fbpx
Wikipedia

Antioxidant

February 16, 2024

Antioxidants are compounds that inhibit oxidation (usually occurring as autoxidation), a chemical reaction that can produce free radicals. Autoxidation leads to degradation of organic compounds, including living matter. Antioxidants are frequently added to industrial products, such as polymers, fuels, and lubricants, to extend their usable lifetimes.[1] Foods are also treated with antioxidants to forestall spoilage, in particular the rancidification of oils and fats. In cells, antioxidants such as glutathione, mycothiol or bacillithiol, and enzyme systems like superoxide dismutase, can prevent damage from oxidative stress.[2]

Structure of the antioxidant, glutathione

Known dietary antioxidants are vitamins A, C, and E, but the term antioxidant has also been applied to numerous other dietary compounds that only have antioxidant properties in vitro, with little evidence for antioxidant properties in vivo.[3] Dietary supplements marketed as antioxidants have not been shown to maintain health or prevent disease in humans.[3][4]

History edit

As part of their adaptation from marine life, terrestrial plants began producing non-marine antioxidants such as ascorbic acid (vitamin C), polyphenols and tocopherols. The evolution of angiosperm plants between 50 and 200 million years ago resulted in the development of many antioxidant pigments – particularly during the Jurassic period – as chemical defences against reactive oxygen species that are byproducts of photosynthesis.[5] Originally, the term antioxidant specifically referred to a chemical that prevented the consumption of oxygen. In the late 19th and early 20th centuries, extensive study concentrated on the use of antioxidants in important industrial processes, such as the prevention of metal corrosion, the vulcanization of rubber, and the polymerization of fuels in the fouling of internal combustion engines.[6]

Early research on the role of antioxidants in biology focused on their use in preventing the oxidation of unsaturated fats, which is the cause of rancidity.[7] Antioxidant activity could be measured simply by placing the fat in a closed container with oxygen and measuring the rate of oxygen consumption. However, it was the identification of vitamins C and E as antioxidants that revolutionized the field and led to the realization of the importance of antioxidants in the biochemistry of living organisms.[8][9] The possible mechanisms of action of antioxidants were first explored when it was recognized that a substance with anti-oxidative activity is likely to be one that is itself readily oxidized.[10] Research into how vitamin E prevents the process of lipid peroxidation led to the identification of antioxidants as reducing agents that prevent oxidative reactions, often by scavenging reactive oxygen species before they can damage cells.[11]

Uses in technology edit

Food preservatives edit

See also: E number § E300–E399 (antioxidants, acidity regulators)

Antioxidants are used as food additives to help guard against food deterioration. Exposure to oxygen and sunlight are the two main factors in the oxidation of food, so food is preserved by keeping in the dark and sealing it in containers or even coating it in wax, as with cucumbers. However, as oxygen is also important for plant respiration, storing plant materials in anaerobic conditions produces unpleasant flavors and unappealing colors.[12] Consequently, packaging of fresh fruits and vegetables contains an ≈8% oxygen atmosphere. Antioxidants are an especially important class of preservatives as, unlike bacterial or fungal spoilage, oxidation reactions still occur relatively rapidly in frozen or refrigerated food.[13] These preservatives include natural antioxidants such as ascorbic acid (AA, E300) and tocopherols (E306), as well as synthetic antioxidants such as propyl gallate (PG, E310), tertiary butylhydroquinone (TBHQ), butylated hydroxyanisole (BHA, E320) and butylated hydroxytoluene (BHT, E321).[14][15]

Unsaturated fats can be highly susceptible to oxidation, causing rancidification.[16] Oxidized lipids are often discolored and can impart unpleasant tastes and flavors. Thus, these foods are rarely preserved by drying; instead, they are preserved by smoking, salting, or fermenting. Even less fatty foods such as fruits are sprayed with sulfurous antioxidants prior to air drying. Metals catalyse oxidation. Some fatty foods such as olive oil are partially protected from oxidation by their natural content of antioxidants. Fatty foods are sensitive to photooxidation,[17] which forms hydroperoxides by oxidizing unsaturated fatty acids and ester.[18] Exposure to ultraviolet (UV) radiation can cause direct photooxidation and decompose peroxides and carbonyl molecules. These molecules undergo free radical chain reactions, but antioxidants inhibit them by preventing the oxidation processes.[18]

Cosmetics preservatives edit

Antioxidant stabilizers are also added to fat-based cosmetics such as lipstick and moisturizers to prevent rancidity.[19] Antioxidants in cosmetic products prevent oxidation of active ingredients and lipid content. For example, phenolic antioxidants such as stilbenes, flavonoids, and hydroxycinnamic acid strongly absorb UV radiation due to the presence of chromophores. They reduce oxidative stress from sun exposure by absorbing UV light.[20]

Industrial uses edit

 
Substituted phenols and derivatives of phenylenediamine are common antioxidants used to inhibit gum formation in gasoline (petrol).

Antioxidants may be added to industrial products, such as stabilizers in fuels and additives in lubricants, to prevent oxidation and polymerization that leads to the formation of engine-fouling residues.[21]

Fuel additive Components[22] Applications[22]
AO-22 N,N'-di-2-butyl-1,4-phenylenediamine Turbine oils, transformer oils, hydraulic fluids, waxes, and greases
AO-24 N,N'-di-2-butyl-1,4-phenylenediamine Low-temperature oils
AO-29 2,6-di-tert-butyl-4-methylphenol (BHT) Turbine oils, transformer oils, hydraulic fluids, waxes, greases, and gasolines
AO-30 2,4-dimethyl-6-tert-butylphenol Jet fuels and gasolines, including aviation gasolines
AO-31 2,4-dimethyl-6-tert-butylphenol Jet fuels and gasolines, including aviation gasolines
AO-32 2,4-dimethyl-6-tert-butylphenol and 2,6-di-tert-butyl-4-methylphenol Jet fuels and gasolines, including aviation gasolines
AO-37 2,6-di-tert-butylphenol Jet fuels and gasolines, widely approved for aviation fuels

Antioxidant polymer stabilizers are widely used to prevent the degradation of polymers, such as rubbers, plastics and adhesives, that causes a loss of strength and flexibility in these materials.[23] Polymers containing double bonds in their main chains, such as natural rubber and polybutadiene, are especially susceptible to oxidation and ozonolysis. They can be protected by antiozonants. Oxidation can be accelerated by UV radiation in natural sunlight to cause photo-oxidation. Various specialised light stabilisers, such as HALS may be added to plastics to prevent this. Synthetic phenolic[24] and aminic[25] antioxidants are increasingly being identified as potential human and environmental health hazards.

Environmental and health hazards edit

Synthetic phenolic antioxidants (SPAs) and aminic antioxidants have potential human and environmental health hazards. SPAs are common in indoor dust, small air particles, sediment, sewage, river water and wastewater.[26] They are synthesized from phenolic compounds and include 2,6-di-tert-butyl-4-methylphenol (BHT), 2,6-di-tert-butyl-p-benzoquinone (BHT-Q), 2,4-di-tert-butyl-phenol (DBP) and 3-tert-butyl-4-hydroxyanisole (BHA). BHT can cause hepatotoxicity and damage to the endocrine system and may increase tumor development rates due to 1,1-dimethylhydrazine.[27] BHT-Q can cause DNA damage and mismatches[28] through the cleavage process, generating superoxide radicals.[26] DBP is toxic to marine life if exposed long-term. Phenolic antioxidants have low biodegradability, but they do not have severe toxicity toward aquatic organisms at low concentrations. Another type of antioxidant, diphenylamine (DPA), is commonly used in the production of commercial, industrial lubricants and rubber products and it also acts as a supplement for automotive engine oils.[29]

Oxidative challenge in biology edit

Further information: Oxidative stress
 
The structure of the antioxidant vitamin ascorbic acid (vitamin C)

The vast majority of complex life on Earth requires oxygen for its metabolism, but this same oxygen is a highly reactive element that can damage living organisms.[2][30] Organisms contain chemicals and enzymes that minimize this oxidative damage without interfering with the beneficial effect of oxygen.[31][32] In general, antioxidant systems either prevent these reactive species from being formed, or remove them, thus minimizing their damage.[30][31] Reactive oxygen species can have useful cellular functions, such as redox signaling. Thus, ideally, antioxidant systems do not remove oxidants entirely, but maintain them at some optimum concentration.[33]

Reactive oxygen species produced in cells include hydrogen peroxide (H2O2), hypochlorous acid (HClO), and free radicals such as the hydroxyl radical (·OH) and the superoxide anion (O2).[34] The hydroxyl radical is particularly unstable and will react rapidly and non-specifically with most biological molecules. This species is produced from hydrogen peroxide in metal-catalyzed redox reactions such as the Fenton reaction.[35] These oxidants can damage cells by starting chemical chain reactions such as lipid peroxidation, or by oxidizing DNA or proteins.[31] Damage to DNA can cause mutations and possibly cancer, if not reversed by DNA repair mechanisms,[36][37] while damage to proteins causes enzyme inhibition, denaturation and protein degradation.[38]

The use of oxygen as part of the process for generating metabolic energy produces reactive oxygen species.[39] In this process, the superoxide anion is produced as a by-product of several steps in the electron transport chain.[40] Particularly important is the reduction of coenzyme Q in complex III, since a highly reactive free radical is formed as an intermediate (Q·). This unstable intermediate can lead to electron "leakage", when electrons jump directly to oxygen and form the superoxide anion, instead of moving through the normal series of well-controlled reactions of the electron transport chain.[41] Peroxide is also produced from the oxidation of reduced flavoproteins, such as complex I.[42] However, although these enzymes can produce oxidants, the relative importance of the electron transfer chain to other processes that generate peroxide is unclear.[43][44] In plants, algae, and cyanobacteria, reactive oxygen species are also produced during photosynthesis,[45] particularly under conditions of high light intensity.[46] This effect is partly offset by the involvement of carotenoids in photoinhibition, and in algae and cyanobacteria, by large amount of iodide and selenium,[47] which involves these antioxidants reacting with over-reduced forms of the photosynthetic reaction centres to prevent the production of reactive oxygen species.[48][49]

Examples of bioactive antioxidant compounds edit

Physiological antioxidants are classified into two broad divisions, depending on whether they are soluble in water (hydrophilic) or in lipids (lipophilic). In general, water-soluble antioxidants react with oxidants in the cell cytosol and the blood plasma, while lipid-soluble antioxidants protect cell membranes from lipid peroxidation.[31] These compounds may be synthesized in the body or obtained from the diet.[32] The different antioxidants are present at a wide range of concentrations in body fluids and tissues, with some such as glutathione or ubiquinone mostly present within cells, while others such as uric acid are more systemically distributed (see table below). Some antioxidants are only found in a few organisms, and can be pathogens or virulence factors.[50]

The interactions between these different antioxidants may be synergistic and interdependent.[51][52] The action of one antioxidant may therefore depend on the proper function of other members of the antioxidant system.[32] The amount of protection provided by any one antioxidant will also depend on its concentration, its reactivity towards the particular reactive oxygen species being considered, and the status of the antioxidants with which it interacts.[32]

Some compounds contribute to antioxidant defense by chelating transition metals and preventing them from catalyzing the production of free radicals in the cell. The ability to sequester iron for iron-binding proteins, such as transferrin and ferritin, is one such function.[44] Selenium and zinc are commonly referred to as antioxidant minerals, but these chemical elements have no antioxidant action themselves, but rather are required for the activity of antioxidant enzymes, such as glutathione reductase and superoxide dismutase. (See also selenium in biology and zinc in biology.)

Antioxidant Solubility Concentration in human serum (μM) Concentration in liver tissue (μmol/kg)
Ascorbic acid (vitamin C) Water 50–60[53] 260 (human)[54]
Glutathione Water 4[55] 6,400 (human)[54]
Lipoic acid Water 0.1–0.7[56] 4–5 (rat)[57]
Uric acid Water 200–400[58] 1,600 (human)[54]
Carotenes Lipid β-carotene: 0.5–1[59]

retinol (vitamin A): 1–3[60]

 5 (human, total carotenoids)[61]
α-Tocopherol (vitamin E) Lipid 10–40[60] 50 (human)[54]
Ubiquinol (coenzyme Q) Lipid 5[62] 200 (human)[63]

Uric acid edit

Uric acid has the highest concentration of any blood antioxidant[58] and provides over half of the total antioxidant capacity of human serum.[64] Uric acid's antioxidant activities are also complex, given that it does not react with some oxidants, such as superoxide, but does act against peroxynitrite,[65] peroxides, and hypochlorous acid.[66] Concerns over elevated UA's contribution to gout must be considered one of many risk factors.[67] By itself, UA-related risk of gout at high levels (415–530 μmol/L) is only 0.5% per year with an increase to 4.5% per year at UA supersaturation levels (535+ μmol/L).[68] Many of these aforementioned studies determined UA's antioxidant actions within normal physiological levels,[69][65] and some found antioxidant activity at levels as high as 285 μmol/L.[70]

Vitamin C edit

Ascorbic acid or vitamin C, an oxidation-reduction (redox) catalyst found in both animals and plants,[71] can reduce, and thereby neutralize, reactive oxygen species such as hydrogen peroxide.[71][72] In addition to its direct antioxidant effects, ascorbic acid is also a substrate for the redox enzyme ascorbate peroxidase, a function that is used in stress resistance in plants.[73] Ascorbic acid is present at high levels in all parts of plants and can reach concentrations of 20 millimolar in chloroplasts.[74]

Glutathione edit

 
The free radical mechanism of lipid peroxidation

Glutathione has antioxidant properties since the thiol group in its cysteine moiety is a reducing agent and can be reversibly oxidized and reduced. In cells, glutathione is maintained in the reduced form by the enzyme glutathione reductase and in turn reduces other metabolites and enzyme systems, such as ascorbate in the glutathione-ascorbate cycle, glutathione peroxidases and glutaredoxins, as well as reacting directly with oxidants.[75] Due to its high concentration and its central role in maintaining the cell's redox state, glutathione is one of the most important cellular antioxidants.[76] In some organisms glutathione is replaced by other thiols, such as by mycothiol in the Actinomycetes, bacillithiol in some gram-positive bacteria,[77][78] or by trypanothione in the Kinetoplastids.[79][80]

Vitamin E edit

Vitamin E is the collective name for a set of eight related tocopherols and tocotrienols, which are fat-soluble vitamins with antioxidant properties.[81][82] Of these, α-tocopherol has been most studied as it has the highest bioavailability, with the body preferentially absorbing and metabolising this form.[83]

It has been claimed that the α-tocopherol form is the most important lipid-soluble antioxidant, and that it protects membranes from oxidation by reacting with lipid radicals produced in the lipid peroxidation chain reaction.[81][84] This removes the free radical intermediates and prevents the propagation reaction from continuing. This reaction produces oxidised α-tocopheroxyl radicals that can be recycled back to the active reduced form through reduction by other antioxidants, such as ascorbate, retinol or ubiquinol.[85] This is in line with findings showing that α-tocopherol, but not water-soluble antioxidants, efficiently protects glutathione peroxidase 4 (GPX4)-deficient cells from cell death.[86] GPx4 is the only known enzyme that efficiently reduces lipid-hydroperoxides within biological membranes.

However, the roles and importance of the various forms of vitamin E are presently unclear,[87][88] and it has even been suggested that the most important function of α-tocopherol is as a signaling molecule, with this molecule having no significant role in antioxidant metabolism.[89][90] The functions of the other forms of vitamin E are even less well understood, although γ-tocopherol is a nucleophile that may react with electrophilic mutagens,[83] and tocotrienols may be important in protecting neurons from damage.[91]

Pro-oxidant activities edit

Further information: Pro-oxidant

Antioxidants that are reducing agents can also act as pro-oxidants. For example, vitamin C has antioxidant activity when it reduces oxidizing substances such as hydrogen peroxide;[92] however, it will also reduce metal ions such as iron and copper[93] that generate free radicals through the Fenton reaction.[35][94] While ascorbic acid is effective antioxidant, it can also oxidatively change the flavor and color of food. With the presence of transition metals, there are low concentrations of ascorbic acid that can act as a radical scavenger in the Fenton reaction.[93]

2 Fe3+ + Ascorbate → 2 Fe2+ + Dehydroascorbate

2 Fe2+ + 2 H2O2 → 2 Fe3+ + 2 OH· + 2 OH

The relative importance of the antioxidant and pro-oxidant activities of antioxidants is an area of current research, but vitamin C, which exerts its effects as a vitamin by oxidizing polypeptides, appears to have a mostly antioxidant action in the human body.[94]

Enzyme systems edit

 
Enzymatic pathway for detoxification of reactive oxygen species

As with the chemical antioxidants, cells are protected against oxidative stress by an interacting network of antioxidant enzymes.[30][31] Here, the superoxide released by processes such as oxidative phosphorylation is first converted to hydrogen peroxide and then further reduced to give water. This detoxification pathway is the result of multiple enzymes, with superoxide dismutases catalysing the first step and then catalases and various peroxidases removing hydrogen peroxide. As with antioxidant metabolites, the contributions of these enzymes to antioxidant defenses can be hard to separate from one another, but the generation of transgenic mice lacking just one antioxidant enzyme can be informative.[95]

Superoxide dismutase, catalase, and peroxiredoxins edit

Superoxide dismutases (SODs) are a class of closely related enzymes that catalyze the breakdown of the superoxide anion into oxygen and hydrogen peroxide.[96][97] SOD enzymes are present in almost all aerobic cells and in extracellular fluids.[98] Superoxide dismutase enzymes contain metal ion cofactors that, depending on the isozyme, can be copper, zinc, manganese or iron. In humans, the copper/zinc SOD is present in the cytosol, while manganese SOD is present in the mitochondrion.[97] There also exists a third form of SOD in extracellular fluids, which contains copper and zinc in its active sites.[99] The mitochondrial isozyme seems to be the most biologically important of these three, since mice lacking this enzyme die soon after birth.[100] In contrast, the mice lacking copper/zinc SOD (Sod1) are viable but have numerous pathologies and a reduced lifespan (see article on superoxide), while mice without the extracellular SOD have minimal defects (sensitive to hyperoxia).[95][101] In plants, SOD isozymes are present in the cytosol and mitochondria, with an iron SOD found in chloroplasts that is absent from vertebrates and yeast.[102]

Catalases are enzymes that catalyse the conversion of hydrogen peroxide to water and oxygen, using either an iron or manganese cofactor.[103][104] This protein is localized to peroxisomes in most eukaryotic cells.[105] Catalase is an unusual enzyme since, although hydrogen peroxide is its only substrate, it follows a ping-pong mechanism. Here, its cofactor is oxidised by one molecule of hydrogen peroxide and then regenerated by transferring the bound oxygen to a second molecule of substrate.[106] Despite its apparent importance in hydrogen peroxide removal, humans with genetic deficiency of catalase — "acatalasemia" — or mice genetically engineered to lack catalase completely, experience few ill effects.[107][108]

 
Decameric structure of AhpC, a bacterial 2-cysteine peroxiredoxin from Salmonella typhimurium[109]

Peroxiredoxins are peroxidases that catalyze the reduction of hydrogen peroxide, organic hydroperoxides, as well as peroxynitrite.[110] They are divided into three classes: typical 2-cysteine peroxiredoxins; atypical 2-cysteine peroxiredoxins; and 1-cysteine peroxiredoxins.[111] These enzymes share the same basic catalytic mechanism, in which a redox-active cysteine (the peroxidatic cysteine) in the active site is oxidized to a sulfenic acid by the peroxide substrate.[112] Over-oxidation of this cysteine residue in peroxiredoxins inactivates these enzymes, but this can be reversed by the action of sulfiredoxin.[113] Peroxiredoxins seem to be important in antioxidant metabolism, as mice lacking peroxiredoxin 1 or 2 have shortened lifespans and develop hemolytic anaemia, while plants use peroxiredoxins to remove hydrogen peroxide generated in chloroplasts.[114][115][116]

Thioredoxin and glutathione systems edit

The thioredoxin system contains the 12-kDa protein thioredoxin and its companion thioredoxin reductase.[117] Proteins related to thioredoxin are present in all sequenced organisms. Plants, such as Arabidopsis thaliana, have a particularly great diversity of isoforms.[118] The active site of thioredoxin consists of two neighboring cysteines, as part of a highly conserved CXXC motif, that can cycle between an active dithiol form (reduced) and an oxidized disulfide form. In its active state, thioredoxin acts as an efficient reducing agent, scavenging reactive oxygen species and maintaining other proteins in their reduced state.[119] After being oxidized, the active thioredoxin is regenerated by the action of thioredoxin reductase, using NADPH as an electron donor.[120]

The glutathione system includes glutathione, glutathione reductase, glutathione peroxidases, and glutathione S-transferases.[76] This system is found in animals, plants and microorganisms.[76][121] Glutathione peroxidase is an enzyme containing four selenium-cofactors that catalyzes the breakdown of hydrogen peroxide and organic hydroperoxides. There are at least four different glutathione peroxidase isozymes in animals.[122] Glutathione peroxidase 1 is the most abundant and is a very efficient scavenger of hydrogen peroxide, while glutathione peroxidase 4 is most active with lipid hydroperoxides. Surprisingly, glutathione peroxidase 1 is dispensable, as mice lacking this enzyme have normal lifespans,[123] but they are hypersensitive to induced oxidative stress.[124] In addition, the glutathione S-transferases show high activity with lipid peroxides.[125] These enzymes are at particularly high levels in the liver and also serve in detoxification metabolism.[126]

Health research edit

Relation to diet edit

The dietary antioxidant vitamins A, C, and E are essential and required in specific daily amounts to prevent diseases.[3][127][128] Polyphenols, which have antioxidant properties in vitro due to their free hydroxy groups,[129] are extensively metabolized by catechol-O-methyltransferase which methylates free hydroxyl groups, and thereby prevents them from acting as antioxidants in vivo.[130][131]

Interactions edit

Common pharmaceuticals (and supplements) with antioxidant properties may interfere with the efficacy of certain anticancer medication and radiation therapy.[132] Pharmaceuticals and supplements that have antioxidant properties suppress the formation of free radicals by inhibiting oxidation processes. Radiation therapy induce oxidative stress that damages essential components of cancer cells, such as proteins, nucleic acids, and lipids that comprise cell membranes.[133]

Adverse effects edit

See also: Antioxidative stress
 
Structure of the metal chelator phytic acid

Relatively strong reducing acids can have antinutrient effects by binding to dietary minerals such as iron and zinc in the gastrointestinal tract and preventing them from being absorbed.[134] Examples are oxalic acid, tannins and phytic acid, which are high in plant-based diets.[135] Calcium and iron deficiencies are not uncommon in diets in developing countries where less meat is eaten and there is high consumption of phytic acid from beans and unleavened whole grain bread. However, germination, soaking, or microbial fermentation are all household strategies that reduce the phytate and polyphenol content of unrefined cereal. Increases in Fe, Zn and Ca absorption have been reported in adults fed dephytinized cereals compared with cereals containing their native phytate.[136]

High doses of some antioxidants may have harmful long-term effects. The Beta-Carotene and Retinol Efficacy Trial (CARET) study of lung cancer patients found that smokers given supplements containing beta-carotene and vitamin A had increased rates of lung cancer.[140] Subsequent studies confirmed these adverse effects.[141] These harmful effects may also be seen in non-smokers, as one meta-analysis including data from approximately 230,000 patients showed that β-carotene, vitamin A or vitamin E supplementation is associated with increased mortality, but saw no significant effect from vitamin C.[142] No health risk was seen when all the randomized controlled studies were examined together, but an increase in mortality was detected when only high-quality and low-bias risk trials were examined separately.[143] As the majority of these low-bias trials dealt with either elderly people, or people with disease, these results may not apply to the general population.[144] This meta-analysis was later repeated and extended by the same authors, confirming the previous results.[143] These two publications are consistent with some previous meta-analyses that also suggested that vitamin E supplementation increased mortality,[145] and that antioxidant supplements increased the risk of colon cancer.[146] Beta-carotene may also increase lung cancer.[146][147] Overall, the large number of clinical trials carried out on antioxidant supplements suggest that either these products have no effect on health, or that they cause a small increase in mortality in elderly or vulnerable populations.[127][148][142]

Exercise and muscle soreness edit

A 2017 review showed that taking antioxidant dietary supplements before or after exercise is unlikely to produce a noticeable reduction in muscle soreness after a person exercises.[149]

Levels in food edit

Further information: List of antioxidants in food and Polyphenol antioxidant
 
Fruits and vegetables are good sources of antioxidant vitamins C and E.

Antioxidant vitamins are found in vegetables, fruits, eggs, legumes and nuts. Vitamins A, C, and E can be destroyed by long-term storage or prolonged cooking.[150] The effects of cooking and food processing are complex, as these processes can also increase the bioavailability of antioxidants, such as some carotenoids in vegetables.[151] Processed food contains fewer antioxidant vitamins than fresh and uncooked foods, as preparation exposes food to heat and oxygen.[152]

Antioxidant vitamins Foods containing high levels of antioxidant vitamins[139][153][154]
Vitamin C (ascorbic acid) Fresh or frozen fruits and vegetables
Vitamin E (tocopherols, tocotrienols) Vegetable oils, nuts, and seeds
Carotenoids (carotenes as provitamin A) Fruit, vegetables and eggs

Other antioxidants are not obtained from the diet, but instead are made in the body. For example, ubiquinol (coenzyme Q) is poorly absorbed from the gut and is made through the mevalonate pathway.[63] Another example is glutathione, which is made from amino acids. As any glutathione in the gut is broken down to free cysteine, glycine and glutamic acid before being absorbed, even large oral intake has little effect on the concentration of glutathione in the body.[155][156] Although large amounts of sulfur-containing amino acids such as acetylcysteine can increase glutathione,[157] no evidence exists that eating high levels of these glutathione precursors is beneficial for healthy adults.[158]

Measurement and invalidation of ORAC edit

Measurement of polyphenol and carotenoid content in food is not a straightforward process, as antioxidants collectively are a diverse group of compounds with different reactivities to various reactive oxygen species. In food science analyses in vitro, the oxygen radical absorbance capacity (ORAC) was once an industry standard for estimating antioxidant strength of whole foods, juices and food additives, mainly from the presence of polyphenols.[159][160] Earlier measurements and ratings by the United States Department of Agriculture were withdrawn in 2012 as biologically irrelevant to human health, referring to an absence of physiological evidence for polyphenols having antioxidant properties in vivo.[161] Consequently, the ORAC method, derived only from in vitro experiments, is no longer considered relevant to human diets or biology, as of 2010.[161]

Alternative in vitro measurements of antioxidant content in foods – also based on the presence of polyphenols – include the Folin-Ciocalteu reagent, and the Trolox equivalent antioxidant capacity assay.[162]

References edit

  1. ^ Klemchuk, Peter P. (2000). "Antioxidants". Ullmann's Encyclopedia of Industrial Chemistry. doi:10.1002/14356007.a03_091. ISBN 3527306730.
  2. ^ a b Helberg, Julian; Pratt, Derek A. (2021). "Autoxidation vs. Antioxidants – the fight for forever". Chemical Society Reviews. 50 (13): 7343–7358. doi:10.1039/D1CS00265A. PMID 34037013. S2CID 235200305.
  3. ^ a b c "Antioxidants: In Depth". National Center for Complementary and Integrative Health, US National Institutes of Health. 1 November 2013. Retrieved 17 March 2023.
  4. ^ Fang, Yun-Zhong; Yang, Sheng; Wu, Guoyao (2002). "Free radicals, antioxidants, and nutrition". Nutrition. 18 (10): 872–879. doi:10.1016/s0899-9007(02)00916-4. PMID 12361782.
  5. ^ Benzie IF (September 2003). "Evolution of dietary antioxidants". Comparative Biochemistry and Physiology A. 136 (1): 113–26. doi:10.1016/S1095-6433(02)00368-9. hdl:10397/34754. PMID 14527634.
  6. ^ Mattill HA (1947). "Antioxidants". Annual Review of Biochemistry. 16: 177–92. doi:10.1146/annurev.bi.16.070147.001141. PMID 20259061.
  7. ^ German JB (1999). "Food Processing and Lipid Oxidation". Impact of Processing on Food Safety. Advances in Experimental Medicine and Biology. Vol. 459. pp. 23–50. doi:10.1007/978-1-4615-4853-9_3. ISBN 978-0-306-46051-7. PMID 10335367.
  8. ^ Jacob RA (1996). Three eras of vitamin C discovery. Subcellular Biochemistry. Vol. 25. pp. 1–16. doi:10.1007/978-1-4613-0325-1_1. ISBN 978-1-4613-7998-0. PMID 8821966.
  9. ^ Knight JA (1998). "Free radicals: their history and current status in aging and disease". Annals of Clinical and Laboratory Science. 28 (6): 331–46. PMID 9846200.
  10. ^ Moureu C, Dufraisse C (1922). "Sur l'autoxydation: Les antioxygènes". Comptes Rendus des Séances et Mémoires de la Société de Biologie (in French). 86: 321–322.
  11. ^ Wolf G (March 2005). "The discovery of the antioxidant function of vitamin E: the contribution of Henry A. Mattill". The Journal of Nutrition. 135 (3): 363–6. doi:10.1093/jn/135.3.363. PMID 15735064.
  12. ^ Kader AA, Zagory D, Kerbel EL (1989). "Modified atmosphere packaging of fruits and vegetables". Critical Reviews in Food Science and Nutrition. 28 (1): 1–30. doi:10.1080/10408398909527490. PMID 2647417.
  13. ^ Zallen EM, Hitchcock MJ, Goertz GE (December 1975). "Chilled food systems. Effects of chilled holding on quality of beef loaves". Journal of the American Dietetic Association. 67 (6): 552–7. doi:10.1016/S0002-8223(21)14836-9. PMID 1184900.
  14. ^ Iverson F (June 1995). "Phenolic antioxidants: Health Protection Branch studies on butylated hydroxyanisole". Cancer Letters. 93 (1): 49–54. doi:10.1016/0304-3835(95)03787-W. PMID 7600543.
  15. ^ "E number index". UK food guide. from the original on 4 March 2007. Retrieved 5 March 2007.
  16. ^ Robards K, Kerr AF, Patsalides E (February 1988). "Rancidity and its Measurement in Edible Oils and Snack Foods. A review". The Analyst. 113 (2): 213–24. Bibcode:1988Ana...113..213R. doi:10.1039/an9881300213. PMID 3288002.
  17. ^ Del Carlo M, Sacchetti G, Di Mattia C, Compagnone D, Mastrocola D, Liberatore L, Cichelli A (June 2004). "Contribution of the phenolic fraction to the antioxidant activity and oxidative stability of olive oil". Journal of Agricultural and Food Chemistry. 52 (13): 4072–9. doi:10.1021/jf049806z. PMID 15212450.
  18. ^ a b Frankel, Edwin N. (1 January 2012), Frankel, Edwin N. (ed.), "Chapter 3 - Photooxidation of unsaturated fats", Lipid Oxidation (Second Edition), Oily Press Lipid Library Series, Woodhead Publishing, pp. 51–66, ISBN 978-0-9531949-8-8, retrieved 15 April 2023
  19. ^ "Final report on the amended safety assessment of Propyl Gallate". International Journal of Toxicology. 26 (3_suppl): 89–118. 2007. doi:10.1080/10915810701663176. PMID 18080874. S2CID 39562131. Propyl Gallate is a generally recognized as safe (GRAS) antioxidant to protect fats, oils, and fat-containing food from rancidity that results from the formation of peroxides.
  20. ^ Débora, Jackeline; Cleide, Viviane; Luciana, Oliveira; Rosemeire, Aparecida (7 August 2019). "Polyphenols as natural antioxidants in cosmetics applications". Journal of Cosmetic Dermatology. 19 (1): 33–37. doi:10.1111/jocd.13093. PMID 31389656. S2CID 201156301.
  21. ^ Boozer CE, Hammond GS, Hamilton CE, Sen JN (1955). "Air Oxidation of Hydrocarbons.1II. The Stoichiometry and Fate of Inhibitors in Benzene and Chlorobenzene". Journal of the American Chemical Society. 77 (12): 3233–7. doi:10.1021/ja01617a026.
  22. ^ a b . Innospec Chemicals. Archived from the original on 15 October 2006. Retrieved 27 February 2007.
  23. ^ . SpecialChem Adhesives. Archived from the original on 11 February 2007. Retrieved 27 February 2007.
  24. ^ Liu, Runzeng; Mabury, Scott A. (6 October 2020). "Synthetic Phenolic Antioxidants: A Review of Environmental Occurrence, Fate, Human Exposure, and Toxicity". Environmental Science & Technology. 54 (19): 11706–11719. Bibcode:2020EnST...5411706L. doi:10.1021/acs.est.0c05077. PMID 32915564. S2CID 221637214.
  25. ^ Xu, Jing; Hao, Yanfen; Yang, Zhiruo; Li, Wenjuan; Xie, Wenjing; Huang, Yani; Wang, Deliang; He, Yuqing; Liang, Yong; Matsiko, Julius; Wang, Pu (7 November 2022). "Rubber Antioxidants and Their Transformation Products: Environmental Occurrence and Potential Impact". International Journal of Environmental Research and Public Health. 19 (21): 14595. doi:10.3390/ijerph192114595. PMC 9657274. PMID 36361475.
  26. ^ a b Li, Chao; Cui, Xinyi; Chen, Yi; Liao, Chunyang; Ma, Lena Q (February 2019). "Synthetic phenolic antioxidants and their major metabolites in human fingernail". Environmental Research. 169: 308–314. Bibcode:2019ER....169..308L. doi:10.1016/j.envres.2018.11.020. PMID 30500685. S2CID 56486425.
  27. ^ Liu, Runzeng; Mabury, Scott A. (11 September 2020). "Synthetic Phenolic Antioxidants: A Review of Environmental Occurrence, Fate, Human Exposure, and Toxicity". Environ. Sci. Technol. 54 (19): 11706–11719. Bibcode:2020EnST...5411706L. doi:10.1021/acs.est.0c05077. PMID 32915564. S2CID 221637214.
  28. ^ Wang, Wanyi; Xiong, Ping; Zhang, He; Zhu, Qingqing; Liao, Chunyang; Jiang, Guibin (1 October 2021). "Analysis, occurrence, toxicity and environmental health risks of synthetic phenolic antioxidants: A review". Environmental Research. 201: 111531. Bibcode:2021ER....201k1531W. doi:10.1016/j.envres.2021.111531. ISSN 0013-9351. PMID 34146526.
  29. ^ Zhang, Zi-Feng; Zhang, Xue; Sverko, Ed; Marvin, Christopher H.; Jobst, Karl J.; Smyth, Shirley Anne; Li, Yi-Fan (11 February 2020). "Determination of Diphenylamine Antioxidants in Wastewater/Biosolids and Sediment". Environmental Science & Technology Letters. 7 (2): 102–110. doi:10.1021/acs.estlett.9b00796. ISSN 2328-8930. S2CID 213719260.
  30. ^ a b c Davies KJ (1995). "Oxidative stress: the paradox of aerobic life". Biochemical Society Symposium. 61: 1–31. doi:10.1042/bss0610001. PMID 8660387.
  31. ^ a b c d e Sies H (March 1997). "Oxidative stress: oxidants and antioxidants". Experimental Physiology. 82 (2): 291–5. doi:10.1113/expphysiol.1997.sp004024. PMID 9129943. S2CID 20240552.
  32. ^ a b c d Vertuani S, Angusti A, Manfredini S (2004). "The Antioxidants and Pro-Antioxidants Network: an Overview". Current Pharmaceutical Design. 10 (14): 1677–94. doi:10.2174/1381612043384655. PMID 15134565.
  33. ^ Rhee SG (June 2006). "Cell signaling. H2O2, a necessary evil for cell signaling". Science. 312 (5782): 1882–3. doi:10.1126/science.1130481. PMID 16809515. S2CID 83598498.
  34. ^ Valko M, Leibfritz D, Moncol J, Cronin MT, Mazur M, Telser J (2007). "Free radicals and antioxidants in normal physiological functions and human disease". The International Journal of Biochemistry & Cell Biology. 39 (1): 44–84. doi:10.1016/j.biocel.2006.07.001. PMID 16978905.
  35. ^ a b Stohs SJ, Bagchi D (February 1995). "Oxidative mechanisms in the toxicity of metal ions" (PDF). Free Radical Biology & Medicine (Submitted manuscript). 18 (2): 321–36. CiteSeerX 10.1.1.461.6417. doi:10.1016/0891-5849(94)00159-H. PMID 7744317.
  36. ^ Nakabeppu Y, Sakumi K, Sakamoto K, Tsuchimoto D, Tsuzuki T, Nakatsu Y (April 2006). "Mutagenesis and carcinogenesis caused by the oxidation of nucleic acids". Biological Chemistry. 387 (4): 373–9. doi:10.1515/BC.2006.050. PMID 16606334. S2CID 20217256.
  37. ^ Valko M, Izakovic M, Mazur M, Rhodes CJ, Telser J (November 2004). "Role of oxygen radicals in DNA damage and cancer incidence". Molecular and Cellular Biochemistry. 266 (1–2): 37–56. doi:10.1023/B:MCBI.0000049134.69131.89. PMID 15646026. S2CID 207547763.
  38. ^ Stadtman ER (August 1992). "Protein oxidation and aging". Science. 257 (5074): 1220–4. Bibcode:1992Sci...257.1220S. doi:10.1126/science.1355616. PMID 1355616.
  39. ^ Raha S, Robinson BH (October 2000). "Mitochondria, oxygen free radicals, disease and ageing". Trends in Biochemical Sciences. 25 (10): 502–8. doi:10.1016/S0968-0004(00)01674-1. PMID 11050436.
  40. ^ Lenaz G (2001). "The mitochondrial production of reactive oxygen species: mechanisms and implications in human pathology". IUBMB Life. 52 (3–5): 159–64. doi:10.1080/15216540152845957. PMID 11798028. S2CID 45366190.
  41. ^ Finkel T, Holbrook NJ (November 2000). "Oxidants, oxidative stress and the biology of ageing". Nature. 408 (6809): 239–47. Bibcode:2000Natur.408..239F. doi:10.1038/35041687. PMID 11089981. S2CID 2502238.
  42. ^ Hirst J, King MS, Pryde KR (October 2008). "The production of reactive oxygen species by complex I". Biochemical Society Transactions. 36 (Pt 5): 976–80. doi:10.1042/BST0360976. PMID 18793173.
  43. ^ Seaver LC, Imlay JA (November 2004). "Are respiratory enzymes the primary sources of intracellular hydrogen peroxide?". The Journal of Biological Chemistry. 279 (47): 48742–50. doi:10.1074/jbc.M408754200. PMID 15361522.
  44. ^ a b Imlay JA (2003). "Pathways of oxidative damage". Annual Review of Microbiology. 57: 395–418. doi:10.1146/annurev.micro.57.030502.090938. PMID 14527285.
  45. ^ Demmig-Adams B, Adams WW (December 2002). "Antioxidants in photosynthesis and human nutrition". Science. 298 (5601): 2149–53. Bibcode:2002Sci...298.2149D. doi:10.1126/science.1078002. PMID 12481128. S2CID 27486669.
  46. ^ Krieger-Liszkay A (January 2005). "Singlet oxygen production in photosynthesis". Journal of Experimental Botany. 56 (411): 337–46. CiteSeerX 10.1.1.327.9651. doi:10.1093/jxb/erh237. PMID 15310815.
  47. ^ Kupper FC, Carpenter LJ, McFiggans GB, Palmer CJ, Waite TJ, Boneberg E-M, Woitsch S, Weiller M, Abela R, Grolimund D, Potin P, Butler A, Luther GW, Kroneck PMH, Meyer-Klaucke W, Feiters MC (2008). "Iodide accumulation provides kelp with an inorganic antioxidant impacting atmospheric chemistry". Proceedings of the National Academy of Sciences. 105 (19): 6954–6958. Bibcode:2008PNAS..105.6954K. doi:10.1073/pnas.0709959105. ISSN 0027-8424. PMC 2383960. PMID 18458346.
  48. ^ Szabó I, Bergantino E, Giacometti GM (July 2005). "Light and oxygenic photosynthesis: energy dissipation as a protection mechanism against photo-oxidation". EMBO Reports. 6 (7): 629–34. doi:10.1038/sj.embor.7400460. PMC 1369118. PMID 15995679.
  49. ^ Kerfeld CA (October 2004). "Water-soluble carotenoid proteins of cyanobacteria" (PDF). Archives of Biochemistry and Biophysics (Submitted manuscript). 430 (1): 2–9. doi:10.1016/j.abb.2004.03.018. PMID 15325905. S2CID 25306222.
  50. ^ Miller RA, Britigan BE (January 1997). "Role of oxidants in microbial pathophysiology". Clinical Microbiology Reviews. 10 (1): 1–18. doi:10.1128/CMR.10.1.1. PMC 172912. PMID 8993856.
  51. ^ Chaudière J, Ferrari-Iliou R (1999). "Intracellular antioxidants: from chemical to biochemical mechanisms". Food and Chemical Toxicology. 37 (9–10): 949–62. doi:10.1016/S0278-6915(99)00090-3. PMID 10541450.
  52. ^ Sies H (July 1993). "Strategies of antioxidant defense". European Journal of Biochemistry. 215 (2): 213–9. doi:10.1111/j.1432-1033.1993.tb18025.x. PMID 7688300.
  53. ^ Khaw KT, Woodhouse P (June 1995). "Interrelation of vitamin C, infection, haemostatic factors, and cardiovascular disease". BMJ. 310 (6994): 1559–63. doi:10.1136/bmj.310.6994.1559. PMC 2549940. PMID 7787643.
  54. ^ a b c d Evelson P, Travacio M, Repetto M, Escobar J, Llesuy S, Lissi EA (April 2001). "Evaluation of total reactive antioxidant potential (TRAP) of tissue homogenates and their cytosols". Archives of Biochemistry and Biophysics. 388 (2): 261–6. doi:10.1006/abbi.2001.2292. PMID 11368163.
  55. ^ Morrison JA, Jacobsen DW, Sprecher DL, Robinson K, Khoury P, Daniels SR (November 1999). "Serum glutathione in adolescent males predicts parental coronary heart disease". Circulation. 100 (22): 2244–7. doi:10.1161/01.CIR.100.22.2244. PMID 10577998.
  56. ^ Teichert J, Preiss R (November 1992). "HPLC-methods for determination of lipoic acid and its reduced form in human plasma". International Journal of Clinical Pharmacology, Therapy, and Toxicology. 30 (11): 511–2. PMID 1490813.
  57. ^ Akiba S, Matsugo S, Packer L, Konishi T (May 1998). "Assay of protein-bound lipoic acid in tissues by a new enzymatic method". Analytical Biochemistry. 258 (2): 299–304. doi:10.1006/abio.1998.2615. PMID 9570844.
  58. ^ a b Glantzounis GK, Tsimoyiannis EC, Kappas AM, Galaris DA (2005). "Uric acid and oxidative stress". Current Pharmaceutical Design. 11 (32): 4145–51. doi:10.2174/138161205774913255. PMID 16375736.
  59. ^ El-Sohemy A, Baylin A, Kabagambe E, Ascherio A, Spiegelman D, Campos H (July 2002). "Individual carotenoid concentrations in adipose tissue and plasma as biomarkers of dietary intake". The American Journal of Clinical Nutrition. 76 (1): 172–9. doi:10.1093/ajcn/76.1.172. PMID 12081831.
  60. ^ a b Sowell AL, Huff DL, Yeager PR, Caudill SP, Gunter EW (March 1994). "Retinol, alpha-tocopherol, lutein/zeaxanthin, beta-cryptoxanthin, lycopene, alpha-carotene, trans-beta-carotene, and four retinyl esters in serum determined simultaneously by reversed-phase HPLC with multiwavelength detection". Clinical Chemistry. 40 (3): 411–6. doi:10.1093/clinchem/40.3.411. PMID 8131277.
  61. ^ Stahl W, Schwarz W, Sundquist AR, Sies H (April 1992). "cis-trans isomers of lycopene and beta-carotene in human serum and tissues". Archives of Biochemistry and Biophysics. 294 (1): 173–7. doi:10.1016/0003-9861(92)90153-N. PMID 1550343.
  62. ^ Zita C, Overvad K, Mortensen SA, Sindberg CD, Moesgaard S, Hunter DA (2003). "Serum coenzyme Q10 concentrations in healthy men supplemented with 30 mg or 100 mg coenzyme Q10 for two months in a randomised controlled study". BioFactors. 18 (1–4): 185–93. doi:10.1002/biof.5520180221. PMID 14695934. S2CID 19895215.
  63. ^ a b Turunen M, Olsson J, Dallner G (January 2004). "Metabolism and function of coenzyme Q". Biochimica et Biophysica Acta (BBA) - Biomembranes. 1660 (1–2): 171–99. doi:10.1016/j.bbamem.2003.11.012. PMID 14757233.
  64. ^ Becker BF (June 1993). "Towards the physiological function of uric acid". Free Radical Biology & Medicine. 14 (6): 615–31. doi:10.1016/0891-5849(93)90143-I. PMID 8325534.
  65. ^ a b Sautin YY, Johnson RJ (June 2008). "Uric acid: the oxidant-antioxidant paradox". Nucleosides, Nucleotides & Nucleic Acids. 27 (6): 608–19. doi:10.1080/15257770802138558. PMC 2895915. PMID 18600514.
  66. ^ Enomoto A, Endou H (September 2005). "Roles of organic anion transporters (OATs) and a urate transporter (URAT1) in the pathophysiology of human disease". Clinical and Experimental Nephrology. 9 (3): 195–205. doi:10.1007/s10157-005-0368-5. PMID 16189627. S2CID 6145651.
  67. ^ Eggebeen AT (September 2007). "Gout: an update". American Family Physician. 76 (6): 801–8. PMID 17910294.
  68. ^ Campion EW, Glynn RJ, DeLabry LO (March 1987). "Asymptomatic hyperuricemia. Risks and consequences in the Normative Aging Study". The American Journal of Medicine. 82 (3): 421–6. doi:10.1016/0002-9343(87)90441-4. PMID 3826098.
  69. ^ Baillie JK, Bates MG, Thompson AA, Waring WS, Partridge RW, Schnopp MF, Simpson A, Gulliver-Sloan F, Maxwell SR, Webb DJ (May 2007). "Endogenous urate production augments plasma antioxidant capacity in healthy lowland subjects exposed to high altitude". Chest. 131 (5): 1473–8. doi:10.1378/chest.06-2235. PMID 17494796.
  70. ^ Nazarewicz RR, Ziolkowski W, Vaccaro PS, Ghafourifar P (December 2007). "Effect of short-term ketogenic diet on redox status of human blood". Rejuvenation Research. 10 (4): 435–40. doi:10.1089/rej.2007.0540. PMID 17663642.
  71. ^ a b "Vitamin C". Micronutrient Information Center, Linus Pauling Institute, Oregon State University, Corvallis, OR. 1 July 2018. Retrieved 19 June 2019.
  72. ^ Padayatty SJ, Katz A, Wang Y, Eck P, Kwon O, Lee JH, Chen S, Corpe C, Dutta A, Dutta SK, Levine M (February 2003). "Vitamin C as an antioxidant: evaluation of its role in disease prevention". Journal of the American College of Nutrition. 22 (1): 18–35. doi:10.1080/07315724.2003.10719272. PMID 12569111. S2CID 21196776.
  73. ^ Shigeoka S, Ishikawa T, Tamoi M, Miyagawa Y, Takeda T, Yabuta Y, Yoshimura K (May 2002). "Regulation and function of ascorbate peroxidase isoenzymes". Journal of Experimental Botany. 53 (372): 1305–19. doi:10.1093/jexbot/53.372.1305. PMID 11997377.
  74. ^ Smirnoff N, Wheeler GL (2000). "Ascorbic acid in plants: biosynthesis and function". Critical Reviews in Biochemistry and Molecular Biology. 35 (4): 291–314. doi:10.1080/10409230008984166. PMID 11005203. S2CID 85060539.
  75. ^ Meister A (April 1994). "Glutathione-ascorbic acid antioxidant system in animals". The Journal of Biological Chemistry. 269 (13): 9397–400. doi:10.1016/S0021-9258(17)36891-6. PMID 8144521.
  76. ^ a b c Meister A, Anderson ME (1983). "Glutathione". Annual Review of Biochemistry. 52: 711–60. doi:10.1146/annurev.bi.52.070183.003431. PMID 6137189.
  77. ^ Gaballa A, Newton GL, Antelmann H, Parsonage D, Upton H, Rawat M, Claiborne A, Fahey RC, Helmann JD (April 2010). "Biosynthesis and functions of bacillithiol, a major low-molecular-weight thiol in Bacilli". Proceedings of the National Academy of Sciences of the United States of America. 107 (14): 6482–6. Bibcode:2010PNAS..107.6482G. doi:10.1073/pnas.1000928107. PMC 2851989. PMID 20308541.
  78. ^ Newton GL, Rawat M, La Clair JJ, Jothivasan VK, Budiarto T, Hamilton CJ, Claiborne A, Helmann JD, Fahey RC (September 2009). "Bacillithiol is an antioxidant thiol produced in Bacilli". Nature Chemical Biology. 5 (9): 625–627. doi:10.1038/nchembio.189. PMC 3510479. PMID 19578333.
  79. ^ Fahey RC (2001). "Novel thiols of prokaryotes". Annual Review of Microbiology. 55: 333–56. doi:10.1146/annurev.micro.55.1.333. PMID 11544359.
  80. ^ Fairlamb AH, Cerami A (1992). "Metabolism and functions of trypanothione in the Kinetoplastida". Annual Review of Microbiology. 46: 695–729. doi:10.1146/annurev.mi.46.100192.003403. PMID 1444271.
  81. ^ a b Herrera E, Barbas C (March 2001). "Vitamin E: action, metabolism and perspectives". Journal of Physiology and Biochemistry. 57 (2): 43–56. doi:10.1007/BF03179812. hdl:10637/720. PMID 11579997. S2CID 7272312.
  82. ^ Packer L, Weber SU, Rimbach G (February 2001). "Molecular aspects of alpha-tocotrienol antioxidant action and cell signalling". The Journal of Nutrition. 131 (2): 369S–73S. doi:10.1093/jn/131.2.369S. PMID 11160563.
  83. ^ a b Brigelius-Flohé R, Traber MG (July 1999). "Vitamin E: function and metabolism". FASEB Journal. 13 (10): 1145–55. CiteSeerX 10.1.1.337.5276. doi:10.1096/fasebj.13.10.1145. PMID 10385606. S2CID 7031925.
  84. ^ Traber MG, Atkinson J (July 2007). "Vitamin E, antioxidant and nothing more". Free Radical Biology & Medicine. 43 (1): 4–15. doi:10.1016/j.freeradbiomed.2007.03.024. PMC 2040110. PMID 17561088.
  85. ^ Wang X, Quinn PJ (July 1999). "Vitamin E and its function in membranes". Progress in Lipid Research. 38 (4): 309–36. doi:10.1016/S0163-7827(99)00008-9. PMID 10793887.
  86. ^ Seiler A, Schneider M, Förster H, Roth S, Wirth EK, Culmsee C, Plesnila N, Kremmer E, Rådmark O, Wurst W, Bornkamm GW, Schweizer U, Conrad M (September 2008). "Glutathione peroxidase 4 senses and translates oxidative stress into 12/15-lipoxygenase dependent- and AIF-mediated cell death". Cell Metabolism. 8 (3): 237–48. doi:10.1016/j.cmet.2008.07.005. PMID 18762024.
  87. ^ Brigelius-Flohé R, Davies KJ (July 2007). "Is vitamin E an antioxidant, a regulator of signal transduction and gene expression, or a 'junk' food? Comments on the two accompanying papers: "Molecular mechanism of alpha-tocopherol action" by A. Azzi and "Vitamin E, antioxidant and nothing more" by M. Traber and J. Atkinson". Free Radical Biology & Medicine. 43 (1): 2–3. doi:10.1016/j.freeradbiomed.2007.05.016. PMID 17561087.
  88. ^ Atkinson J, Epand RF, Epand RM (March 2008). "Tocopherols and tocotrienols in membranes: a critical review". Free Radical Biology & Medicine. 44 (5): 739–64. doi:10.1016/j.freeradbiomed.2007.11.010. PMID 18160049.
  89. ^ Azzi A (July 2007). "Molecular mechanism of alpha-tocopherol action". Free Radical Biology & Medicine. 43 (1): 16–21. doi:10.1016/j.freeradbiomed.2007.03.013. PMID 17561089.
  90. ^ Zingg JM, Azzi A (May 2004). . Current Medicinal Chemistry. 11 (9): 1113–33. doi:10.2174/0929867043365332. PMID 15134510. Archived from the original on 6 October 2011.
  91. ^ Sen CK, Khanna S, Roy S (March 2006). "Tocotrienols: Vitamin E beyond tocopherols". Life Sciences. 78 (18): 2088–98. doi:10.1016/j.lfs.2005.12.001. PMC 1790869. PMID 16458936.
  92. ^ Duarte TL, Lunec J (July 2005). "Review: When is an antioxidant not an antioxidant? A review of novel actions and reactions of vitamin C". Free Radical Research. 39 (7): 671–86. doi:10.1080/10715760500104025. PMID 16036346. S2CID 39962659.
  93. ^ a b Shen, Jiaqi; Griffiths, Paul T.; Campbell, Steven J.; Utinger, Battist; Kalberer, Markus; Paulson, Suzanne E. (1 April 2021). "Ascorbate oxidation by iron, copper and reactive oxygen species: review, model development, and derivation of key rate constants". Scientific Reports. 11 (1): 7417. Bibcode:2021NatSR..11.7417S. doi:10.1038/s41598-021-86477-8. ISSN 2045-2322. PMC 8016884. PMID 33795736.
  94. ^ a b Carr A, Frei B (June 1999). "Does vitamin C act as a pro-oxidant under physiological conditions?". FASEB Journal. 13 (9): 1007–24. doi:10.1096/fasebj.13.9.1007. PMID 10336883. S2CID 15426564.
  95. ^ a b Ho YS, Magnenat JL, Gargano M, Cao J (October 1998). "The nature of antioxidant defense mechanisms: a lesson from transgenic studies". Environmental Health Perspectives. 106 (Suppl 5): 1219–28. doi:10.2307/3433989. JSTOR 3433989. PMC 1533365. PMID 9788901.
  96. ^ Zelko IN, Mariani TJ, Folz RJ (August 2002). "Superoxide dismutase multigene family: a comparison of the CuZn-SOD (SOD1), Mn-SOD (SOD2), and EC-SOD (SOD3) gene structures, evolution, and expression". Free Radical Biology & Medicine. 33 (3): 337–49. doi:10.1016/S0891-5849(02)00905-X. PMID 12126755.
  97. ^ a b Bannister JV, Bannister WH, Rotilio G (1987). "Aspects of the structure, function, and applications of superoxide dismutase". CRC Critical Reviews in Biochemistry. 22 (2): 111–80. doi:10.3109/10409238709083738. PMID 3315461.
  98. ^ Johnson F, Giulivi C (2005). "Superoxide dismutases and their impact upon human health". Molecular Aspects of Medicine. 26 (4–5): 340–52. doi:10.1016/j.mam.2005.07.006. PMID 16099495.
  99. ^ Nozik-Grayck E, Suliman HB, Piantadosi CA (December 2005). "Extracellular superoxide dismutase". The International Journal of Biochemistry & Cell Biology. 37 (12): 2466–71. doi:10.1016/j.biocel.2005.06.012. PMID 16087389.
  100. ^ Melov S, Schneider JA, Day BJ, Hinerfeld D, Coskun P, Mirra SS, Crapo JD, Wallace DC (February 1998). "A novel neurological phenotype in mice lacking mitochondrial manganese superoxide dismutase". Nature Genetics. 18 (2): 159–63. doi:10.1038/ng0298-159. PMID 9462746. S2CID 20843002.
  101. ^ Reaume AG, Elliott JL, Hoffman EK, Kowall NW, Ferrante RJ, Siwek DF, Wilcox HM, Flood DG, Beal MF, Brown RH, Scott RW, Snider WD (May 1996). "Motor neurons in Cu/Zn superoxide dismutase-deficient mice develop normally but exhibit enhanced cell death after axonal injury". Nature Genetics. 13 (1): 43–7. doi:10.1038/ng0596-43. PMID 8673102. S2CID 13070253.
  102. ^ Van Camp W, Inzé D, Van Montagu M (1997). "The regulation and function of tobacco superoxide dismutases". Free Radical Biology & Medicine. 23 (3): 515–20. doi:10.1016/S0891-5849(97)00112-3. PMID 9214590.
  103. ^ Chelikani P, Fita I, Loewen PC (January 2004). "Diversity of structures and properties among catalases" (PDF). Cellular and Molecular Life Sciences (Submitted manuscript). 61 (2): 192–208. doi:10.1007/s00018-003-3206-5. hdl:10261/111097. PMID 14745498. S2CID 4411482.
  104. ^ Zámocký M, Koller F (1999). "Understanding the structure and function of catalases: clues from molecular evolution and in vitro mutagenesis". Progress in Biophysics and Molecular Biology. 72 (1): 19–66. doi:10.1016/S0079-6107(98)00058-3. PMID 10446501.
  105. ^ del Río LA, Sandalio LM, Palma JM, Bueno P, Corpas FJ (November 1992). "Metabolism of oxygen radicals in peroxisomes and cellular implications". Free Radical Biology & Medicine. 13 (5): 557–80. doi:10.1016/0891-5849(92)90150-F. PMID 1334030.
  106. ^ Hiner AN, Raven EL, Thorneley RN, García-Cánovas F, Rodríguez-López JN (July 2002). "Mechanisms of compound I formation in heme peroxidases". Journal of Inorganic Biochemistry. 91 (1): 27–34. doi:10.1016/S0162-0134(02)00390-2. PMID 12121759.
  107. ^ Mueller S, Riedel HD, Stremmel W (December 1997). "Direct evidence for catalase as the predominant H2O2 -removing enzyme in human erythrocytes". Blood. 90 (12): 4973–8. doi:10.1182/blood.V90.12.4973. PMID 9389716.
  108. ^ Ogata M (February 1991). "Acatalasemia". Human Genetics. 86 (4): 331–40. doi:10.1007/BF00201829. PMID 1999334.
  109. ^ Parsonage D, Youngblood D, Sarma G, Wood Z, Karplus P, Poole L (2005). "Analysis of the link between enzymatic activity and oligomeric state in AhpC, a bacterial peroxiredoxin". Biochemistry. 44 (31): 10583–92. doi:10.1021/bi050448i. PMC 3832347. PMID 16060667. PDB 1YEX
  110. ^ Rhee SG, Chae HZ, Kim K (June 2005). "Peroxiredoxins: a historical overview and speculative preview of novel mechanisms and emerging concepts in cell signaling". Free Radical Biology & Medicine. 38 (12): 1543–52. doi:10.1016/j.freeradbiomed.2005.02.026. PMID 15917183.
  111. ^ Wood ZA, Schröder E, Robin Harris J, Poole LB (January 2003). "Structure, mechanism and regulation of peroxiredoxins". Trends in Biochemical Sciences. 28 (1): 32–40. doi:10.1016/S0968-0004(02)00003-8. PMID 12517450.
  112. ^ Claiborne A, Yeh JI, Mallett TC, Luba J, Crane EJ, Charrier V, Parsonage D (November 1999). "Protein-sulfenic acids: diverse roles for an unlikely player in enzyme catalysis and redox regulation". Biochemistry. 38 (47): 15407–16. doi:10.1021/bi992025k. PMID 10569923. S2CID 29055779.
  113. ^ Jönsson TJ, Lowther WT (2007). "The peroxiredoxin repair proteins". Peroxiredoxin Systems. Subcellular Biochemistry. Vol. 44. pp. 115–41. doi:10.1007/978-1-4020-6051-9_6. ISBN 978-1-4020-6050-2. PMC 2391273. PMID 18084892.
  114. ^ Neumann CA, Krause DS, Carman CV, Das S, Dubey DP, Abraham JL, Bronson RT, Fujiwara Y, Orkin SH, Van Etten RA (July 2003). "Essential role for the peroxiredoxin Prdx1 in erythrocyte antioxidant defence and tumour suppression" (PDF). Nature. 424 (6948): 561–5. Bibcode:2003Natur.424..561N. doi:10.1038/nature01819. PMID 12891360. S2CID 3570549.
  115. ^ Lee TH, Kim SU, Yu SL, Kim SH, Park DS, Moon HB, Dho SH, Kwon KS, Kwon HJ, Han YH, Jeong S, Kang SW, Shin HS, Lee KK, Rhee SG, Yu DY (June 2003). "Peroxiredoxin II is essential for sustaining life span of erythrocytes in mice". Blood. 101 (12): 5033–8. doi:10.1182/blood-2002-08-2548. PMID 12586629.
  116. ^ Dietz KJ, Jacob S, Oelze ML, Laxa M, Tognetti V, de Miranda SM, Baier M, Finkemeier I (2006). "The function of peroxiredoxins in plant organelle redox metabolism". Journal of Experimental Botany. 57 (8): 1697–709. doi:10.1093/jxb/erj160. PMID 16606633.
  117. ^ Nordberg J, Arnér ES (December 2001). "Reactive oxygen species, antioxidants, and the mammalian thioredoxin system". Free Radical Biology & Medicine. 31 (11): 1287–312. doi:10.1016/S0891-5849(01)00724-9. PMID 11728801.
  118. ^ Vieira Dos Santos C, Rey P (July 2006). "Plant thioredoxins are key actors in the oxidative stress response". Trends in Plant Science. 11 (7): 329–34. doi:10.1016/j.tplants.2006.05.005. PMID 16782394.
  119. ^ Arnér ES, Holmgren A (October 2000). "Physiological functions of thioredoxin and thioredoxin reductase". European Journal of Biochemistry. 267 (20): 6102–9. doi:10.1046/j.1432-1327.2000.01701.x. PMID 11012661.
  120. ^ Mustacich D, Powis G (February 2000). "Thioredoxin reductase". The Biochemical Journal. 346 (1): 1–8. doi:10.1042/0264-6021:3460001. PMC 1220815. PMID 10657232.
  121. ^ Creissen G, Broadbent P, Stevens R, Wellburn AR, Mullineaux P (May 1996). "Manipulation of glutathione metabolism in transgenic plants". Biochemical Society Transactions. 24 (2): 465–9. doi:10.1042/bst0240465. PMID 8736785.
  122. ^ Brigelius-Flohé R (November 1999). "Tissue-specific functions of individual glutathione peroxidases". Free Radical Biology & Medicine. 27 (9–10): 951–65. doi:10.1016/S0891-5849(99)00173-2. PMID 10569628.
  123. ^ Ho YS, Magnenat JL, Bronson RT, Cao J, Gargano M, Sugawara M, Funk CD (June 1997). "Mice deficient in cellular glutathione peroxidase develop normally and show no increased sensitivity to hyperoxia". The Journal of Biological Chemistry. 272 (26): 16644–51. doi:10.1074/jbc.272.26.16644. PMID 9195979.
  124. ^ de Haan JB, Bladier C, Griffiths P, Kelner M, O'Shea RD, Cheung NS, Bronson RT, Silvestro MJ, Wild S, Zheng SS, Beart PM, Hertzog PJ, Kola I (August 1998). "Mice with a homozygous null mutation for the most abundant glutathione peroxidase, Gpx1, show increased susceptibility to the oxidative stress-inducing agents paraquat and hydrogen peroxide". The Journal of Biological Chemistry. 273 (35): 22528–36. doi:10.1074/jbc.273.35.22528. hdl:10536/DRO/DU:30101410. PMID 9712879.
  125. ^ Sharma R, Yang Y, Sharma A, Awasthi S, Awasthi YC (April 2004). "Antioxidant role of glutathione S-transferases: protection against oxidant toxicity and regulation of stress-mediated apoptosis". Antioxidants & Redox Signaling. 6 (2): 289–300. doi:10.1089/152308604322899350. PMID 15025930.
  126. ^ Hayes JD, Flanagan JU, Jowsey IR (2005). "Glutathione transferases". Annual Review of Pharmacology and Toxicology. 45: 51–88. doi:10.1146/annurev.pharmtox.45.120403.095857. PMID 15822171.
  127. ^ a b Stanner SA, Hughes J, Kelly CN, Buttriss J (May 2004). "A review of the epidemiological evidence for the 'antioxidant hypothesis'". Public Health Nutrition. 7 (3): 407–22. doi:10.1079/PHN2003543. PMID 15153272.
  128. ^ Food, Nutrition, Physical Activity, and the Prevention of Cancer: a Global Perspective 23 September 2015 at the Wayback Machine. World Cancer Research Fund (2007). ISBN 978-0-9722522-2-5.
  129. ^ Rice-Evans, Catherine A.; Miller, Nicholas J.; Paganga, George (1996). "Structure-antioxidant activity relationships of flavonoids and phenolic acids". Free Radical Biology and Medicine. 20 (7): 933–956. doi:10.1016/0891-5849(95)02227-9. PMID 8743980.
  130. ^ Del Rio D, Rodriguez-Mateos A, Spencer JP, Tognolini M, Borges G, Crozier A (May 2013). "Dietary (poly)phenolics in human health: structures, bioavailability, and evidence of protective effects against chronic diseases". Antioxidants & Redox Signaling. 18 (14): 1818–1892. doi:10.1089/ars.2012.4581. PMC 3619154. PMID 22794138.
  131. ^ "Flavonoids". Linus Pauling Institute, Oregon State University, Corvallis. 2016. Retrieved 24 July 2016.
  132. ^ Lemmo W (September 2014). "Potential interactions of prescription and over-the-counter medications having antioxidant capabilities with radiation and chemotherapy". International Journal of Cancer. 137 (11): 2525–33. doi:10.1002/ijc.29208. PMID 25220632. S2CID 205951215.
  133. ^ Forman, Henry Jay; Zhang, Hongqiao (30 June 2021). "Targeting oxidative stress in disease: promise and limitations of antioxidant therapy". Nature Reviews Drug Discovery. 20 (9): 689–709. doi:10.1038/s41573-021-00233-1. ISSN 1474-1784. PMC 8243062. PMID 34194012.
  134. ^ Hurrell RF (September 2003). "Influence of vegetable protein sources on trace element and mineral bioavailability". The Journal of Nutrition. 133 (9): 2973S–7S. doi:10.1093/jn/133.9.2973S. PMID 12949395.
  135. ^ Hunt JR (September 2003). "Bioavailability of iron, zinc, and other trace minerals from vegetarian diets". The American Journal of Clinical Nutrition. 78 (3 Suppl): 633S–639S. doi:10.1093/ajcn/78.3.633S. PMID 12936958.
  136. ^ Gibson RS, Perlas L, Hotz C (May 2006). "Improving the bioavailability of nutrients in plant foods at the household level". The Proceedings of the Nutrition Society. 65 (2): 160–8. doi:10.1079/PNS2006489. PMID 16672077.
  137. ^ a b Mosha TC, Gaga HE, Pace RD, Laswai HS, Mtebe K (June 1995). "Effect of blanching on the content of antinutritional factors in selected vegetables". Plant Foods for Human Nutrition. 47 (4): 361–7. doi:10.1007/BF01088275. PMID 8577655. S2CID 1118651.
  138. ^ Sandberg AS (December 2002). "Bioavailability of minerals in legumes". The British Journal of Nutrition. 88 (Suppl 3): S281–5. doi:10.1079/BJN/2002718. PMID 12498628.
  139. ^ a b Beecher GR (October 2003). "Overview of dietary flavonoids: nomenclature, occurrence and intake". The Journal of Nutrition. 133 (10): 3248S–3254S. doi:10.1093/jn/133.10.3248S. PMID 14519822.
  140. ^ Omenn GS, Goodman GE, Thornquist MD, Balmes J, Cullen MR, Glass A, Keogh JP, Meyskens FL, Valanis B, Williams JH, Barnhart S, Cherniack MG, Brodkin CA, Hammar S (November 1996). "Risk factors for lung cancer and for intervention effects in CARET, the Beta-Carotene and Retinol Efficacy Trial" (PDF). Journal of the National Cancer Institute. 88 (21): 1550–9. doi:10.1093/jnci/88.21.1550. PMID 8901853.
  141. ^ Albanes D (June 1999). "Beta-carotene and lung cancer: a case study". The American Journal of Clinical Nutrition. 69 (6): 1345S–50S. doi:10.1093/ajcn/69.6.1345S. PMID 10359235.
  142. ^ a b Bjelakovic G, Nikolova D, Gluud LL, Simonetti RG, Gluud C (February 2007). "Mortality in randomized trials of antioxidant supplements for primary and secondary prevention: systematic review and meta-analysis". JAMA. 297 (8): 842–57. doi:10.1001/jama.297.8.842. PMID 17327526.
  143. ^ a b Bjelakovic G, Nikolova D, Gluud LL, Simonetti RG, Gluud C (14 March 2012). "Antioxidant supplements for prevention of mortality in healthy participants and patients with various diseases". The Cochrane Database of Systematic Reviews. 2012 (3): CD007176. doi:10.1002/14651858.CD007176.pub2. hdl:10138/136201. PMC 8407395. PMID 22419320.
  144. ^ Study Citing Antioxidant Vitamin Risks Based On Flawed Methodology, Experts Argue News release from Oregon State University published on ScienceDaily. Retrieved 19 April 2007
  145. ^ Miller ER, Pastor-Barriuso R, Dalal D, Riemersma RA, Appel LJ, Guallar E (January 2005). "Meta-analysis: high-dosage vitamin E supplementation may increase all-cause mortality". Annals of Internal Medicine. 142 (1): 37–46. doi:10.7326/0003-4819-142-1-200501040-00110. PMID 15537682.
  146. ^ a b Bjelakovic G, Nagorni A, Nikolova D, Simonetti RG, Bjelakovic M, Gluud C (July 2006). "Meta-analysis: antioxidant supplements for primary and secondary prevention of colorectal adenoma". Alimentary Pharmacology & Therapeutics. 24 (2): 281–91. doi:10.1111/j.1365-2036.2006.02970.x. PMID 16842454. S2CID 20452618.
  147. ^ Cortés-Jofré M, Rueda JR, Asenjo-Lobos C, Madrid E, Bonfill Cosp X (March 2020). "Drugs for preventing lung cancer in healthy people". The Cochrane Database of Systematic Reviews. 2020 (3): CD002141. doi:10.1002/14651858.CD002141.pub3. PMC 7059884. PMID 32130738.
  148. ^ Shenkin A (February 2006). "The key role of micronutrients". Clinical Nutrition. 25 (1): 1–13. doi:10.1016/j.clnu.2005.11.006. PMID 16376462.
  149. ^ Ranchordas, Mayur K.; Rogerson, David; Soltani, Hora; Costello, Joseph T. (14 December 2017). "Antioxidants for preventing and reducing muscle soreness after exercise". The Cochrane Database of Systematic Reviews. 2017 (12): CD009789. doi:10.1002/14651858.CD009789.pub2. ISSN 1469-493X. PMC 6486214. PMID 29238948.
  150. ^ Rodriguez-Amaya DB (2003). "Food carotenoids: analysis, composition and alterations during storage and processing of foods". Forum of Nutrition. 56: 35–7. PMID 15806788.
  151. ^ Maiani G, Castón MJ, Catasta G, Toti E, Cambrodón IG, Bysted A, Granado-Lorencio F, Olmedilla-Alonso B, Knuthsen P, Valoti M, Böhm V, Mayer-Miebach E, Behsnilian D, Schlemmer U (September 2009). . Molecular Nutrition & Food Research. 53 (Suppl 2): S194–218. doi:10.1002/mnfr.200800053. hdl:10261/77697. PMID 19035552. Archived from the original on 27 September 2018. Retrieved 18 April 2017.
  152. ^ Henry CJ, Heppell N (February 2002). "Nutritional losses and gains during processing: future problems and issues". The Proceedings of the Nutrition Society. 61 (1): 145–8. doi:10.1079/PNS2001142. PMID 12002789.
  153. ^ "Antioxidants and Cancer Prevention: Fact Sheet". National Cancer Institute. from the original on 4 March 2007. Retrieved 27 February 2007.
  154. ^ Ortega R (December 2006). "Importance of functional foods in the Mediterranean diet". Public Health Nutrition. 9 (8A): 1136–40. doi:10.1017/S1368980007668530. PMID 17378953.
  155. ^ Witschi A, Reddy S, Stofer B, Lauterburg BH (1992). "The systemic availability of oral glutathione". European Journal of Clinical Pharmacology. 43 (6): 667–9. doi:10.1007/BF02284971. PMID 1362956. S2CID 27606314.
  156. ^ Flagg EW, Coates RJ, Eley JW, Jones DP, Gunter EW, Byers TE, Block GS, Greenberg RS (1994). "Dietary glutathione intake in humans and the relationship between intake and plasma total glutathione level". Nutrition and Cancer. 21 (1): 33–46. doi:10.1080/01635589409514302. PMID 8183721.
  157. ^ Dodd S, Dean O, Copolov DL, Malhi GS, Berk M (December 2008). "N-acetylcysteine for antioxidant therapy: pharmacology and clinical utility". Expert Opinion on Biological Therapy. 8 (12): 1955–62. doi:10.1517/14728220802517901. PMID 18990082. S2CID 74736842.
  158. ^ van de Poll MC, Dejong CH, Soeters PB (June 2006). "Adequate range for sulfur-containing amino acids and biomarkers for their excess: lessons from enteral and parenteral nutrition". The Journal of Nutrition. 136 (6 Suppl): 1694S–1700S. doi:10.1093/jn/136.6.1694S. PMID 16702341.
  159. ^ Cao G, Alessio HM, Cutler RG (March 1993). "Oxygen-radical absorbance capacity assay for antioxidants". Free Radical Biology & Medicine. 14 (3): 303–11. doi:10.1016/0891-5849(93)90027-R. PMID 8458588.
  160. ^ Ou B, Hampsch-Woodill M, Prior RL (October 2001). "Development and validation of an improved oxygen radical absorbance capacity assay using fluorescein as the fluorescent probe". Journal of Agricultural and Food Chemistry. 49 (10): 4619–26. doi:10.1021/jf010586o. PMID 11599998.
  161. ^ a b "Withdrawn: Oxygen Radical Absorbance Capacity (ORAC) of Selected Foods, Release 2 (2010)". United States Department of Agriculture, Agricultural Research Service. 16 May 2012. Retrieved 13 June 2012.
  162. ^ Prior RL, Wu X, Schaich K (May 2005). (PDF). Journal of Agricultural and Food Chemistry. 53 (10): 4290–302. doi:10.1021/jf0502698. PMID 15884874. Archived from the original (PDF) on 29 December 2016. Retrieved 24 October 2017.

Further reading edit

  • Halliwell B, Gutteridge JM (2015). Free Radicals in Biology and Medicine (5th ed.). Oxford University Press. ISBN 978-0-19-856869-8.
  • Lane N (2003). Oxygen: The Molecule That Made the World. Oxford University Press. ISBN 978-0-19-860783-0.
  • Pokorny J, Yanishlieva N, Gordon MH (2001). Antioxidants in Food: Practical Applications. CRC Press. ISBN 978-0-8493-1222-9.

External links edit

  •   Media related to Antioxidants at Wikimedia Commons

February 16, 2024
antioxidant, compounds, that, inhibit, oxidation, usually, occurring, autoxidation, chemical, reaction, that, produce, free, radicals, autoxidation, leads, degradation, organic, compounds, including, living, matter, frequently, added, industrial, products, suc. Antioxidants are compounds that inhibit oxidation usually occurring as autoxidation a chemical reaction that can produce free radicals Autoxidation leads to degradation of organic compounds including living matter Antioxidants are frequently added to industrial products such as polymers fuels and lubricants to extend their usable lifetimes 1 Foods are also treated with antioxidants to forestall spoilage in particular the rancidification of oils and fats In cells antioxidants such as glutathione mycothiol or bacillithiol and enzyme systems like superoxide dismutase can prevent damage from oxidative stress 2 Structure of the antioxidant glutathioneKnown dietary antioxidants are vitamins A C and E but the term antioxidant has also been applied to numerous other dietary compounds that only have antioxidant properties in vitro with little evidence for antioxidant properties in vivo 3 Dietary supplements marketed as antioxidants have not been shown to maintain health or prevent disease in humans 3 4 Contents 1 History 2 Uses in technology 2 1 Food preservatives 2 2 Cosmetics preservatives 2 3 Industrial uses 2 4 Environmental and health hazards 3 Oxidative challenge in biology 3 1 Examples of bioactive antioxidant compounds 3 1 1 Uric acid 3 1 2 Vitamin C 3 1 3 Glutathione 3 1 4 Vitamin E 3 2 Pro oxidant activities 3 3 Enzyme systems 3 3 1 Superoxide dismutase catalase and peroxiredoxins 3 3 2 Thioredoxin and glutathione systems 4 Health research 4 1 Relation to diet 4 2 Interactions 4 3 Adverse effects 4 4 Exercise and muscle soreness 5 Levels in food 5 1 Measurement and invalidation of ORAC 6 References 7 Further reading 8 External linksHistory editAs part of their adaptation from marine life terrestrial plants began producing non marine antioxidants such as ascorbic acid vitamin C polyphenols and tocopherols The evolution of angiosperm plants between 50 and 200 million years ago resulted in the development of many antioxidant pigments particularly during the Jurassic period as chemical defences against reactive oxygen species that are byproducts of photosynthesis 5 Originally the term antioxidant specifically referred to a chemical that prevented the consumption of oxygen In the late 19th and early 20th centuries extensive study concentrated on the use of antioxidants in important industrial processes such as the prevention of metal corrosion the vulcanization of rubber and the polymerization of fuels in the fouling of internal combustion engines 6 Early research on the role of antioxidants in biology focused on their use in preventing the oxidation of unsaturated fats which is the cause of rancidity 7 Antioxidant activity could be measured simply by placing the fat in a closed container with oxygen and measuring the rate of oxygen consumption However it was the identification of vitamins C and E as antioxidants that revolutionized the field and led to the realization of the importance of antioxidants in the biochemistry of living organisms 8 9 The possible mechanisms of action of antioxidants were first explored when it was recognized that a substance with anti oxidative activity is likely to be one that is itself readily oxidized 10 Research into how vitamin E prevents the process of lipid peroxidation led to the identification of antioxidants as reducing agents that prevent oxidative reactions often by scavenging reactive oxygen species before they can damage cells 11 Uses in technology editFood preservatives edit See also E number E300 E399 antioxidants acidity regulators Antioxidants are used as food additives to help guard against food deterioration Exposure to oxygen and sunlight are the two main factors in the oxidation of food so food is preserved by keeping in the dark and sealing it in containers or even coating it in wax as with cucumbers However as oxygen is also important for plant respiration storing plant materials in anaerobic conditions produces unpleasant flavors and unappealing colors 12 Consequently packaging of fresh fruits and vegetables contains an 8 oxygen atmosphere Antioxidants are an especially important class of preservatives as unlike bacterial or fungal spoilage oxidation reactions still occur relatively rapidly in frozen or refrigerated food 13 These preservatives include natural antioxidants such as ascorbic acid AA E300 and tocopherols E306 as well as synthetic antioxidants such as propyl gallate PG E310 tertiary butylhydroquinone TBHQ butylated hydroxyanisole BHA E320 and butylated hydroxytoluene BHT E321 14 15 Unsaturated fats can be highly susceptible to oxidation causing rancidification 16 Oxidized lipids are often discolored and can impart unpleasant tastes and flavors Thus these foods are rarely preserved by drying instead they are preserved by smoking salting or fermenting Even less fatty foods such as fruits are sprayed with sulfurous antioxidants prior to air drying Metals catalyse oxidation Some fatty foods such as olive oil are partially protected from oxidation by their natural content of antioxidants Fatty foods are sensitive to photooxidation 17 which forms hydroperoxides by oxidizing unsaturated fatty acids and ester 18 Exposure to ultraviolet UV radiation can cause direct photooxidation and decompose peroxides and carbonyl molecules These molecules undergo free radical chain reactions but antioxidants inhibit them by preventing the oxidation processes 18 Cosmetics preservatives edit Antioxidant stabilizers are also added to fat based cosmetics such as lipstick and moisturizers to prevent rancidity 19 Antioxidants in cosmetic products prevent oxidation of active ingredients and lipid content For example phenolic antioxidants such as stilbenes flavonoids and hydroxycinnamic acid strongly absorb UV radiation due to the presence of chromophores They reduce oxidative stress from sun exposure by absorbing UV light 20 Industrial uses edit nbsp Substituted phenols and derivatives of phenylenediamine are common antioxidants used to inhibit gum formation in gasoline petrol Antioxidants may be added to industrial products such as stabilizers in fuels and additives in lubricants to prevent oxidation and polymerization that leads to the formation of engine fouling residues 21 Fuel additive Components 22 Applications 22 AO 22 N N di 2 butyl 1 4 phenylenediamine Turbine oils transformer oils hydraulic fluids waxes and greasesAO 24 N N di 2 butyl 1 4 phenylenediamine Low temperature oilsAO 29 2 6 di tert butyl 4 methylphenol BHT Turbine oils transformer oils hydraulic fluids waxes greases and gasolinesAO 30 2 4 dimethyl 6 tert butylphenol Jet fuels and gasolines including aviation gasolinesAO 31 2 4 dimethyl 6 tert butylphenol Jet fuels and gasolines including aviation gasolinesAO 32 2 4 dimethyl 6 tert butylphenol and 2 6 di tert butyl 4 methylphenol Jet fuels and gasolines including aviation gasolinesAO 37 2 6 di tert butylphenol Jet fuels and gasolines widely approved for aviation fuelsAntioxidant polymer stabilizers are widely used to prevent the degradation of polymers such as rubbers plastics and adhesives that causes a loss of strength and flexibility in these materials 23 Polymers containing double bonds in their main chains such as natural rubber and polybutadiene are especially susceptible to oxidation and ozonolysis They can be protected by antiozonants Oxidation can be accelerated by UV radiation in natural sunlight to cause photo oxidation Various specialised light stabilisers such as HALS may be added to plastics to prevent this Synthetic phenolic 24 and aminic 25 antioxidants are increasingly being identified as potential human and environmental health hazards Environmental and health hazards edit Synthetic phenolic antioxidants SPAs and aminic antioxidants have potential human and environmental health hazards SPAs are common in indoor dust small air particles sediment sewage river water and wastewater 26 They are synthesized from phenolic compounds and include 2 6 di tert butyl 4 methylphenol BHT 2 6 di tert butyl p benzoquinone BHT Q 2 4 di tert butyl phenol DBP and 3 tert butyl 4 hydroxyanisole BHA BHT can cause hepatotoxicity and damage to the endocrine system and may increase tumor development rates due to 1 1 dimethylhydrazine 27 BHT Q can cause DNA damage and mismatches 28 through the cleavage process generating superoxide radicals 26 DBP is toxic to marine life if exposed long term Phenolic antioxidants have low biodegradability but they do not have severe toxicity toward aquatic organisms at low concentrations Another type of antioxidant diphenylamine DPA is commonly used in the production of commercial industrial lubricants and rubber products and it also acts as a supplement for automotive engine oils 29 Oxidative challenge in biology editFurther information Oxidative stress nbsp The structure of the antioxidant vitamin ascorbic acid vitamin C The vast majority of complex life on Earth requires oxygen for its metabolism but this same oxygen is a highly reactive element that can damage living organisms 2 30 Organisms contain chemicals and enzymes that minimize this oxidative damage without interfering with the beneficial effect of oxygen 31 32 In general antioxidant systems either prevent these reactive species from being formed or remove them thus minimizing their damage 30 31 Reactive oxygen species can have useful cellular functions such as redox signaling Thus ideally antioxidant systems do not remove oxidants entirely but maintain them at some optimum concentration 33 Reactive oxygen species produced in cells include hydrogen peroxide H2O2 hypochlorous acid HClO and free radicals such as the hydroxyl radical OH and the superoxide anion O2 34 The hydroxyl radical is particularly unstable and will react rapidly and non specifically with most biological molecules This species is produced from hydrogen peroxide in metal catalyzed redox reactions such as the Fenton reaction 35 These oxidants can damage cells by starting chemical chain reactions such as lipid peroxidation or by oxidizing DNA or proteins 31 Damage to DNA can cause mutations and possibly cancer if not reversed by DNA repair mechanisms 36 37 while damage to proteins causes enzyme inhibition denaturation and protein degradation 38 The use of oxygen as part of the process for generating metabolic energy produces reactive oxygen species 39 In this process the superoxide anion is produced as a by product of several steps in the electron transport chain 40 Particularly important is the reduction of coenzyme Q in complex III since a highly reactive free radical is formed as an intermediate Q This unstable intermediate can lead to electron leakage when electrons jump directly to oxygen and form the superoxide anion instead of moving through the normal series of well controlled reactions of the electron transport chain 41 Peroxide is also produced from the oxidation of reduced flavoproteins such as complex I 42 However although these enzymes can produce oxidants the relative importance of the electron transfer chain to other processes that generate peroxide is unclear 43 44 In plants algae and cyanobacteria reactive oxygen species are also produced during photosynthesis 45 particularly under conditions of high light intensity 46 This effect is partly offset by the involvement of carotenoids in photoinhibition and in algae and cyanobacteria by large amount of iodide and selenium 47 which involves these antioxidants reacting with over reduced forms of the photosynthetic reaction centres to prevent the production of reactive oxygen species 48 49 Examples of bioactive antioxidant compounds edit Physiological antioxidants are classified into two broad divisions depending on whether they are soluble in water hydrophilic or in lipids lipophilic In general water soluble antioxidants react with oxidants in the cell cytosol and the blood plasma while lipid soluble antioxidants protect cell membranes from lipid peroxidation 31 These compounds may be synthesized in the body or obtained from the diet 32 The different antioxidants are present at a wide range of concentrations in body fluids and tissues with some such as glutathione or ubiquinone mostly present within cells while others such as uric acid are more systemically distributed see table below Some antioxidants are only found in a few organisms and can be pathogens or virulence factors 50 The interactions between these different antioxidants may be synergistic and interdependent 51 52 The action of one antioxidant may therefore depend on the proper function of other members of the antioxidant system 32 The amount of protection provided by any one antioxidant will also depend on its concentration its reactivity towards the particular reactive oxygen species being considered and the status of the antioxidants with which it interacts 32 Some compounds contribute to antioxidant defense by chelating transition metals and preventing them from catalyzing the production of free radicals in the cell The ability to sequester iron for iron binding proteins such as transferrin and ferritin is one such function 44 Selenium and zinc are commonly referred to as antioxidant minerals but these chemical elements have no antioxidant action themselves but rather are required for the activity of antioxidant enzymes such as glutathione reductase and superoxide dismutase See also selenium in biology and zinc in biology Antioxidant Solubility Concentration in human serum mM Concentration in liver tissue mmol kg Ascorbic acid vitamin C Water 50 60 53 260 human 54 Glutathione Water 4 55 6 400 human 54 Lipoic acid Water 0 1 0 7 56 4 5 rat 57 Uric acid Water 200 400 58 1 600 human 54 Carotenes Lipid b carotene 0 5 1 59 retinol vitamin A 1 3 60 5 human total carotenoids 61 a Tocopherol vitamin E Lipid 10 40 60 50 human 54 Ubiquinol coenzyme Q Lipid 5 62 200 human 63 Uric acid edit Uric acid has the highest concentration of any blood antioxidant 58 and provides over half of the total antioxidant capacity of human serum 64 Uric acid s antioxidant activities are also complex given that it does not react with some oxidants such as superoxide but does act against peroxynitrite 65 peroxides and hypochlorous acid 66 Concerns over elevated UA s contribution to gout must be considered one of many risk factors 67 By itself UA related risk of gout at high levels 415 530 mmol L is only 0 5 per year with an increase to 4 5 per year at UA supersaturation levels 535 mmol L 68 Many of these aforementioned studies determined UA s antioxidant actions within normal physiological levels 69 65 and some found antioxidant activity at levels as high as 285 mmol L 70 Vitamin C edit Ascorbic acid or vitamin C an oxidation reduction redox catalyst found in both animals and plants 71 can reduce and thereby neutralize reactive oxygen species such as hydrogen peroxide 71 72 In addition to its direct antioxidant effects ascorbic acid is also a substrate for the redox enzyme ascorbate peroxidase a function that is used in stress resistance in plants 73 Ascorbic acid is present at high levels in all parts of plants and can reach concentrations of 20 millimolar in chloroplasts 74 Glutathione edit nbsp The free radical mechanism of lipid peroxidationGlutathione has antioxidant properties since the thiol group in its cysteine moiety is a reducing agent and can be reversibly oxidized and reduced In cells glutathione is maintained in the reduced form by the enzyme glutathione reductase and in turn reduces other metabolites and enzyme systems such as ascorbate in the glutathione ascorbate cycle glutathione peroxidases and glutaredoxins as well as reacting directly with oxidants 75 Due to its high concentration and its central role in maintaining the cell s redox state glutathione is one of the most important cellular antioxidants 76 In some organisms glutathione is replaced by other thiols such as by mycothiol in the Actinomycetes bacillithiol in some gram positive bacteria 77 78 or by trypanothione in the Kinetoplastids 79 80 Vitamin E edit Vitamin E is the collective name for a set of eight related tocopherols and tocotrienols which are fat soluble vitamins with antioxidant properties 81 82 Of these a tocopherol has been most studied as it has the highest bioavailability with the body preferentially absorbing and metabolising this form 83 It has been claimed that the a tocopherol form is the most important lipid soluble antioxidant and that it protects membranes from oxidation by reacting with lipid radicals produced in the lipid peroxidation chain reaction 81 84 This removes the free radical intermediates and prevents the propagation reaction from continuing This reaction produces oxidised a tocopheroxyl radicals that can be recycled back to the active reduced form through reduction by other antioxidants such as ascorbate retinol or ubiquinol 85 This is in line with findings showing that a tocopherol but not water soluble antioxidants efficiently protects glutathione peroxidase 4 GPX4 deficient cells from cell death 86 GPx4 is the only known enzyme that efficiently reduces lipid hydroperoxides within biological membranes However the roles and importance of the various forms of vitamin E are presently unclear 87 88 and it has even been suggested that the most important function of a tocopherol is as a signaling molecule with this molecule having no significant role in antioxidant metabolism 89 90 The functions of the other forms of vitamin E are even less well understood although g tocopherol is a nucleophile that may react with electrophilic mutagens 83 and tocotrienols may be important in protecting neurons from damage 91 Pro oxidant activities edit Further information Pro oxidant Antioxidants that are reducing agents can also act as pro oxidants For example vitamin C has antioxidant activity when it reduces oxidizing substances such as hydrogen peroxide 92 however it will also reduce metal ions such as iron and copper 93 that generate free radicals through the Fenton reaction 35 94 While ascorbic acid is effective antioxidant it can also oxidatively change the flavor and color of food With the presence of transition metals there are low concentrations of ascorbic acid that can act as a radical scavenger in the Fenton reaction 93 2 Fe3 Ascorbate 2 Fe2 Dehydroascorbate2 Fe2 2 H2O2 2 Fe3 2 OH 2 OH The relative importance of the antioxidant and pro oxidant activities of antioxidants is an area of current research but vitamin C which exerts its effects as a vitamin by oxidizing polypeptides appears to have a mostly antioxidant action in the human body 94 Enzyme systems edit O 2 Oxygen O 2 Superoxide Superoxide dismutase H 2 O 2 Hydrogen peroxide Peroxidases catalase H 2 O Water displaystyle ce underset Oxygen O2 gt underset Superoxide O2 gt ce Superoxide atop dismutase underset Hydrogen atop peroxide H2O2 gt ce Peroxidases atop catalase underset Water H2O nbsp Enzymatic pathway for detoxification of reactive oxygen species As with the chemical antioxidants cells are protected against oxidative stress by an interacting network of antioxidant enzymes 30 31 Here the superoxide released by processes such as oxidative phosphorylation is first converted to hydrogen peroxide and then further reduced to give water This detoxification pathway is the result of multiple enzymes with superoxide dismutases catalysing the first step and then catalases and various peroxidases removing hydrogen peroxide As with antioxidant metabolites the contributions of these enzymes to antioxidant defenses can be hard to separate from one another but the generation of transgenic mice lacking just one antioxidant enzyme can be informative 95 Superoxide dismutase catalase and peroxiredoxins edit Superoxide dismutases SODs are a class of closely related enzymes that catalyze the breakdown of the superoxide anion into oxygen and hydrogen peroxide 96 97 SOD enzymes are present in almost all aerobic cells and in extracellular fluids 98 Superoxide dismutase enzymes contain metal ion cofactors that depending on the isozyme can be copper zinc manganese or iron In humans the copper zinc SOD is present in the cytosol while manganese SOD is present in the mitochondrion 97 There also exists a third form of SOD in extracellular fluids which contains copper and zinc in its active sites 99 The mitochondrial isozyme seems to be the most biologically important of these three since mice lacking this enzyme die soon after birth 100 In contrast the mice lacking copper zinc SOD Sod1 are viable but have numerous pathologies and a reduced lifespan see article on superoxide while mice without the extracellular SOD have minimal defects sensitive to hyperoxia 95 101 In plants SOD isozymes are present in the cytosol and mitochondria with an iron SOD found in chloroplasts that is absent from vertebrates and yeast 102 Catalases are enzymes that catalyse the conversion of hydrogen peroxide to water and oxygen using either an iron or manganese cofactor 103 104 This protein is localized to peroxisomes in most eukaryotic cells 105 Catalase is an unusual enzyme since although hydrogen peroxide is its only substrate it follows a ping pong mechanism Here its cofactor is oxidised by one molecule of hydrogen peroxide and then regenerated by transferring the bound oxygen to a second molecule of substrate 106 Despite its apparent importance in hydrogen peroxide removal humans with genetic deficiency of catalase acatalasemia or mice genetically engineered to lack catalase completely experience few ill effects 107 108 nbsp Decameric structure of AhpC a bacterial 2 cysteine peroxiredoxin from Salmonella typhimurium 109 Peroxiredoxins are peroxidases that catalyze the reduction of hydrogen peroxide organic hydroperoxides as well as peroxynitrite 110 They are divided into three classes typical 2 cysteine peroxiredoxins atypical 2 cysteine peroxiredoxins and 1 cysteine peroxiredoxins 111 These enzymes share the same basic catalytic mechanism in which a redox active cysteine the peroxidatic cysteine in the active site is oxidized to a sulfenic acid by the peroxide substrate 112 Over oxidation of this cysteine residue in peroxiredoxins inactivates these enzymes but this can be reversed by the action of sulfiredoxin 113 Peroxiredoxins seem to be important in antioxidant metabolism as mice lacking peroxiredoxin 1 or 2 have shortened lifespans and develop hemolytic anaemia while plants use peroxiredoxins to remove hydrogen peroxide generated in chloroplasts 114 115 116 Thioredoxin and glutathione systems edit The thioredoxin system contains the 12 kDa protein thioredoxin and its companion thioredoxin reductase 117 Proteins related to thioredoxin are present in all sequenced organisms Plants such as Arabidopsis thaliana have a particularly great diversity of isoforms 118 The active site of thioredoxin consists of two neighboring cysteines as part of a highly conserved CXXC motif that can cycle between an active dithiol form reduced and an oxidized disulfide form In its active state thioredoxin acts as an efficient reducing agent scavenging reactive oxygen species and maintaining other proteins in their reduced state 119 After being oxidized the active thioredoxin is regenerated by the action of thioredoxin reductase using NADPH as an electron donor 120 The glutathione system includes glutathione glutathione reductase glutathione peroxidases and glutathione S transferases 76 This system is found in animals plants and microorganisms 76 121 Glutathione peroxidase is an enzyme containing four selenium cofactors that catalyzes the breakdown of hydrogen peroxide and organic hydroperoxides There are at least four different glutathione peroxidase isozymes in animals 122 Glutathione peroxidase 1 is the most abundant and is a very efficient scavenger of hydrogen peroxide while glutathione peroxidase 4 is most active with lipid hydroperoxides Surprisingly glutathione peroxidase 1 is dispensable as mice lacking this enzyme have normal lifespans 123 but they are hypersensitive to induced oxidative stress 124 In addition the glutathione S transferases show high activity with lipid peroxides 125 These enzymes are at particularly high levels in the liver and also serve in detoxification metabolism 126 Health research editRelation to diet edit The dietary antioxidant vitamins A C and E are essential and required in specific daily amounts to prevent diseases 3 127 128 Polyphenols which have antioxidant properties in vitro due to their free hydroxy groups 129 are extensively metabolized by catechol O methyltransferase which methylates free hydroxyl groups and thereby prevents them from acting as antioxidants in vivo 130 131 Interactions edit Common pharmaceuticals and supplements with antioxidant properties may interfere with the efficacy of certain anticancer medication and radiation therapy 132 Pharmaceuticals and supplements that have antioxidant properties suppress the formation of free radicals by inhibiting oxidation processes Radiation therapy induce oxidative stress that damages essential components of cancer cells such as proteins nucleic acids and lipids that comprise cell membranes 133 Adverse effects edit See also Antioxidative stress nbsp Structure of the metal chelator phytic acidRelatively strong reducing acids can have antinutrient effects by binding to dietary minerals such as iron and zinc in the gastrointestinal tract and preventing them from being absorbed 134 Examples are oxalic acid tannins and phytic acid which are high in plant based diets 135 Calcium and iron deficiencies are not uncommon in diets in developing countries where less meat is eaten and there is high consumption of phytic acid from beans and unleavened whole grain bread However germination soaking or microbial fermentation are all household strategies that reduce the phytate and polyphenol content of unrefined cereal Increases in Fe Zn and Ca absorption have been reported in adults fed dephytinized cereals compared with cereals containing their native phytate 136 Foods Reducing acid presentCocoa bean and chocolate spinach turnip and rhubarb 137 Oxalic acidWhole grains maize legumes 138 Phytic acidTea beans cabbage 137 139 TanninsHigh doses of some antioxidants may have harmful long term effects The Beta Carotene and Retinol Efficacy Trial CARET study of lung cancer patients found that smokers given supplements containing beta carotene and vitamin A had increased rates of lung cancer 140 Subsequent studies confirmed these adverse effects 141 These harmful effects may also be seen in non smokers as one meta analysis including data from approximately 230 000 patients showed that b carotene vitamin A or vitamin E supplementation is associated with increased mortality but saw no significant effect from vitamin C 142 No health risk was seen when all the randomized controlled studies were examined together but an increase in mortality was detected when only high quality and low bias risk trials were examined separately 143 As the majority of these low bias trials dealt with either elderly people or people with disease these results may not apply to the general population 144 This meta analysis was later repeated and extended by the same authors confirming the previous results 143 These two publications are consistent with some previous meta analyses that also suggested that vitamin E supplementation increased mortality 145 and that antioxidant supplements increased the risk of colon cancer 146 Beta carotene may also increase lung cancer 146 147 Overall the large number of clinical trials carried out on antioxidant supplements suggest that either these products have no effect on health or that they cause a small increase in mortality in elderly or vulnerable populations 127 148 142 Exercise and muscle soreness edit A 2017 review showed that taking antioxidant dietary supplements before or after exercise is unlikely to produce a noticeable reduction in muscle soreness after a person exercises 149 Levels in food editFurther information List of antioxidants in food and Polyphenol antioxidant nbsp Fruits and vegetables are good sources of antioxidant vitamins C and E Antioxidant vitamins are found in vegetables fruits eggs legumes and nuts Vitamins A C and E can be destroyed by long term storage or prolonged cooking 150 The effects of cooking and food processing are complex as these processes can also increase the bioavailability of antioxidants such as some carotenoids in vegetables 151 Processed food contains fewer antioxidant vitamins than fresh and uncooked foods as preparation exposes food to heat and oxygen 152 Antioxidant vitamins Foods containing high levels of antioxidant vitamins 139 153 154 Vitamin C ascorbic acid Fresh or frozen fruits and vegetablesVitamin E tocopherols tocotrienols Vegetable oils nuts and seedsCarotenoids carotenes as provitamin A Fruit vegetables and eggsOther antioxidants are not obtained from the diet but instead are made in the body For example ubiquinol coenzyme Q is poorly absorbed from the gut and is made through the mevalonate pathway 63 Another example is glutathione which is made from amino acids As any glutathione in the gut is broken down to free cysteine glycine and glutamic acid before being absorbed even large oral intake has little effect on the concentration of glutathione in the body 155 156 Although large amounts of sulfur containing amino acids such as acetylcysteine can increase glutathione 157 no evidence exists that eating high levels of these glutathione precursors is beneficial for healthy adults 158 Measurement and invalidation of ORAC edit Measurement of polyphenol and carotenoid content in food is not a straightforward process as antioxidants collectively are a diverse group of compounds with different reactivities to various reactive oxygen species In food science analyses in vitro the oxygen radical absorbance capacity ORAC was once an industry standard for estimating antioxidant strength of whole foods juices and food additives mainly from the presence of polyphenols 159 160 Earlier measurements and ratings by the United States Department of Agriculture were withdrawn in 2012 as biologically irrelevant to human health referring to an absence of physiological evidence for polyphenols having antioxidant properties in vivo 161 Consequently the ORAC method derived only from in vitro experiments is no longer considered relevant to human diets or biology as of 2010 161 Alternative in vitro measurements of antioxidant content in foods also based on the presence of polyphenols include the Folin Ciocalteu reagent and the Trolox equivalent antioxidant capacity assay 162 References edit Klemchuk Peter P 2000 Antioxidants Ullmann s Encyclopedia of Industrial Chemistry doi 10 1002 14356007 a03 091 ISBN 3527306730 a b Helberg Julian Pratt Derek A 2021 Autoxidation vs Antioxidants the fight for forever Chemical Society Reviews 50 13 7343 7358 doi 10 1039 D1CS00265A PMID 34037013 S2CID 235200305 a b c Antioxidants In Depth National Center for Complementary and Integrative Health US National Institutes of Health 1 November 2013 Retrieved 17 March 2023 Fang Yun Zhong Yang Sheng Wu Guoyao 2002 Free radicals antioxidants and nutrition Nutrition 18 10 872 879 doi 10 1016 s0899 9007 02 00916 4 PMID 12361782 Benzie IF September 2003 Evolution of dietary antioxidants Comparative Biochemistry and Physiology A 136 1 113 26 doi 10 1016 S1095 6433 02 00368 9 hdl 10397 34754 PMID 14527634 Mattill HA 1947 Antioxidants Annual Review of Biochemistry 16 177 92 doi 10 1146 annurev bi 16 070147 001141 PMID 20259061 German JB 1999 Food Processing and Lipid Oxidation Impact of Processing on Food Safety Advances in Experimental Medicine and Biology Vol 459 pp 23 50 doi 10 1007 978 1 4615 4853 9 3 ISBN 978 0 306 46051 7 PMID 10335367 Jacob RA 1996 Three eras of vitamin C discovery Subcellular Biochemistry Vol 25 pp 1 16 doi 10 1007 978 1 4613 0325 1 1 ISBN 978 1 4613 7998 0 PMID 8821966 Knight JA 1998 Free radicals their history and current status in aging and disease Annals of Clinical and Laboratory Science 28 6 331 46 PMID 9846200 Moureu C Dufraisse C 1922 Sur l autoxydation Les antioxygenes Comptes Rendus des Seances et Memoires de la Societe de Biologie in French 86 321 322 Wolf G March 2005 The discovery of the antioxidant function of vitamin E the contribution of Henry A Mattill The Journal of Nutrition 135 3 363 6 doi 10 1093 jn 135 3 363 PMID 15735064 Kader AA Zagory D Kerbel EL 1989 Modified atmosphere packaging of fruits and vegetables Critical Reviews in Food Science and Nutrition 28 1 1 30 doi 10 1080 10408398909527490 PMID 2647417 Zallen EM Hitchcock MJ Goertz GE December 1975 Chilled food systems Effects of chilled holding on quality of beef loaves Journal of the American Dietetic Association 67 6 552 7 doi 10 1016 S0002 8223 21 14836 9 PMID 1184900 Iverson F June 1995 Phenolic antioxidants Health Protection Branch studies on butylated hydroxyanisole Cancer Letters 93 1 49 54 doi 10 1016 0304 3835 95 03787 W PMID 7600543 E number index UK food guide Archived from the original on 4 March 2007 Retrieved 5 March 2007 Robards K Kerr AF Patsalides E February 1988 Rancidity and its Measurement in Edible Oils and Snack Foods A review The Analyst 113 2 213 24 Bibcode 1988Ana 113 213R doi 10 1039 an9881300213 PMID 3288002 Del Carlo M Sacchetti G Di Mattia C Compagnone D Mastrocola D Liberatore L Cichelli A June 2004 Contribution of the phenolic fraction to the antioxidant activity and oxidative stability of olive oil Journal of Agricultural and Food Chemistry 52 13 4072 9 doi 10 1021 jf049806z PMID 15212450 a b Frankel Edwin N 1 January 2012 Frankel Edwin N ed Chapter 3 Photooxidation of unsaturated fats Lipid Oxidation Second Edition Oily Press Lipid Library Series Woodhead Publishing pp 51 66 ISBN 978 0 9531949 8 8 retrieved 15 April 2023 Final report on the amended safety assessment of Propyl Gallate International Journal of Toxicology 26 3 suppl 89 118 2007 doi 10 1080 10915810701663176 PMID 18080874 S2CID 39562131 Propyl Gallate is a generally recognized as safe GRAS antioxidant to protect fats oils and fat containing food from rancidity that results from the formation of peroxides Debora Jackeline Cleide Viviane Luciana Oliveira Rosemeire Aparecida 7 August 2019 Polyphenols as natural antioxidants in cosmetics applications Journal of Cosmetic Dermatology 19 1 33 37 doi 10 1111 jocd 13093 PMID 31389656 S2CID 201156301 Boozer CE Hammond GS Hamilton CE Sen JN 1955 Air Oxidation of Hydrocarbons 1II The Stoichiometry and Fate of Inhibitors in Benzene and Chlorobenzene Journal of the American Chemical Society 77 12 3233 7 doi 10 1021 ja01617a026 a b Fuel antioxidants Innospec Chemicals Archived from the original on 15 October 2006 Retrieved 27 February 2007 Why use Antioxidants SpecialChem Adhesives Archived from the original on 11 February 2007 Retrieved 27 February 2007 Liu Runzeng Mabury Scott A 6 October 2020 Synthetic Phenolic Antioxidants A Review of Environmental Occurrence Fate Human Exposure and Toxicity Environmental Science amp Technology 54 19 11706 11719 Bibcode 2020EnST 5411706L doi 10 1021 acs est 0c05077 PMID 32915564 S2CID 221637214 Xu Jing Hao Yanfen Yang Zhiruo Li Wenjuan Xie Wenjing Huang Yani Wang Deliang He Yuqing Liang Yong Matsiko Julius Wang Pu 7 November 2022 Rubber Antioxidants and Their Transformation Products Environmental Occurrence and Potential Impact International Journal of Environmental Research and Public Health 19 21 14595 doi 10 3390 ijerph192114595 PMC 9657274 PMID 36361475 a b Li Chao Cui Xinyi Chen Yi Liao Chunyang Ma Lena Q February 2019 Synthetic phenolic antioxidants and their major metabolites in human fingernail Environmental Research 169 308 314 Bibcode 2019ER 169 308L doi 10 1016 j envres 2018 11 020 PMID 30500685 S2CID 56486425 Liu Runzeng Mabury Scott A 11 September 2020 Synthetic Phenolic Antioxidants A Review of Environmental Occurrence Fate Human Exposure and Toxicity Environ Sci Technol 54 19 11706 11719 Bibcode 2020EnST 5411706L doi 10 1021 acs est 0c05077 PMID 32915564 S2CID 221637214 Wang Wanyi Xiong Ping Zhang He Zhu Qingqing Liao Chunyang Jiang Guibin 1 October 2021 Analysis occurrence toxicity and environmental health risks of synthetic phenolic antioxidants A review Environmental Research 201 111531 Bibcode 2021ER 201k1531W doi 10 1016 j envres 2021 111531 ISSN 0013 9351 PMID 34146526 Zhang Zi Feng Zhang Xue Sverko Ed Marvin Christopher H Jobst Karl J Smyth Shirley Anne Li Yi Fan 11 February 2020 Determination of Diphenylamine Antioxidants in Wastewater Biosolids and Sediment Environmental Science amp Technology Letters 7 2 102 110 doi 10 1021 acs estlett 9b00796 ISSN 2328 8930 S2CID 213719260 a b c Davies KJ 1995 Oxidative stress the paradox of aerobic life Biochemical Society Symposium 61 1 31 doi 10 1042 bss0610001 PMID 8660387 a b c d e Sies H March 1997 Oxidative stress oxidants and antioxidants Experimental Physiology 82 2 291 5 doi 10 1113 expphysiol 1997 sp004024 PMID 9129943 S2CID 20240552 a b c d Vertuani S Angusti A Manfredini S 2004 The Antioxidants and Pro Antioxidants Network an Overview Current Pharmaceutical Design 10 14 1677 94 doi 10 2174 1381612043384655 PMID 15134565 Rhee SG June 2006 Cell signaling H2O2 a necessary evil for cell signaling Science 312 5782 1882 3 doi 10 1126 science 1130481 PMID 16809515 S2CID 83598498 Valko M Leibfritz D Moncol J Cronin MT Mazur M Telser J 2007 Free radicals and antioxidants in normal physiological functions and human disease The International Journal of Biochemistry amp Cell Biology 39 1 44 84 doi 10 1016 j biocel 2006 07 001 PMID 16978905 a b Stohs SJ Bagchi D February 1995 Oxidative mechanisms in the toxicity of metal ions PDF Free Radical Biology amp Medicine Submitted manuscript 18 2 321 36 CiteSeerX 10 1 1 461 6417 doi 10 1016 0891 5849 94 00159 H PMID 7744317 Nakabeppu Y Sakumi K Sakamoto K Tsuchimoto D Tsuzuki T Nakatsu Y April 2006 Mutagenesis and carcinogenesis caused by the oxidation of nucleic acids Biological Chemistry 387 4 373 9 doi 10 1515 BC 2006 050 PMID 16606334 S2CID 20217256 Valko M Izakovic M Mazur M Rhodes CJ Telser J November 2004 Role of oxygen radicals in DNA damage and cancer incidence Molecular and Cellular Biochemistry 266 1 2 37 56 doi 10 1023 B MCBI 0000049134 69131 89 PMID 15646026 S2CID 207547763 Stadtman ER August 1992 Protein oxidation and aging Science 257 5074 1220 4 Bibcode 1992Sci 257 1220S doi 10 1126 science 1355616 PMID 1355616 Raha S Robinson BH October 2000 Mitochondria oxygen free radicals disease and ageing Trends in Biochemical Sciences 25 10 502 8 doi 10 1016 S0968 0004 00 01674 1 PMID 11050436 Lenaz G 2001 The mitochondrial production of reactive oxygen species mechanisms and implications in human pathology IUBMB Life 52 3 5 159 64 doi 10 1080 15216540152845957 PMID 11798028 S2CID 45366190 Finkel T Holbrook NJ November 2000 Oxidants oxidative stress and the biology of ageing Nature 408 6809 239 47 Bibcode 2000Natur 408 239F doi 10 1038 35041687 PMID 11089981 S2CID 2502238 Hirst J King MS Pryde KR October 2008 The production of reactive oxygen species by complex I Biochemical Society Transactions 36 Pt 5 976 80 doi 10 1042 BST0360976 PMID 18793173 Seaver LC Imlay JA November 2004 Are respiratory enzymes the primary sources of intracellular hydrogen peroxide The Journal of Biological Chemistry 279 47 48742 50 doi 10 1074 jbc M408754200 PMID 15361522 a b Imlay JA 2003 Pathways of oxidative damage Annual Review of Microbiology 57 395 418 doi 10 1146 annurev micro 57 030502 090938 PMID 14527285 Demmig Adams B Adams WW December 2002 Antioxidants in photosynthesis and human nutrition Science 298 5601 2149 53 Bibcode 2002Sci 298 2149D doi 10 1126 science 1078002 PMID 12481128 S2CID 27486669 Krieger Liszkay A January 2005 Singlet oxygen production in photosynthesis Journal of Experimental Botany 56 411 337 46 CiteSeerX 10 1 1 327 9651 doi 10 1093 jxb erh237 PMID 15310815 Kupper FC Carpenter LJ McFiggans GB Palmer CJ Waite TJ Boneberg E M Woitsch S Weiller M Abela R Grolimund D Potin P Butler A Luther GW Kroneck PMH Meyer Klaucke W Feiters MC 2008 Iodide accumulation provides kelp with an inorganic antioxidant impacting atmospheric chemistry Proceedings of the National Academy of Sciences 105 19 6954 6958 Bibcode 2008PNAS 105 6954K doi 10 1073 pnas 0709959105 ISSN 0027 8424 PMC 2383960 PMID 18458346 Szabo I Bergantino E Giacometti GM July 2005 Light and oxygenic photosynthesis energy dissipation as a protection mechanism against photo oxidation EMBO Reports 6 7 629 34 doi 10 1038 sj embor 7400460 PMC 1369118 PMID 15995679 Kerfeld CA October 2004 Water soluble carotenoid proteins of cyanobacteria PDF Archives of Biochemistry and Biophysics Submitted manuscript 430 1 2 9 doi 10 1016 j abb 2004 03 018 PMID 15325905 S2CID 25306222 Miller RA Britigan BE January 1997 Role of oxidants in microbial pathophysiology Clinical Microbiology Reviews 10 1 1 18 doi 10 1128 CMR 10 1 1 PMC 172912 PMID 8993856 Chaudiere J Ferrari Iliou R 1999 Intracellular antioxidants from chemical to biochemical mechanisms Food and Chemical Toxicology 37 9 10 949 62 doi 10 1016 S0278 6915 99 00090 3 PMID 10541450 Sies H July 1993 Strategies of antioxidant defense European Journal of Biochemistry 215 2 213 9 doi 10 1111 j 1432 1033 1993 tb18025 x PMID 7688300 Khaw KT Woodhouse P June 1995 Interrelation of vitamin C infection haemostatic factors and cardiovascular disease BMJ 310 6994 1559 63 doi 10 1136 bmj 310 6994 1559 PMC 2549940 PMID 7787643 a b c d Evelson P Travacio M Repetto M Escobar J Llesuy S Lissi EA April 2001 Evaluation of total reactive antioxidant potential TRAP of tissue homogenates and their cytosols Archives of Biochemistry and Biophysics 388 2 261 6 doi 10 1006 abbi 2001 2292 PMID 11368163 Morrison JA Jacobsen DW Sprecher DL Robinson K Khoury P Daniels SR November 1999 Serum glutathione in adolescent males predicts parental coronary heart disease Circulation 100 22 2244 7 doi 10 1161 01 CIR 100 22 2244 PMID 10577998 Teichert J Preiss R November 1992 HPLC methods for determination of lipoic acid and its reduced form in human plasma International Journal of Clinical Pharmacology Therapy and Toxicology 30 11 511 2 PMID 1490813 Akiba S Matsugo S Packer L Konishi T May 1998 Assay of protein bound lipoic acid in tissues by a new enzymatic method Analytical Biochemistry 258 2 299 304 doi 10 1006 abio 1998 2615 PMID 9570844 a b Glantzounis GK Tsimoyiannis EC Kappas AM Galaris DA 2005 Uric acid and oxidative stress Current Pharmaceutical Design 11 32 4145 51 doi 10 2174 138161205774913255 PMID 16375736 El Sohemy A Baylin A Kabagambe E Ascherio A Spiegelman D Campos H July 2002 Individual carotenoid concentrations in adipose tissue and plasma as biomarkers of dietary intake The American Journal of Clinical Nutrition 76 1 172 9 doi 10 1093 ajcn 76 1 172 PMID 12081831 a b Sowell AL Huff DL Yeager PR Caudill SP Gunter EW March 1994 Retinol alpha tocopherol lutein zeaxanthin beta cryptoxanthin lycopene alpha carotene trans beta carotene and four retinyl esters in serum determined simultaneously by reversed phase HPLC with multiwavelength detection Clinical Chemistry 40 3 411 6 doi 10 1093 clinchem 40 3 411 PMID 8131277 Stahl W Schwarz W Sundquist AR Sies H April 1992 cis trans isomers of lycopene and beta carotene in human serum and tissues Archives of Biochemistry and Biophysics 294 1 173 7 doi 10 1016 0003 9861 92 90153 N PMID 1550343 Zita C Overvad K Mortensen SA Sindberg CD Moesgaard S Hunter DA 2003 Serum coenzyme Q10 concentrations in healthy men supplemented with 30 mg or 100 mg coenzyme Q10 for two months in a randomised controlled study BioFactors 18 1 4 185 93 doi 10 1002 biof 5520180221 PMID 14695934 S2CID 19895215 a b Turunen M Olsson J Dallner G January 2004 Metabolism and function of coenzyme Q Biochimica et Biophysica Acta BBA Biomembranes 1660 1 2 171 99 doi 10 1016 j bbamem 2003 11 012 PMID 14757233 Becker BF June 1993 Towards the physiological function of uric acid Free Radical Biology amp Medicine 14 6 615 31 doi 10 1016 0891 5849 93 90143 I PMID 8325534 a b Sautin YY Johnson RJ June 2008 Uric acid the oxidant antioxidant paradox Nucleosides Nucleotides amp Nucleic Acids 27 6 608 19 doi 10 1080 15257770802138558 PMC 2895915 PMID 18600514 Enomoto A Endou H September 2005 Roles of organic anion transporters OATs and a urate transporter URAT1 in the pathophysiology of human disease Clinical and Experimental Nephrology 9 3 195 205 doi 10 1007 s10157 005 0368 5 PMID 16189627 S2CID 6145651 Eggebeen AT September 2007 Gout an update American Family Physician 76 6 801 8 PMID 17910294 Campion EW Glynn RJ DeLabry LO March 1987 Asymptomatic hyperuricemia Risks and consequences in the Normative Aging Study The American Journal of Medicine 82 3 421 6 doi 10 1016 0002 9343 87 90441 4 PMID 3826098 Baillie JK Bates MG Thompson AA Waring WS Partridge RW Schnopp MF Simpson A Gulliver Sloan F Maxwell SR Webb DJ May 2007 Endogenous urate production augments plasma antioxidant capacity in healthy lowland subjects exposed to high altitude Chest 131 5 1473 8 doi 10 1378 chest 06 2235 PMID 17494796 Nazarewicz RR Ziolkowski W Vaccaro PS Ghafourifar P December 2007 Effect of short term ketogenic diet on redox status of human blood Rejuvenation Research 10 4 435 40 doi 10 1089 rej 2007 0540 PMID 17663642 a b Vitamin C Micronutrient Information Center Linus Pauling Institute Oregon State University Corvallis OR 1 July 2018 Retrieved 19 June 2019 Padayatty SJ Katz A Wang Y Eck P Kwon O Lee JH Chen S Corpe C Dutta A Dutta SK Levine M February 2003 Vitamin C as an antioxidant evaluation of its role in disease prevention Journal of the American College of Nutrition 22 1 18 35 doi 10 1080 07315724 2003 10719272 PMID 12569111 S2CID 21196776 Shigeoka S Ishikawa T Tamoi M Miyagawa Y Takeda T Yabuta Y Yoshimura K May 2002 Regulation and function of ascorbate peroxidase isoenzymes Journal of Experimental Botany 53 372 1305 19 doi 10 1093 jexbot 53 372 1305 PMID 11997377 Smirnoff N Wheeler GL 2000 Ascorbic acid in plants biosynthesis and function Critical Reviews in Biochemistry and Molecular Biology 35 4 291 314 doi 10 1080 10409230008984166 PMID 11005203 S2CID 85060539 Meister A April 1994 Glutathione ascorbic acid antioxidant system in animals The Journal of Biological Chemistry 269 13 9397 400 doi 10 1016 S0021 9258 17 36891 6 PMID 8144521 a b c Meister A Anderson ME 1983 Glutathione Annual Review of Biochemistry 52 711 60 doi 10 1146 annurev bi 52 070183 003431 PMID 6137189 Gaballa A Newton GL Antelmann H Parsonage D Upton H Rawat M Claiborne A Fahey RC Helmann JD April 2010 Biosynthesis and functions of bacillithiol a major low molecular weight thiol in Bacilli Proceedings of the National Academy of Sciences of the United States of America 107 14 6482 6 Bibcode 2010PNAS 107 6482G doi 10 1073 pnas 1000928107 PMC 2851989 PMID 20308541 Newton GL Rawat M La Clair JJ Jothivasan VK Budiarto T Hamilton CJ Claiborne A Helmann JD Fahey RC September 2009 Bacillithiol is an antioxidant thiol produced in Bacilli Nature Chemical Biology 5 9 625 627 doi 10 1038 nchembio 189 PMC 3510479 PMID 19578333 Fahey RC 2001 Novel thiols of prokaryotes Annual Review of Microbiology 55 333 56 doi 10 1146 annurev micro 55 1 333 PMID 11544359 Fairlamb AH Cerami A 1992 Metabolism and functions of trypanothione in the Kinetoplastida Annual Review of Microbiology 46 695 729 doi 10 1146 annurev mi 46 100192 003403 PMID 1444271 a b Herrera E Barbas C March 2001 Vitamin E action metabolism and perspectives Journal of Physiology and Biochemistry 57 2 43 56 doi 10 1007 BF03179812 hdl 10637 720 PMID 11579997 S2CID 7272312 Packer L Weber SU Rimbach G February 2001 Molecular aspects of alpha tocotrienol antioxidant action and cell signalling The Journal of Nutrition 131 2 369S 73S doi 10 1093 jn 131 2 369S PMID 11160563 a b Brigelius Flohe R Traber MG July 1999 Vitamin E function and metabolism FASEB Journal 13 10 1145 55 CiteSeerX 10 1 1 337 5276 doi 10 1096 fasebj 13 10 1145 PMID 10385606 S2CID 7031925 Traber MG Atkinson J July 2007 Vitamin E antioxidant and nothing more Free Radical Biology amp Medicine 43 1 4 15 doi 10 1016 j freeradbiomed 2007 03 024 PMC 2040110 PMID 17561088 Wang X Quinn PJ July 1999 Vitamin E and its function in membranes Progress in Lipid Research 38 4 309 36 doi 10 1016 S0163 7827 99 00008 9 PMID 10793887 Seiler A Schneider M Forster H Roth S Wirth EK Culmsee C Plesnila N Kremmer E Radmark O Wurst W Bornkamm GW Schweizer U Conrad M September 2008 Glutathione peroxidase 4 senses and translates oxidative stress into 12 15 lipoxygenase dependent and AIF mediated cell death Cell Metabolism 8 3 237 48 doi 10 1016 j cmet 2008 07 005 PMID 18762024 Brigelius Flohe R Davies KJ July 2007 Is vitamin E an antioxidant a regulator of signal transduction and gene expression or a junk food Comments on the two accompanying papers Molecular mechanism of alpha tocopherol action by A Azzi and Vitamin E antioxidant and nothing more by M Traber and J Atkinson Free Radical Biology amp Medicine 43 1 2 3 doi 10 1016 j freeradbiomed 2007 05 016 PMID 17561087 Atkinson J Epand RF Epand RM March 2008 Tocopherols and tocotrienols in membranes a critical review Free Radical Biology amp Medicine 44 5 739 64 doi 10 1016 j freeradbiomed 2007 11 010 PMID 18160049 Azzi A July 2007 Molecular mechanism of alpha tocopherol action Free Radical Biology amp Medicine 43 1 16 21 doi 10 1016 j freeradbiomed 2007 03 013 PMID 17561089 Zingg JM Azzi A May 2004 Non antioxidant activities of vitamin E Current Medicinal Chemistry 11 9 1113 33 doi 10 2174 0929867043365332 PMID 15134510 Archived from the original on 6 October 2011 Sen CK Khanna S Roy S March 2006 Tocotrienols Vitamin E beyond tocopherols Life Sciences 78 18 2088 98 doi 10 1016 j lfs 2005 12 001 PMC 1790869 PMID 16458936 Duarte TL Lunec J July 2005 Review When is an antioxidant not an antioxidant A review of novel actions and reactions of vitamin C Free Radical Research 39 7 671 86 doi 10 1080 10715760500104025 PMID 16036346 S2CID 39962659 a b Shen Jiaqi Griffiths Paul T Campbell Steven J Utinger Battist Kalberer Markus Paulson Suzanne E 1 April 2021 Ascorbate oxidation by iron copper and reactive oxygen species review model development and derivation of key rate constants Scientific Reports 11 1 7417 Bibcode 2021NatSR 11 7417S doi 10 1038 s41598 021 86477 8 ISSN 2045 2322 PMC 8016884 PMID 33795736 a b Carr A Frei B June 1999 Does vitamin C act as a pro oxidant under physiological conditions FASEB Journal 13 9 1007 24 doi 10 1096 fasebj 13 9 1007 PMID 10336883 S2CID 15426564 a b Ho YS Magnenat JL Gargano M Cao J October 1998 The nature of antioxidant defense mechanisms a lesson from transgenic studies Environmental Health Perspectives 106 Suppl 5 1219 28 doi 10 2307 3433989 JSTOR 3433989 PMC 1533365 PMID 9788901 Zelko IN Mariani TJ Folz RJ August 2002 Superoxide dismutase multigene family a comparison of the CuZn SOD SOD1 Mn SOD SOD2 and EC SOD SOD3 gene structures evolution and expression Free Radical Biology amp Medicine 33 3 337 49 doi 10 1016 S0891 5849 02 00905 X PMID 12126755 a b Bannister JV Bannister WH Rotilio G 1987 Aspects of the structure function and applications of superoxide dismutase CRC Critical Reviews in Biochemistry 22 2 111 80 doi 10 3109 10409238709083738 PMID 3315461 Johnson F Giulivi C 2005 Superoxide dismutases and their impact upon human health Molecular Aspects of Medicine 26 4 5 340 52 doi 10 1016 j mam 2005 07 006 PMID 16099495 Nozik Grayck E Suliman HB Piantadosi CA December 2005 Extracellular superoxide dismutase The International Journal of Biochemistry amp Cell Biology 37 12 2466 71 doi 10 1016 j biocel 2005 06 012 PMID 16087389 Melov S Schneider JA Day BJ Hinerfeld D Coskun P Mirra SS Crapo JD Wallace DC February 1998 A novel neurological phenotype in mice lacking mitochondrial manganese superoxide dismutase Nature Genetics 18 2 159 63 doi 10 1038 ng0298 159 PMID 9462746 S2CID 20843002 Reaume AG Elliott JL Hoffman EK Kowall NW Ferrante RJ Siwek DF Wilcox HM Flood DG Beal MF Brown RH Scott RW Snider WD May 1996 Motor neurons in Cu Zn superoxide dismutase deficient mice develop normally but exhibit enhanced cell death after axonal injury Nature Genetics 13 1 43 7 doi 10 1038 ng0596 43 PMID 8673102 S2CID 13070253 Van Camp W Inze D Van Montagu M 1997 The regulation and function of tobacco superoxide dismutases Free Radical Biology amp Medicine 23 3 515 20 doi 10 1016 S0891 5849 97 00112 3 PMID 9214590 Chelikani P Fita I Loewen PC January 2004 Diversity of structures and properties among catalases PDF Cellular and Molecular Life Sciences Submitted manuscript 61 2 192 208 doi 10 1007 s00018 003 3206 5 hdl 10261 111097 PMID 14745498 S2CID 4411482 Zamocky M Koller F 1999 Understanding the structure and function of catalases clues from molecular evolution and in vitro mutagenesis Progress in Biophysics and Molecular Biology 72 1 19 66 doi 10 1016 S0079 6107 98 00058 3 PMID 10446501 del Rio LA Sandalio LM Palma JM Bueno P Corpas FJ November 1992 Metabolism of oxygen radicals in peroxisomes and cellular implications Free Radical Biology amp Medicine 13 5 557 80 doi 10 1016 0891 5849 92 90150 F PMID 1334030 Hiner AN Raven EL Thorneley RN Garcia Canovas F Rodriguez Lopez JN July 2002 Mechanisms of compound I formation in heme peroxidases Journal of Inorganic Biochemistry 91 1 27 34 doi 10 1016 S0162 0134 02 00390 2 PMID 12121759 Mueller S Riedel HD Stremmel W December 1997 Direct evidence for catalase as the predominant H2O2 removing enzyme in human erythrocytes Blood 90 12 4973 8 doi 10 1182 blood V90 12 4973 PMID 9389716 Ogata M February 1991 Acatalasemia Human Genetics 86 4 331 40 doi 10 1007 BF00201829 PMID 1999334 Parsonage D Youngblood D Sarma G Wood Z Karplus P Poole L 2005 Analysis of the link between enzymatic activity and oligomeric state in AhpC a bacterial peroxiredoxin Biochemistry 44 31 10583 92 doi 10 1021 bi050448i PMC 3832347 PMID 16060667 PDB 1YEX Rhee SG Chae HZ Kim K June 2005 Peroxiredoxins a historical overview and speculative preview of novel mechanisms and emerging concepts in cell signaling Free Radical Biology amp Medicine 38 12 1543 52 doi 10 1016 j freeradbiomed 2005 02 026 PMID 15917183 Wood ZA Schroder E Robin Harris J Poole LB January 2003 Structure mechanism and regulation of peroxiredoxins Trends in Biochemical Sciences 28 1 32 40 doi 10 1016 S0968 0004 02 00003 8 PMID 12517450 Claiborne A Yeh JI Mallett TC Luba J Crane EJ Charrier V Parsonage D November 1999 Protein sulfenic acids diverse roles for an unlikely player in enzyme catalysis and redox regulation Biochemistry 38 47 15407 16 doi 10 1021 bi992025k PMID 10569923 S2CID 29055779 Jonsson TJ Lowther WT 2007 The peroxiredoxin repair proteins Peroxiredoxin Systems Subcellular Biochemistry Vol 44 pp 115 41 doi 10 1007 978 1 4020 6051 9 6 ISBN 978 1 4020 6050 2 PMC 2391273 PMID 18084892 Neumann CA Krause DS Carman CV Das S Dubey DP Abraham JL Bronson RT Fujiwara Y Orkin SH Van Etten RA July 2003 Essential role for the peroxiredoxin Prdx1 in erythrocyte antioxidant defence and tumour suppression PDF Nature 424 6948 561 5 Bibcode 2003Natur 424 561N doi 10 1038 nature01819 PMID 12891360 S2CID 3570549 Lee TH Kim SU Yu SL Kim SH Park DS Moon HB Dho SH Kwon KS Kwon HJ Han YH Jeong S Kang SW Shin HS Lee KK Rhee SG Yu DY June 2003 Peroxiredoxin II is essential for sustaining life span of erythrocytes in mice Blood 101 12 5033 8 doi 10 1182 blood 2002 08 2548 PMID 12586629 Dietz KJ Jacob S Oelze ML Laxa M Tognetti V de Miranda SM Baier M Finkemeier I 2006 The function of peroxiredoxins in plant organelle redox metabolism Journal of Experimental Botany 57 8 1697 709 doi 10 1093 jxb erj160 PMID 16606633 Nordberg J Arner ES December 2001 Reactive oxygen species antioxidants and the mammalian thioredoxin system Free Radical Biology amp Medicine 31 11 1287 312 doi 10 1016 S0891 5849 01 00724 9 PMID 11728801 Vieira Dos Santos C Rey P July 2006 Plant thioredoxins are key actors in the oxidative stress response Trends in Plant Science 11 7 329 34 doi 10 1016 j tplants 2006 05 005 PMID 16782394 Arner ES Holmgren A October 2000 Physiological functions of thioredoxin and thioredoxin reductase European Journal of Biochemistry 267 20 6102 9 doi 10 1046 j 1432 1327 2000 01701 x PMID 11012661 Mustacich D Powis G February 2000 Thioredoxin reductase The Biochemical Journal 346 1 1 8 doi 10 1042 0264 6021 3460001 PMC 1220815 PMID 10657232 Creissen G Broadbent P Stevens R Wellburn AR Mullineaux P May 1996 Manipulation of glutathione metabolism in transgenic plants Biochemical Society Transactions 24 2 465 9 doi 10 1042 bst0240465 PMID 8736785 Brigelius Flohe R November 1999 Tissue specific functions of individual glutathione peroxidases Free Radical Biology amp Medicine 27 9 10 951 65 doi 10 1016 S0891 5849 99 00173 2 PMID 10569628 Ho YS Magnenat JL Bronson RT Cao J Gargano M Sugawara M Funk CD June 1997 Mice deficient in cellular glutathione peroxidase develop normally and show no increased sensitivity to hyperoxia The Journal of Biological Chemistry 272 26 16644 51 doi 10 1074 jbc 272 26 16644 PMID 9195979 de Haan JB Bladier C Griffiths P Kelner M O Shea RD Cheung NS Bronson RT Silvestro MJ Wild S Zheng SS Beart PM Hertzog PJ Kola I August 1998 Mice with a homozygous null mutation for the most abundant glutathione peroxidase Gpx1 show increased susceptibility to the oxidative stress inducing agents paraquat and hydrogen peroxide The Journal of Biological Chemistry 273 35 22528 36 doi 10 1074 jbc 273 35 22528 hdl 10536 DRO DU 30101410 PMID 9712879 Sharma R Yang Y Sharma A Awasthi S Awasthi YC April 2004 Antioxidant role of glutathione S transferases protection against oxidant toxicity and regulation of stress mediated apoptosis Antioxidants amp Redox Signaling 6 2 289 300 doi 10 1089 152308604322899350 PMID 15025930 Hayes JD Flanagan JU Jowsey IR 2005 Glutathione transferases Annual Review of Pharmacology and Toxicology 45 51 88 doi 10 1146 annurev pharmtox 45 120403 095857 PMID 15822171 a b Stanner SA Hughes J Kelly CN Buttriss J May 2004 A review of the epidemiological evidence for the antioxidant hypothesis Public Health Nutrition 7 3 407 22 doi 10 1079 PHN2003543 PMID 15153272 Food Nutrition Physical Activity and the Prevention of Cancer a Global Perspective Archived 23 September 2015 at the Wayback Machine World Cancer Research Fund 2007 ISBN 978 0 9722522 2 5 Rice Evans Catherine A Miller Nicholas J Paganga George 1996 Structure antioxidant activity relationships of flavonoids and phenolic acids Free Radical Biology and Medicine 20 7 933 956 doi 10 1016 0891 5849 95 02227 9 PMID 8743980 Del Rio D Rodriguez Mateos A Spencer JP Tognolini M Borges G Crozier A May 2013 Dietary poly phenolics in human health structures bioavailability and evidence of protective effects against chronic diseases Antioxidants amp Redox Signaling 18 14 1818 1892 doi 10 1089 ars 2012 4581 PMC 3619154 PMID 22794138 Flavonoids Linus Pauling Institute Oregon State University Corvallis 2016 Retrieved 24 July 2016 Lemmo W September 2014 Potential interactions of prescription and over the counter medications having antioxidant capabilities with radiation and chemotherapy International Journal of Cancer 137 11 2525 33 doi 10 1002 ijc 29208 PMID 25220632 S2CID 205951215 Forman Henry Jay Zhang Hongqiao 30 June 2021 Targeting oxidative stress in disease promise and limitations of antioxidant therapy Nature Reviews Drug Discovery 20 9 689 709 doi 10 1038 s41573 021 00233 1 ISSN 1474 1784 PMC 8243062 PMID 34194012 Hurrell RF September 2003 Influence of vegetable protein sources on trace element and mineral bioavailability The Journal of Nutrition 133 9 2973S 7S doi 10 1093 jn 133 9 2973S PMID 12949395 Hunt JR September 2003 Bioavailability of iron zinc and other trace minerals from vegetarian diets The American Journal of Clinical Nutrition 78 3 Suppl 633S 639S doi 10 1093 ajcn 78 3 633S PMID 12936958 Gibson RS Perlas L Hotz C May 2006 Improving the bioavailability of nutrients in plant foods at the household level The Proceedings of the Nutrition Society 65 2 160 8 doi 10 1079 PNS2006489 PMID 16672077 a b Mosha TC Gaga HE Pace RD Laswai HS Mtebe K June 1995 Effect of blanching on the content of antinutritional factors in selected vegetables Plant Foods for Human Nutrition 47 4 361 7 doi 10 1007 BF01088275 PMID 8577655 S2CID 1118651 Sandberg AS December 2002 Bioavailability of minerals in legumes The British Journal of Nutrition 88 Suppl 3 S281 5 doi 10 1079 BJN 2002718 PMID 12498628 a b Beecher GR October 2003 Overview of dietary flavonoids nomenclature occurrence and intake The Journal of Nutrition 133 10 3248S 3254S doi 10 1093 jn 133 10 3248S PMID 14519822 Omenn GS Goodman GE Thornquist MD Balmes J Cullen MR Glass A Keogh JP Meyskens FL Valanis B Williams JH Barnhart S Cherniack MG Brodkin CA Hammar S November 1996 Risk factors for lung cancer and for intervention effects in CARET the Beta Carotene and Retinol Efficacy Trial PDF Journal of the National Cancer Institute 88 21 1550 9 doi 10 1093 jnci 88 21 1550 PMID 8901853 Albanes D June 1999 Beta carotene and lung cancer a case study The American Journal of Clinical Nutrition 69 6 1345S 50S doi 10 1093 ajcn 69 6 1345S PMID 10359235 a b Bjelakovic G Nikolova D Gluud LL Simonetti RG Gluud C February 2007 Mortality in randomized trials of antioxidant supplements for primary and secondary prevention systematic review and meta analysis JAMA 297 8 842 57 doi 10 1001 jama 297 8 842 PMID 17327526 a b Bjelakovic G Nikolova D Gluud LL Simonetti RG Gluud C 14 March 2012 Antioxidant supplements for prevention of mortality in healthy participants and patients with various diseases The Cochrane Database of Systematic Reviews 2012 3 CD007176 doi 10 1002 14651858 CD007176 pub2 hdl 10138 136201 PMC 8407395 PMID 22419320 Study Citing Antioxidant Vitamin Risks Based On Flawed Methodology Experts Argue News release from Oregon State University published on ScienceDaily Retrieved 19 April 2007 Miller ER Pastor Barriuso R Dalal D Riemersma RA Appel LJ Guallar E January 2005 Meta analysis high dosage vitamin E supplementation may increase all cause mortality Annals of Internal Medicine 142 1 37 46 doi 10 7326 0003 4819 142 1 200501040 00110 PMID 15537682 a b Bjelakovic G Nagorni A Nikolova D Simonetti RG Bjelakovic M Gluud C July 2006 Meta analysis antioxidant supplements for primary and secondary prevention of colorectal adenoma Alimentary Pharmacology amp Therapeutics 24 2 281 91 doi 10 1111 j 1365 2036 2006 02970 x PMID 16842454 S2CID 20452618 Cortes Jofre M Rueda JR Asenjo Lobos C Madrid E Bonfill Cosp X March 2020 Drugs for preventing lung cancer in healthy people The Cochrane Database of Systematic Reviews 2020 3 CD002141 doi 10 1002 14651858 CD002141 pub3 PMC 7059884 PMID 32130738 Shenkin A February 2006 The key role of micronutrients Clinical Nutrition 25 1 1 13 doi 10 1016 j clnu 2005 11 006 PMID 16376462 Ranchordas Mayur K Rogerson David Soltani Hora Costello Joseph T 14 December 2017 Antioxidants for preventing and reducing muscle soreness after exercise The Cochrane Database of Systematic Reviews 2017 12 CD009789 doi 10 1002 14651858 CD009789 pub2 ISSN 1469 493X PMC 6486214 PMID 29238948 Rodriguez Amaya DB 2003 Food carotenoids analysis composition and alterations during storage and processing of foods Forum of Nutrition 56 35 7 PMID 15806788 Maiani G Caston MJ Catasta G Toti E Cambrodon IG Bysted A Granado Lorencio F Olmedilla Alonso B Knuthsen P Valoti M Bohm V Mayer Miebach E Behsnilian D Schlemmer U September 2009 Carotenoids actual knowledge on food sources intakes stability and bioavailability and their protective role in humans Molecular Nutrition amp Food Research 53 Suppl 2 S194 218 doi 10 1002 mnfr 200800053 hdl 10261 77697 PMID 19035552 Archived from the original on 27 September 2018 Retrieved 18 April 2017 Henry CJ Heppell N February 2002 Nutritional losses and gains during processing future problems and issues The Proceedings of the Nutrition Society 61 1 145 8 doi 10 1079 PNS2001142 PMID 12002789 Antioxidants and Cancer Prevention Fact Sheet National Cancer Institute Archived from the original on 4 March 2007 Retrieved 27 February 2007 Ortega R December 2006 Importance of functional foods in the Mediterranean diet Public Health Nutrition 9 8A 1136 40 doi 10 1017 S1368980007668530 PMID 17378953 Witschi A Reddy S Stofer B Lauterburg BH 1992 The systemic availability of oral glutathione European Journal of Clinical Pharmacology 43 6 667 9 doi 10 1007 BF02284971 PMID 1362956 S2CID 27606314 Flagg EW Coates RJ Eley JW Jones DP Gunter EW Byers TE Block GS Greenberg RS 1994 Dietary glutathione intake in humans and the relationship between intake and plasma total glutathione level Nutrition and Cancer 21 1 33 46 doi 10 1080 01635589409514302 PMID 8183721 Dodd S Dean O Copolov DL Malhi GS Berk M December 2008 N acetylcysteine for antioxidant therapy pharmacology and clinical utility Expert Opinion on Biological Therapy 8 12 1955 62 doi 10 1517 14728220802517901 PMID 18990082 S2CID 74736842 van de Poll MC Dejong CH Soeters PB June 2006 Adequate range for sulfur containing amino acids and biomarkers for their excess lessons from enteral and parenteral nutrition The Journal of Nutrition 136 6 Suppl 1694S 1700S doi 10 1093 jn 136 6 1694S PMID 16702341 Cao G Alessio HM Cutler RG March 1993 Oxygen radical absorbance capacity assay for antioxidants Free Radical Biology amp Medicine 14 3 303 11 doi 10 1016 0891 5849 93 90027 R PMID 8458588 Ou B Hampsch Woodill M Prior RL October 2001 Development and validation of an improved oxygen radical absorbance capacity assay using fluorescein as the fluorescent probe Journal of Agricultural and Food Chemistry 49 10 4619 26 doi 10 1021 jf010586o PMID 11599998 a b Withdrawn Oxygen Radical Absorbance Capacity ORAC of Selected Foods Release 2 2010 United States Department of Agriculture Agricultural Research Service 16 May 2012 Retrieved 13 June 2012 Prior RL Wu X Schaich K May 2005 Standardized methods for the determination of antioxidant capacity and phenolics in foods and dietary supplements PDF Journal of Agricultural and Food Chemistry 53 10 4290 302 doi 10 1021 jf0502698 PMID 15884874 Archived from the original PDF on 29 December 2016 Retrieved 24 October 2017 Further reading editHalliwell B Gutteridge JM 2015 Free Radicals in Biology and Medicine 5th ed Oxford University Press ISBN 978 0 19 856869 8 Lane N 2003 Oxygen The Molecule That Made the World Oxford University Press ISBN 978 0 19 860783 0 Pokorny J Yanishlieva N Gordon MH 2001 Antioxidants in Food Practical Applications CRC Press ISBN 978 0 8493 1222 9 External links edit nbsp Media related to Antioxidants at Wikimedia Commons Retrieved from https en wikipedia org w index php title Antioxidant amp oldid 1198772731, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.