Carotenes

The carotenes are non-polar and therefore fat-soluble, which is why they can only be used in the human organism together with at least a small amount of fat. Carotenes come in many variants - over 600 are known to date. What they all have in common is a similar basic structure with different end groups.

The best known carotene is β-carotene . The name of the entire group of carotenes is derived from him. It is the main precursor of vitamin A in foods and is therefore also called pro-vitamin A called. In addition to β-carotene, α- and γ-carotene and β-cryptoxanthin can also be converted into vitamin A. However, the individual forms, such as β-carotene, also have effects independent of vitamin A.

In plants, carotenes play a role in photosynthesis and protect against the harmful effects of UV rays. Formed in the roots of plants, they protect against infections there.

Humans ingest large amounts of α- and β-carotene, α- and β-cryptoxanthine and lycopene with their food . The functions and effects of carotenes in the human body are becoming more and more known, but they are also easily disputed. For example, recent studies cast doubts about the cancer-inhibiting effect. A general cell-protecting effect as antioxidants can certainly be ascribed to them.

The IUPAC recommends a different nomenclature for carotenes. The carotene is named according to the end groups and marked with β, ε (contain ionone rings) and ψ (open-chain). α-carotene is therefore β, ε-carotene, β-carotene is β, β-carotene and γ-carotene is β, ψ-carotene according to the IUPAC-compliant nomenclature.

Natural occurrence

Tomato ( Solanum lycopersicum )

Kale

Carrots

β-carotene (beta-carotene, INN : beta-carotene ) is the most important precursor of retinol (vitamin A) and is therefore also referred to as provitamin A.

The best sources of beta-carotene are kale , deep yellow to orange fruits and vegetables, but also dark green vegetables. At 8.68 mg β-carotene / 100 g, kale has the highest beta-carotene content of all foods. Examples:

• yellow to orange vegetables: carrots , sweet potatoes , pumpkins
• yellow to orange fruits: persimmons , apricots , papayas , mangoes , nectarines , peaches , pears , sea ​​buckthorn
• dark green vegetables: kale , spinach , broccoli , endive , chicory , cress , rocket , beetroot or dandelion leaves , high content in the leaves of sorrel (0.15%) and purslane (0.45%).
• also possible sources of β-carotene are: tomatoes , asparagus , peas , cabbage , corn , sour cherries , plums

Analytics

Use as a food coloring

Beta-carotene extracted from plants or synthetically produced is used as a food coloring ( E  160a , see food additive ) and as an addition to vitamin preparations. Beta-carotene is added to many foods such as butter, margarines, confectionery, dairy products and lemonades, sometimes in very large quantities, in order to give the consumer the image of the goods (color) that he expects. Otherwise, margarines, for example, would be more or less white to light gray.

Absorption in the human intestine

The absorption of β-carotene is worse than that of vitamin A. About six times as much β-carotene has to be absorbed in order to provide the body with the same amount of vitamin A. The two fabrics can be freely combined. The German Nutrition Society (DGE) recommends a daily intake of 0.8 to 1.1 mg vitamin A for healthy adults.

Health aspects

Teratogenic effects of β-carotene are not known. Even high supplemented daily doses (20-30 mg) or a particularly carotene-rich diet over long periods of time are not associated with toxicity .

However, the multi-year supplementation of β-carotene is suspected in smokers and drinkers , the incidence risk for lung cancer and colon cancer to increase. For example, in an Australian study in the Journal of the National Cancer Institute on May 21, 2003, which wanted to investigate its effect as a sunscreen, double the number of adenomas in smokers and people who regularly consumed more than one alcoholic drink per day of the colon - the precursors of colon cancer. Instead, their incidence was reduced by 44% in non-smokers and non-drinkers. The American Cancer Society requires warning labels on goods containing β-carotene to warn smokers of a possible increased risk of lung cancer.

Regulations of the Federal Institute for Drugs, which have been in force since May 2006, only partially take into account the results and obvious conclusions from the above study. Since then, all drugs containing β-carotene have had to carry a warning that they pose an increased risk for smokers of developing lung cancer. Medicines containing more than 20 mg β-carotene may no longer be prescribed to smokers. No statement can be made from the studies as to whether the consumption of natural foods with a natural carotene content could pose a risk; however, the proportion of β-carotene in natural foods and juices is often noticeably lower than in artificially fortified foods.

As part of the so-called CARET study in the 1990s, the effect of supplementing 30 mg β-carotene daily in combination with 25,000 IU retinyl palmitate on the risk of incidence of various cancers and mortality was examined. 18314 people took part whose risk of lung cancer was increased because they either had a long smoking career or were exposed to asbestos dust . In addition to the further increase in the risk of lung cancer, the researchers found that the presumed consequence of supplementation was an increased mortality rate from cardiovascular disease .

Historical

Individual evidence

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9. ↑ Entry on E 160a: Carotenes in the European database on food additives, accessed on June 16, 2020.
10. ↑ MJ Scotter, L. Castle, JM Croucher, L. Olivier: Method development and analysis of retail foods and beverages for carotenoid food coloring materials E160a (ii) and E160e. In: Food Additives and Contaminants. Volume 20, 2003, pp. 115-126, doi: 10.1080 / 0265203021000055397 .
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16. ^ ^{A b} National Institutes of Health - Office of Dietary Supplements: Health Risks from Excessive Vitamin A In: Vitamin A - Fact Sheet for Health Professionals. 5th June 2013.
17. ↑ The Alpha-Tocopherol Beta Carotene Cancer Prevention Study Group: The effect of vitamin E and beta carotene on the incidence of lung cancer and other cancers in male smokers. In: The New England journal of medicine . Volume 330, Number 15, April 1994, pp. 1029-1035, doi: 10.1056 / NEJM199404143301501 . PMID 8127329 .
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21. ↑ Vitamin supplements, smoking and lung cancer risk . (No longer available online.) April 14, 2011, archived from the original on October 25, 2012 ; accessed on August 26, 2012 (English). 
22. ↑ GE Goodman et al: The Beta-Carotene and Retinol Efficacy Trial: incidence of lung cancer and cardiovascular disease mortality during 6-year follow-up after stopping beta-carotene and retinol supplements. In: Journal of the National Cancer Institute. Volume 96, Number 23, December 2004, pp. 1743-1750, doi: 10.1093 / jnci / djh320 . PMID 15572756 .
23. ↑ Theodore L. Sourkes: The Discovery And Early History Of Carotene. In: Bull. Hist. Chem. Volume 34, 2009, pp. 32-38. (pdf, online)
24. ↑ Biography of Paul Karrer .
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27. ↑ Clarence Sterling: Crystal structure analysis of β-carotene. In: Acta Crystallographica. Volume 17, No. 10, 1964, pp. 1224-1228, doi: 10.1107 / S0365110X64003152 .