Phytochemical

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Red, blue, and purple colors of berries derive mainly from polyphenol phytochemicals called anthocyanins.
Cucurbita fruits, including squash and pumpkin, typically have high content of the phytochemical pigments called carotenoids.

Phytochemicals are chemical compounds produced by plants, generally to help them resist fungi, bacteria and plant virus infections, and also consumption by insects and other animals. The name comes from Greek φυτόν (phyton) 'plant'. Some phytochemicals have been used as poisons and others as traditional medicine.

As a term, phytochemicals is generally used to describe plant compounds that are under research with unestablished effects on health, and are not essential nutrients. Regulatory agencies governing food labeling in Europe and the United States have provided guidance for industry to limit or prevent health claims about phytochemicals on food product or nutrition labels.

Definition

Phytochemicals are chemicals of plant origin.[1] Phytochemicals (from Greek phyto, meaning "plant") are chemicals produced by plants through primary or secondary metabolism.[2][3] They generally have biological activity in the plant host and play a role in plant growth or defense against competitors, pathogens, or predators.[2]

Phytochemicals are generally regarded as research compounds rather than essential nutrients because proof of their possible health effects has not been established yet.[4][5] Phytochemicals under research can be classified into major categories, such as carotenoids[6] and polyphenols, which include phenolic acids, flavonoids, stilbenes or lignans.[5] Flavonoids can be further divided into groups based on their similar chemical structure, such as anthocyanins, flavones, flavanones, isoflavones, and flavanols.[5][7] Flavanols are further classified as catechins, epicatechins, and proanthocyanidins.[5][7] In total, between 50,000[8] and 130,000[9] phytochemicals have been discovered.

Phytochemists study phytochemicals by first extracting and isolating compounds from the origin plant, followed by defining their structure or testing in laboratory model systems, such as in vitro studies using cell lines or in vivo studies using laboratory animals.[2] Challenges in that field include isolating specific compounds and determining their structures, which are often complex, and identifying what specific phytochemical is primarily responsible for any given biological activity.[2][10][11]

History of uses

Berries of Atropa belladonna, also called deadly nightshade

Without specific knowledge of their cellular actions or mechanisms, phytochemicals have been used as poison and in traditional medicine. For example, salicin, having anti-inflammatory and pain-relieving properties, was originally extracted from the bark of the white willow tree and later synthetically produced to become the common, over-the-counter drug aspirin.[12][13] The tropane alkaloids of Atropa belladonna were used as poisons, and early humans made poisonous arrows from the plant.[14] In Ancient Rome, it was used as a poison by Agrippina the Younger, wife of Emperor Claudius on advice of Locusta, a lady specialized in poisons, and Livia, who is rumored to have used it to kill her husband Emperor Augustus.[14][15] Other uses include perfumes, such as the sequiterpene santolols, from sandalwood.[16]

The English yew tree was long known to be extremely and immediately toxic to animals that grazed on its leaves or children who ate its berries; however, in 1971, paclitaxel was isolated from it, subsequently becoming an important cancer drug.[2]

The biological activities for most phytochemicals are unknown or poorly understood, in isolation or as part of foods.[2][5] Phytochemicals with established roles in the body are classified as essential nutrients.[4][17]

Functions

The phytochemical category includes compounds recognized as essential nutrients, which are naturally contained in plants and are required for normal physiological functions, so must be obtained from the diet in humans.[17][18]

Some phytochemicals are known phytotoxins that are toxic to humans;[19][20] for example aristolochic acid is carcinogenic at low doses.[21] Some phytochemicals are antinutrients that interfere with the absorption of nutrients.[22] Others, such as some polyphenols and flavonoids, may be pro-oxidants in high ingested amounts.[23]

Non-digestible dietary fibers from plant foods, often considered as a phytochemical,[24] are now generally regarded as a nutrient group having approved health claims for reducing the risk of some types of cancer[25] and coronary heart disease.[26]

Eating a diet high in fruits, vegetables, grains, legumes and plant-based beverages has long-term health benefits,[17] but there is no evidence that taking dietary supplements of non-nutrient phytochemicals extracted from plants similarly benefits health.[4] Phytochemical supplements are neither recommended by health authorities for improving health[5][27] nor approved by regulatory agencies for health claims on product labels.[28][29]

Consumer and industry guidance

While health authorities encourage consumers to eat diets rich in fruit, vegetables, whole grains, legumes, and nuts to improve and maintain health,[17] evidence that such effects result from specific, non-nutrient phytochemicals is limited or absent.[4] For example, systematic reviews and/or meta-analyses indicate weak or no evidence for phytochemicals from plant food consumption having an effect on breast, lung, or bladder cancers.[30][31] Further, in the United States, regulations exist to limit the language on product labels for how plant food consumption may affect cancers, excluding mention of any phytochemical except for those with established health benefits against cancer, such as dietary fiber, vitamin A, and vitamin C.[32]

Phytochemicals, such as polyphenols, have been specifically discouraged from food labeling in Europe and the United States because there is no evidence for a cause-and-effect relationship between dietary polyphenols and inhibition or prevention of any disease.[28][33]

Among carotenoids such as the tomato phytochemical, lycopene, the US Food and Drug Administration found insufficient evidence for its effects on any of several cancer types, resulting in limited language for how products containing lycopene can be described on labels.[34]

Effects of food processing

Phytochemicals in freshly harvested plant foods may be degraded by processing techniques, including cooking.[35] The main cause of phytochemical loss from cooking is thermal decomposition.[35]

A converse exists in the case of carotenoids, such as lycopene present in tomatoes, which may remain stable or increase in content from cooking due to liberation from cellular membranes in the cooked food.[36] Food processing techniques like mechanical processing can also free carotenoids and other phytochemicals from the food matrix, increasing dietary intake.[35][37]

In some cases, processing of food is necessary to remove phytotoxins or antinutrients; for example societies that use cassava as a staple have traditional practices that involve some processing (soaking, cooking, fermentation, etc.), which are necessary to avoid getting sick from cyanogenic glycosides present in unprocessed cassava.[38]

See also

References

  1. ^ Breslin, Andrew (2017). "The Chemical Composition of Green Plants". Sciencing, Leaf Group Ltd.
  2. ^ a b c d e f Molyneux, RJ; Lee, ST; Gardner, DR; Panter, KE; James, LF (2007). "Phytochemicals: the good, the bad and the ugly?". Phytochemistry. 68 (22–24): 2973–85. Bibcode:2007PChem..68.2973M. doi:10.1016/j.phytochem.2007.09.004. PMID 17950388. Archived from the original on 2023-07-03. Retrieved 2017-02-10.
  3. ^ Harborne, Jeffrey B.; Baxter, Herbert; Moss, Gerard P., eds. (1999). "General Introduction". Phytochemical dictionary a handbook of bioactive compounds from plants (2nd ed.). London: Taylor & Francis. p. vii. ISBN 9780203483756.
  4. ^ a b c d "Phytochemicals". Micronutrient Information Center, Linus Pauling Institute, Oregon State University, Corvallis, Oregon. 2017. Retrieved 12 February 2017.
  5. ^ a b c d e f Heneman, Karrie; Zidenberg-Cherr, Sheri (2008). "Publication 8313: Phytochemicals" (PDF). University of California Cooperative Extension.
  6. ^ "Carotenoids". Micronutrient Information Center, Linus Pauling Institute, Oregon State University, Corvallis, Oregon. July 2016. Retrieved 12 February 2017.
  7. ^ a b "Flavonoids". Micronutrient Information Center, Linus Pauling Institute, Oregon State University, Corvallis, Oregon. November 2015. Retrieved 12 February 2017.
  8. ^ Afendi, Farit Mochamad; Okada, Taketo; Yamazaki, Mami; et al. (February 2012). "KNApSAcK Family Databases: Integrated Metabolite–Plant Species Databases for Multifaceted Plant Research". Plant and Cell Physiology. 53 (2): e1. doi:10.1093/pcp/pcr165. PMID 22123792.
  9. ^ Rutz, Adriano; Sorokina, Maria; Galgonek, Jakub; et al. (26 May 2022). "The LOTUS initiative for open knowledge management in natural products research". eLife. 11: e70780. doi:10.7554/eLife.70780. PMC 9135406. PMID 35616633.
  10. ^ Webb, L. J. (Leonard James) (1950), An Australian phytochemical survey : Alkaloids in Queensland flowering plants, Brisbane, retrieved 25 March 2022
  11. ^ Price, J. R.; Lamberton, J. A.; Culvenor, C.C.J (1992), "The Australian Phytochemical Survey: historical aspects of the CSIRO search for new drugs in Australian plants. Historical Records of Australian Science, 9(4), 335–356", Historical Records of Australian Science, 9 (4), Australian Academy of Science: 335, 336, doi:10.1071/hr9930940335
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  16. ^ Ellena 2022, pp. 12–15.
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  19. ^ Iwasaki, S (April 1998). "Natural organic compounds that affect to microtubule functions". Yakugaku Zasshi. 118 (4): 112–26. doi:10.1248/yakushi1947.118.4_111. PMID 9564789.
  20. ^ Bjeldanes, Leonard; Shibamoto, Takayuki (2009). Introduction to Food Toxicology (2nd ed.). Burlington: Elsevier. p. 124. ISBN 9780080921532.
  21. ^ Shaw, D (December 2010). "Toxicological risks of Chinese herbs". Planta Medica. 76 (17): 2012–8. doi:10.1055/s-0030-1250533. PMID 21077025.
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  32. ^ "Electronic Code of Federal Regulations, Title 21, Chapter I, Subchapter B, Part 101.78. Health claims: fruits and vegetables and cancer". US Government Printing Office. 9 February 2017. Retrieved 12 February 2017.
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  34. ^ Schneeman BO (9 July 2015). "Qualified Health Claims: Letter Regarding "Tomatoes and Prostate, Ovarian, Gastric and Pancreatic Cancers (American Longevity Petition)" (Docket No. 2004Q-0201)". Office of Nutritional Products, Labeling and Dietary Supplements, Center for Food Safety and Applied Nutrition, US Food and Drug Administration. Retrieved 12 February 2017.
  35. ^ a b c Palermo, M; Pellegrini, N; Fogliano, V (2014). "The effect of cooking on the phytochemical content of vegetables". Journal of the Science of Food and Agriculture. 94 (6): 1057–70. doi:10.1002/jsfa.6478. hdl:11381/2677278. PMID 24227349.
  36. ^ Dewanto, V; Wu, X; Adom, KK; Liu, RH (2002). "Thermal processing enhances the nutritional value of tomatoes by increasing total antioxidant activity". Journal of Agricultural and Food Chemistry. 50 (10): 3010–4. doi:10.1021/jf0115589. PMID 11982434.
  37. ^ Hotz, C; Gibson, R. S. (2007). "Traditional food-processing and preparation practices to enhance the bioavailability of micronutrients in plant-based diets". The Journal of Nutrition. 137 (4): 1097–100. doi:10.1093/jn/137.4.1097. PMID 17374686.
  38. ^ Contents: Roots, tubers, plantains and bananas in human nutrition. Rome: FAO. 1990. Chapter 7: Cassava toxicity

Further reading

Notes

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