Blog List

Saturday, 25 June 2016

List of antioxidants in food


Foods highest in antioxidants

Food Sources

Regulatory guidanceEdit

In the following discussion, the term "antioxidant" refers mainly to non-nutrient compounds in foods, such as polyphenols, which have antioxidant capacity in vitro and so provide an artificial index of antioxidant strength – the ORAC measurement. Other than for dietary antioxidant vitamins – vitamin Avitamin C and vitamin E – no food compounds have been proved with antioxidant efficacy in vivo. Accordingly, regulatory agencies like the Food and Drug Administration of the United States and the European Food Safety Authority (EFSA) have published guidance disallowing food product labels to claim an inferred antioxidant benefit when no such physiological evidence exists.[1][2]

Polyphenols in foodsEdit

Many common foods contain rich sources of polyphenols which have antioxidant properties only in test tube studies. As interpreted by the Linus Pauling Institute, dietary polyphenols have little or no direct antioxidant food value following digestion.[3] Not like controlled test tube conditions, the fate of flavones or polyphenols in vivo shows they are poorly conserved (less than 5%), with most of what is absorbed existing as metabolites modified during digestion and destined for rapid excretion.[4]
Spices, herbs, and essential oils are rich in polyphenols in the plant itself and shown with antioxidant potential in vitro. Typical spices high in polyphenols (confirmed in vitro) are clovecinnamonoreganoturmericcuminparsleybasilcurry powdermustard seedgingerpepperchili powderpaprikagarliccorianderonion and cardamom. Typical herbs are sagethymemarjoramtarragonpeppermintoreganosavorybasil and dill weed.
Dried fruits are a good source of polyphenols by weight/serving size as the water has been removed making the ratio of polyphenols higher. Typical dried fruits are pears, apples, plums, peaches, raisins, figs and dates. Dried raisins are high in polyphenol count. Red wine is high in total polyphenol count which supplies antioxidant quality which is unlikely to be conserved following digestion (see section below).
Deeply pigmented fruits like cranberries, blueberries, plums, blackberries, raspberries, strawberries, blackcurrants, figs, cherries, guava, oranges, mango, grape juice and pomegranate juice also have significant polyphenol content.
Typical cooked vegetables rich in antioxidants are artichokescabbagebroccoliasparagusavocadosbeetroot and spinach.
Nuts are a moderate source of polyphenol antioxidants. Typical nuts are pecanswalnutshazelnutspistachioalmondscashew nutsmacadamia nuts and peanut butter.
Sorghum bran, cocoa powder, and cinnamon are rich sources of procyanidins, which are large molecular weight compounds found in many fruits and some vegetables. Partly due to the large molecular weight (size) of these compounds, their amount actually absorbed in the body is low, an effect also resulting from the action of stomach acids, enzymes and bacteria in the gastrointestinal tract where smaller derivatives are metabolized and prepared for rapid excretion.[3][4]

Physiological contextEdit

Despite the above discussion implying that ORAC-rich foods with polyphenols may provide antioxidant benefits when in the diet, there remains no physiological evidence that any polyphenols have such actions or that ORAC has any relevance in the human body.
On the contrary, research indicates that although polyphenols are good antioxidants in vitro, antioxidant effects in vivo are probably negligible or absent.[5][6][7] By non-antioxidant mechanisms still undefined, polyphenols may affect mechanisms of cardiovascular disease or cancer.[8]
The increase in antioxidant capacity of blood seen after the consumption of polyphenol-rich (ORAC-rich) foods is not caused directly by the polyphenols, but most likely results from increased uric acid levels derived from metabolism of flavonoids.[3][4] According to Frei, "we can now follow the activity of flavonoids in the body, and one thing that is clear is that the body sees them as foreign compounds and is trying to get rid of them."[4] Another mechanism may be the increase in activities of paraoxonases by dietary antioxidants which can reduce oxidative stress.[9]

Vitamins


Vitamin cofactors and minerals


Hormones



Carotenoid terpenoids

Main article: carotenoid
  • Alpha-carotene - found in carrots, winter squash, tomatoes, green beans, cilantro, Swiss chard
  • Astaxanthin - found naturally in red algae and animals higher in the marine food chain. It is a red pigment familiarly recognized in crustacean shells and salmon flesh/roe.
  • Beta-carotene - found in high concentrations in butternut squash, carrots, orange bell peppers, pumpkins, kale, peaches, apricots, mango, turnip greens, broccoli, spinach, and sweet potatoes.
  • Canthaxanthin
  • Lutein - found in high concentration in spinach, kale, Swiss chard, collard greens, beet and mustard greens, endive, red pepper and okra
  • Lycopene - found in high concentration in cooked red tomato products like canned tomatoes, tomato sauce, tomato juice and garden cocktails, guava and watermelons.
  • Zeaxanthin - best sources are kale, collard greens, spinach, turnip greens, Swiss chard, mustard and beet greens, corn, and broccoli

Natural phenols

Natural phenols are a class of molecules found in abundance in plants.

FlavonoidsEdit

Flavonoids, a subset of polyphenol antioxidants, are present in many berries, as well as in coffee and tea.

Phenolic acids and their estersEdit

Main article: polyphenol antioxidant
  • Chicoric acid - another caffeic acid derivative, is found in chicory and Echinacea.
  • Chlorogenic acid - found in high concentration in coffee (more concentrated in robusta than arabica beans), blueberries and tomatoes. Produced from esterification of caffeic acid.
  • Cinnamic acid and its derivatives, such as ferulic acid - found in seeds of plants such as in brown rice, whole wheat and oats, as well as in coffee, apple, artichoke, peanut, orange and pineapple.
  • Ellagic acid - found in high concentration in raspberry and strawberry, and in ester form in red wine tannins.
  • Ellagitannins - hydrolyzable tannin polymer formed when ellagic acid, a polyphenol monomer, esterifies and binds with the hydroxyl group of a polyol carbohydrate such as glucose.
  • Gallic acid - found in gallnuts, sumac, witch hazel, tea leaves, oak bark, and many other plants.
  • Gallotannins - hydrolyzable tannin polymer formed when gallic acid, a polyphenol monomer, esterifies and binds with the hydroxyl group of a polyol carbohydrate such as glucose.
  • Rosmarinic acid - found in high concentration in rosemaryoreganolemon balmsage, and marjoram.
  • Salicylic acid - found in most vegetables, fruits, and herbs; but most abundantly in the bark of willow trees, from where it was extracted for use in the early manufacture of aspirin.

Other nonflavonoid phenolicsEdit


Other potential organic antioxidants


See Also


References

  1. ^ Guidance for Industry, Food Labeling; Nutrient Content Claims; Definition for "High Potency" and Definition for "Antioxidant" for Use in Nutrient Content Claims for Dietary Supplements and Conventional Foods U.S. Department of Health and Human Services, Food and Drug Administration, Center for Food Safety and Applied Nutrition, June 2008
  2. ^ EFSA Panel on Dietetic Products, Nutrition and Allergies (2010). "Scientific Opinion on the substantiation of health claims related to various food(s)/food constituent(s) and protection of cells from premature aging, antioxidant activity, antioxidant content and antioxidant properties, and protection of DNA, proteins and lipids from oxidative damage pursuant to Article 13(1) of Regulation (EC) No 1924/2006". EFSA Journal 8 (2): 1489. doi:10.2903/j.efsa.2010.1489.
  3. a b c Lotito, S; Frei, B (2006). "Consumption of flavonoid-rich foods and increased plasma antioxidant capacity in humans: Cause, consequence, or epiphenomenon?". Free Radical Biology and Medicine 41 (12): 1727–46. doi:10.1016/j.freeradbiomed.2006.04.033PMID 17157175.
  4. a b c d David Stauth (5 March 2007). "Studies force new view on biology of flavonoids". EurekAlert!; Adapted from a news release issued by Oregon State University.
  5. ^ Williams, Robert J; Spencer, Jeremy P.E; Rice-Evans, Catherine (2004). "Flavonoids: antioxidants or signalling molecules?☆". Free Radical Biology and Medicine 36 (7): 838–49. doi:10.1016/j.freeradbiomed.2004.01.001PMID 15019969.
  6. ^ Gross, P (2009). "New Roles for Polyphenols. A 3-Part report on Current Regulations & the State of Science"Nutraceuticals World. Rodman Media. Retrieved April 11, 2013.
  7. ^ Jonny Bowden, PhD, C.N.S. (16 Dec 2012). "ORAC no more!". Huffington Post. Retrieved 12 Dec 2012.
  8. ^ Arts, IC; Hollman, PC (2005). "Polyphenols and disease risk in epidemiologic studies". The American Journal of Clinical Nutrition 81 (1 Suppl): 317S–325S. PMID 15640497.
  9. ^ Aviram, M; Rosenblat, M (2005). "Paraoxonases and cardiovascular diseases: pharmacological and nutritional influences". Current Opinion in Lipidology 16 (4): 393–9. doi:10.1097/01.mol.0000174398.84185.0fPMID 15990587.
  10. a b Anand, Preetha; Kunnumakkara, Ajaikumar B.; Newman, Robert A.; Aggarwal, Bharat B. (2007). "Bioavailability of Curcumin: Problems and Promises". Molecular Pharmaceutics 4 (6): 807–18. doi:10.1021/mp700113rPMID 17999464.
  11. ^ Kurien, Biji T.; Singh, Anil; Matsumoto, Hiroyuki; Scofield, R. Hal (2007). "Improving the Solubility and Pharmacological Efficacy of Curcumin by Heat Treatment". ASSAY and Drug Development Technologies 5 (4): 567–76. doi:10.1089/adt.2007.064PMID 17767425.
  12. ^ Nair, Hareesh B.; Sung, Bokyung; Yadav, Vivek R.; Kannappan, Ramaswamy; Chaturvedi, Madan M.; Aggarwal, Bharat B. (2010). "Delivery of antiinflammatory nutraceuticals by nanoparticles for the prevention and treatment of cancer"Biochemical Pharmacology 80 (12): 1833–1843. doi:10.1016/j.bcp.2010.07.021PMC 2974020PMID 20654584.
  13. ^ [1] Archived August 4, 2008, at the Wayback Machine.
  14. ^ Stocker, R; Yamamoto, Y; McDonagh, A.; Glazer, A.; Ames, B. (1987). "Bilirubin is an antioxidant of possible physiological importance". Science 235 (4792): 1043–6. Bibcode:1987Sci...235.1043Sdoi:10.1126/science.3029864PMID 3029864.
  15. ^ Zawiasa, A.; Szklarek-Kubicka, M.; Fijałkowska-Morawska, J.; Nowak, D.; Rysz, J.; Mamełka, B.; Nowicki, M. (2009). "Effect of Oral Fructose Load on Serum Uric Acid and Lipids in Kidney Transplant Recipients Treated with Cyclosporine or Tacrolimus". Transplantation Proceedings 41 (1): 188–91. doi:10.1016/j.transproceed.2008.10.038PMID 19249511.
  16. ^ De Vera, Mary; Rahman, M. Mushfiqur; Rankin, James; Kopec, Jacek; Gao, Xiang; Choi, Hyon (2008). "Gout and the risk of parkinson's disease: A cohort study". Arthritis & Rheumatism 59 (11): 1549–54. doi:10.1002/art.24193PMID 18975349.

External Links



Wikipedia 

No comments:

Post a Comment

Advantages and Disadvantages of Fasting for Runners

Author BY   ANDREA CESPEDES  Food is fuel, especially for serious runners who need a lot of energy. It may seem counterintuiti...