β-Carotene

β-Carotene

Skeletal formula

Ball-and-stick model[1][2]

Space-filling model[1][2]
Names
IUPAC name
β,β-Carotene
Preferred IUPAC name
1,1′-[(1E,3E,5E,7E,9E,11E,13E,15E,17E)-3,7,12,16-Tetramethyloctadeca-1,3,5,7,9,11,13,15,17-nonaene-1,18-diyl]bis(2,6,6-trimethylcyclohex-1-ene)
Other names
Betacarotene (INN), β-Carotene,[3] Food Orange 5, Provitamin A
Identifiers
3D model (JSmol)
3DMet
Beilstein Reference
1917416
ChEBI
ChEMBL
ChemSpider
ECHA InfoCard 100.027.851
EC Number
  • 230-636-6
E number E160a (colours)
KEGG
UNII
CompTox Dashboard (EPA)
  • InChI=1S/C40H56/c1-31(19-13-21-33(3)25-27-37-35(5)23-15-29-39(37,7)8) 17-11-12-18-32(2)20-14-22-34(4)26-28-38-36(6)24-16-30-40(38,9) 10/h11-14,17-22,25-28H,15-16,23-24,29-30H2,1-10H3 N
    Key: OENHQHLEOONYIE-UHFFFAOYSA-N N
  • CC2(C)CCCC(\C)=C2\C=C\C(\C)=C\C=C\C(\C)=C\C=C\C=C(/C)\C=C\C=C(/C)\C=C\C1=C(/C)CCCC1(C)C
Properties
C40H56
Molar mass 536.888 g·mol−1
Appearance Dark orange crystals
Density 1.00 g/cm3[4]
Melting point 183 °C (361 °F; 456 K)[4]
decomposes[5]
Boiling point 654.7 °C (1,210.5 °F; 927.9 K)
at 760 mmHg (101324 Pa)
Insoluble
Solubility Soluble in CS2, benzene, CHCl3, ethanol
Insoluble in glycerin
Solubility in dichloromethane 4.51 g/kg (20 °C)[6] = 5.98 g/L (given BCM density of 1.3266 g/cm3 at 20°C)
Solubility in hexane 0.1 g/L
log P 14.764
Vapor pressure 2.71·10−16 mmHg
1.565
Pharmacology
A11CA02 (WHO) D02BB01 (WHO)
Hazards
GHS labelling:
Warning
Hazard statements
H315, H319, H412
Precautionary statements
P264, P273, P280, P302+P352, P305+P351+P338, P321, P332+P313, P337+P313, P362, P501
NFPA 704 (fire diamond)
0
1
0
Flash point 103 °C (217 °F; 376 K)[5]
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
N verify (what is YN ?)
Infobox references

β-Carotene (beta-carotene) is an organic, strongly coloured red-orange pigment abundant in fungi,[7] plants, and fruits. It is a member of the carotenes, which are terpenoids (isoprenoids), synthesized biochemically from eight isoprene units and thus having 40 carbons. Among the carotenes, β-carotene is distinguished by having beta-rings at both ends of the molecule.[1][2] β-Carotene is biosynthesized from geranylgeranyl pyrophosphate.[8]

In some Mucoralean fungi, β-carotene is a precursor to the synthesis of trisporic acid.[7]

β-carotene is the most common form of carotene in plants. When used as a food coloring, it has the E number E160a.[9]:119 The structure was deduced by Karrer et al. in 1930.[10] In nature, β-carotene is a precursor (inactive form) to vitamin A via the action of beta-carotene 15,15'-monooxygenase.[8]

Isolation of β-carotene from fruits abundant in carotenoids is commonly done using column chromatography. It can also be extracted from the beta-carotene rich algae, Dunaliella salina.[11] The separation of β-carotene from the mixture of other carotenoids is based on the polarity of a compound. β-Carotene is a non-polar compound, so it is separated with a non-polar solvent such as hexane.[12] Being highly conjugated, it is deeply colored, and as a hydrocarbon lacking functional groups, it is very lipophilic.

Provitamin A activity

Plant carotenoids are the primary dietary source of provitamin A worldwide, with β-carotene as the best-known provitamin A carotenoid. Others include α-carotene and β-cryptoxanthin. Carotenoid absorption is restricted to the duodenum of the small intestine. One molecule of β-carotene can be cleaved by the intestinal enzyme β,β-carotene 15,15'-monooxygenase into two molecules of vitamin A.[13][14]

Absorption, metabolism and excretion

As part of the digestive process, food-sourced carotenoids must be separated from plant cells and incorporated into lipid-containing micelles to be bioaccessible to intestinal enterocytes. If already extracted (or synthetic) and then presented in an oil-filled dietary supplement capsule, there is greater bioavailability compared to that from foods.[15] 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 then either incorporated as such into chylomicrons or first converted to retinal and then retinol, bound to retinol binding protein 2, before being incorporated into chylomicrons. The conversion process consists of one molecule of β-carotene cleaved by the enzyme beta-carotene 15,15'-dioxygenase, which is encoded by the BC01 gene, into two molecules of retinal. When plasma retinol is in the normal range the gene expression for SCARB1 and BC01 are suppressed, creating a feedback loop that suppresses β-carotene absorption and conversion.[15] The majority of chylomicrons are taken up by the liver, then secreted into the blood repackaged into low density lipoproteins (LDLs). From these circulating lipoproteins and the chylomicrons that bypassed the liver, β-carotene is taken into cells via receptor SCARB1. Human tissues differ in expression of SCARB1, and hence β-carotene content. Examples expressed as ng/g, wet weight: liver=479, lung=226, prostate=163 and skin=26.[15]

Once taken up by peripheral tissue cells, the major usage of absorbed β-carotene is as a precursor to retinal via symmetric cleavage by the enzyme beta-carotene 15,15'-dioxygenase, which is encoded by the BC01 gene. A lesser amount is metabolized by the mitochondrial enzyme beta-carotene 9',10'-dioxygenase, which is encoded by the BC02 gene. The products of this asymmetric cleavage are two beta-ionone molecules and rosafluene. BC02 appears to be involved in preventing excessive accumulation of carotenoids; a BC02 defect in chickens results in yellow skin color due to accumulation in subcutaneous fat.[16][17]

Conversion factors

Since 2001, the US Institute of Medicine uses retinol activity equivalents (RAE) for their Dietary Reference Intakes, defined as follows:[18]

Retinol activity equivalents (RAEs)

1 µg RAE = 1 µg retinol

1 µg RAE = 2 µg all-trans-β-carotene from supplements

1 µg RAE = 12 µg of all-trans-β-carotene from food

1 µg RAE = 24 µg α-carotene or β-cryptoxanthin from food

RAE takes into account carotenoids' variable absorption and conversion to vitamin A by humans better than and replaces the older retinol equivalent (RE) (1 µg RE = 1 µg retinol, 6 µg β-carotene, or 12 µg α-carotene or β-cryptoxanthin).[18] RE was developed 1967 by the United Nations/World Health Organization Food and Agriculture Organization (FAO/WHO).[19]

Another older unit of vitamin A activity is the international unit (IU). Like retinol equivalent, the international unit does not take into account carotenoids' variable absorption and conversion to vitamin A by humans, as well as the more modern retinol activity equivalent. Unfortunately, food and supplement labels still generally use IU, but IU can be converted to the more useful retinol activity equivalent as follows:[18]

International Units

  • 1 µg RAE = 3.33 IU retinol
  • 1 IU retinol = 0.3 μg RAE
  • 1 IU β-carotene from supplements = 0.3 μg RAE
  • 1 IU β-carotene from food = 0.05 μg RAE
  • 1 IU α-carotene or β-cryptoxanthin from food = 0.025 μg RAE1

Dietary sources

The average daily intake of β-carotene is in the range 2–7 mg, as estimated from a pooled analysis of 500,000 women living in the US, Canada, and some European countries.[20] Beta-carotene is found in many foods and is sold as a dietary supplement. β-Carotene contributes to the orange color of many different fruits and vegetables. Vietnamese gac (Momordica cochinchinensis Spreng.) and crude palm oil are particularly rich sources, as are yellow and orange fruits, such as cantaloupe, mangoes, pumpkin, and papayas, and orange root vegetables such as carrots and sweet potatoes. The color of β-carotene is masked by chlorophyll in green leaf vegetables such as spinach, kale, sweet potato leaves, and sweet gourd leaves.[21] Vietnamese gac and crude palm oil have the highest content of β-carotene of any known plant sources, 10 times higher than carrots, for example. However, gac is quite rare and unknown outside its native region of Southeast Asia, and crude palm oil is typically processed to remove the carotenoids before sale to improve the color and clarity.[22]

The U.S. Department of Agriculture lists high in β-carotene content.[23]

Food Beta-carotene

Milligrams per 100 g

Sweet potato, skinned, boiled 9.4
Carrot juice 9.3
Carrots, raw or boiled 9.2
Kale, boiled 8.8
Pumpkin, canned 6.9
Spinach, canned 5.9

No dietary requirement

Government and non-government organization have not set a dietary requirement for β-carotene.[15]

Side effects

Excess β-carotene is predominantly stored in the fat tissues of the body. The most common side effect of excessive β-carotene consumption is carotenodermia, a physically harmless condition that presents as a conspicuous orange skin tint arising from deposition of the carotenoid in the outermost layer of the epidermis.[24][15]

Carotenosis

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. Carotenodermia is reversible upon cessation of excessive intake.[25] Consumption of greater than 30 mg/day for a prolonged period has been confirmed as leading to carotenemia.[15][26]

No risk for hypervitaminosis A

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 then either incorporated as such into chylomicrons or first converted to retinal and then retinol, bound to retinol binding protein 2, before being incorporated into chylomicrons. The conversion process consists of one molecule of β-carotene cleaved by the enzyme beta-carotene 15,15'-dioxygenase, which is encoded by the BC01 gene, into two molecules of retinal. When plasma retinol is in the normal range the gene expression for SCARB1 and BC01 are suppressed, creating a feedback loop that suppresses absorption and conversion. Because of these two mechanisms, high intake will not lead to hypervitaminosis A.[15]

Drug interactions

β-Carotene can interact with medication used for lowering cholesterol. Taking them together can lower the effectiveness of these medications and is considered only a moderate interaction.[27] Bile acid sequestrants and proton-pump inhibitors can decrease absorption of β-carotene.[28] Consuming alcohol with β-carotene can decrease its ability to convert to retinol and could possibly result in hepatotoxicity.[29]

β-Carotene and lung cancer in smokers

Chronic high doses of β-carotene supplementation increases the probability of lung cancer in smokers.[30] The effect is specific to supplementation dose as no lung damage has been detected in those who are exposed to cigarette smoke and who ingest a physiologic dose of β-carotene (6 mg), in contrast to high pharmacologic dose (30 mg). Therefore, the oncology from β-carotene is based on both cigarette smoke and high daily doses of β-carotene.[31]

Increases in lung cancer may be due to the tendency of β-carotene to oxidize,[32] and may hasten oxidation more than other food colors such as annatto. A β-carotene breakdown product suspected of causing cancer at high dose is trans-β-apo-8'-carotenal (common apocarotenal), which has been found in one study to be mutagenic and genotoxic in cell cultures which do not respond to β-carotene itself.[33]

Additionally, supplemental, high-dose β-carotene may increase the risk of prostate cancer, intracerebral hemorrhage, and cardiovascular and total mortality in people who smoke cigarettes or have a history of high-level exposure to asbestos.[34]

Research

Medical authorities generally recommend obtaining beta-carotene from food rather than dietary supplements.[35] Research is insufficient to determine whether a minimum level of beta-carotene consumption is necessary for human health and to identify what problems might arise from insufficient beta-carotene intake.[36]

Macular degeneration

Age-related macular degeneration (AMD) represents the leading cause of irreversible blindness in elderly people. AMD is an oxidative stress, retinal disease that affects the macula, causing progressive loss of central vision.[37] β-carotene content is confirmed in human retinal pigment epithelium.[15] Reviews reported mixed results for observational studies, with some reporting that diets higher in β-carotene correlated with a decreased risk of AMD whereas other studies reporting no benefits.[38] Reviews reported that for intervention trials using only β-carotene, there was no change to risk of developing AMD.[38][39]

Cancer

A meta-analysis concluded that supplementation with β-carotene does not appear to decrease the risk of cancer overall, nor specific cancers including: pancreatic, colorectal, prostate, breast, melanoma, or skin cancer generally.[40] High levels of β-carotene may increase the risk of lung cancer in current and former smokers.[41] This is likely because beta-carotene is unstable in cigarette smoke-exposed lungs where it forms oxidized metabolites that can induce carcinogen-bioactivating enzymes.[42] Results are not clear for thyroid cancer.[43] In a single, small clinical study published in 1989, natural beta-carotene appeared to reduce premalignant gastric lesions.[36]:177

Cataract

A Cochrane review looked at supplementation of β-carotene, vitamin C, and vitamin E, independently and combined, on people to examine differences in risk of cataract, cataract extraction, progression of cataract, and slowing the loss of visual acuity. These studies found no evidence of any protective effects afforded by β-carotene supplementation on preventing and slowing age-related cataract.[44] A second meta-analysis compiled data from studies that measured diet-derived serum beta-carotene and reported a not statistically significant 10% decrease in cataract risk.[45]

Food drying

Caretenoids were found to be suseptible to a thermal degradation and discoloration upon drying, which are believed to associated with isomerization and oxidation reactions.[46]

See also

References

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