015 Leukocyte homing fate and function are controlled by retinoic acid Physiol Rev 95 1 125 48 doi 10 1152 physrev 00032 2013 PMC 4281589 PMID 25540140 a b c Bono MR Tejon G Flores Santibanez F Fernandez D Rosemblatt M Sauma D June 2016 Retinoic Acid as a Modulator of T Cell Immunity Nutrients 8 6 349 doi 10 3390 nu8060349 PMC 4924190 PMID 27304965 Janeway C Travers P Walport M Shlomchik M 2001 Immunobiology 5th ed New York and London Garland Science ISBN 0 8153 4101 6 Omman RA Kini AR 2020 Leukocyte development kinetics and functions In Keohane EM Otto CN Walenga JN eds Rodak s Hematology Clinical Principles and Applications 6th ed St Louis Missouri Elsevier pp 117 35 ISBN 978 0 323 53045 3 Cohn L Hawrylowicz C Ray A 2014 Biology of Lymphocytes Middleton s Allergy Principles and Practice 8th ed Philadelphia Saunders pp 203 14 doi 10 1016 B978 0 323 08593 9 00013 9 ISBN 9780323085939 Canete A Cano E Munoz Chapuli R Carmona R February 2017 Role of Vitamin A Retinoic Acid in Regulation of Embryonic and Adult Hematopoiesis Nutrients 9 2 159 doi 10 3390 nu9020159 PMC 5331590 PMID 28230720 a b Czarnewski P Das S Parigi SM Villablanca EJ January 2017 Retinoic Acid and Its Role in Modulating Intestinal Innate Immunity Nutrients 9 1 68 doi 10 3390 nu9010068 PMC 5295112 PMID 28098786 a b c Roche FC Harris Tryon TA January 2021 Illuminating the Role of Vitamin A in Skin Innate Immunity and the Skin Microbiome A Narrative Review Nutrients 13 2 302 doi 10 3390 nu13020302 PMC 7909803 PMID 33494277 Composition of Foods Raw Processed Prepared USDA National Nutrient Database for Standard Reference Release 20 USDA Feb 2008 Overview on Dietary Reference Values for the EU population as derived by the EFSA Panel on Dietetic Products Nutrition and Allergies PDF 2017 a b Tolerable Upper Intake Levels For Vitamins And Minerals PDF European Food Safety Authority 2006 Rodahl K Moore T July 1943 The vitamin A content 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06935 9 PMID 25077263 Archived from the original on 2 September 2017 Retrieved 19 December 2021 Maharshak N Shapiro J Trau H March 2003 Carotenoderma a review of the current literature Int J Dermatol 42 3 178 81 doi 10 1046 j 1365 4362 2003 01657 x PMID 12653910 S2CID 27934066 Nasser Y Jamal Z Albuteaey M 11 August 2021 Carotenemia StatPearls doi 10 1007 s00253 001 0902 7 PMID 30521299 S2CID 22232461 Federal Register May 27 2016 Food Labeling Revision of the Nutrition and Supplement Facts Labels PDF Daily Value Reference of the Dietary Supplement Label Database DSLD Dietary Supplement Label Database DSLD Archived from the original on 7 April 2020 Retrieved 18 December 2021 a b c Rank order of vitamin A content in foods retinol activity equivalent RAE in ug per 100 g FoodData Central US Department of Agriculture 1 October 2021 Retrieved 20 December 2021 USDA National Nutrient Database for Standard Reference Release 28 PDF 28 October 2015 Retrieved 5 February 2022 Vitamin A 25 000 IU 7 500 mg WonderLabs Retrieved 26 January 2022 Vital Nutrients Vitamin A 7 500 RAE Pure Prescriptions Retrieved 26 January 2022 a b c d Total number of nutrients in food vehicles according to a country s fortification standard Global Fortification Data Exchange Retrieved 7 January 2022 FAQ Who invented Golden Rice and how did the project start Goldenrice org LSU AgCenter Communications 2004 Golden Rice Could Help Reduce Malnutrition Archived from the original on 28 September 2007 Kettenburg AJ Hanspach J Abson DJ Fischer J 2018 From disagreements to dialogue unpacking the Golden Rice debate Sustain Sci 13 5 1469 82 doi 10 1007 s11625 018 0577 y PMC 6132390 PMID 30220919 Ye X Al Babili S Kloti A Zhang J Lucca P Beyer P Potrykus I January 2000 Engineering the provitamin A beta carotene biosynthetic pathway into carotenoid free rice endosperm Science 287 5451 303 5 Bibcode 2000Sci 287 303Y doi 10 1126 science 287 5451 303 PMID 10634784 S2CID 40258379 Golden Rice meets food safety standards in three global leading regulatory agencies International Rice Research Institute IRRI Retrieved 30 May 2018 Talavera C Philippines OKs GMO golden rice Philstar com Retrieved 21 August 2021 Filipinos soon to plant and eat Golden Rice Philippine Rice Research Institute 23 July 2021 Retrieved 21 August 2021 Servallos Neil Jayson 20 April 2023 SC issues writ vs GMO golden rice eggplant Philippine Star Retrieved 22 September 2023 Vitamin A supplementation coverage rate children ages 6 59 months Our World in Data Retrieved 6 March 2020 Vitamin A Supplementation A Decade of Progress PDF New York UNICEF 2007 p 3 ISBN 978 92 806 4150 9 Archived from the original PDF on 31 October 2020 Retrieved 23 January 2011 a b Wirth JP Petry N Tanumihardjo SA Rogers LM McLean E Greig A Garrett GS Klemm RD Rohner F February 2017 Vitamin A Supplementation Programs and Country Level Evidence of Vitamin A Deficiency Nutrients 9 3 190 doi 10 3390 nu9030190 PMC 5372853 PMID 28245571 Global prevalence of vitamin 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1997 Vitamine vitamin The early years of discovery Clinical Chemistry 43 4 680 685 doi 10 1093 clinchem 43 4 680 PMID 9105273 Arens JF Van Dorp DA February 1946 Synthesis of some compounds possessing vitamin A activity Nature 157 3981 190 191 Bibcode 1946Natur 157 190A doi 10 1038 157190a0 PMID 21015124 S2CID 27157783 Van Dorp DA Arens JF August 1947 Synthesis of vitamin A aldehyde Nature 159 4058 189 Bibcode 1947Natur 160 189V doi 10 1038 160189a0 PMID 20256189 S2CID 4137483 Luis Villazon Do carrots really help you see in the dark sciencefocus com The Nobel Prize in Physiology or Medicine 1967 Nobel Foundation Archived from the original on 4 December 2013 Retrieved 28 July 2007 Ebrey T Koutalos Y January 2001 Vertebrate photoreceptors Progress in Retinal and Eye Research 20 1 49 94 doi 10 1016 S1350 9462 00 00014 8 PMID 11070368 S2CID 2789591 Fridericia LS Holm E 1925 Experimental contribution to the study of the relation between night blindness and malnutrition Am J Physiol 73 63 78 doi 10 1152 ajplegacy 1925 73 1 63 External links editVitamin A at the U S National Library of Medicine Medical Subject Headings MeSH WHO publications on Vitamin A Deficiency Retrieved from https en wikipedia org w index php title Vitamin A amp oldid 1181131288, wikipedia, wiki, book, books, library,

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