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:''This article is about the [[nutrient]]; for other uses see [[Vitamin C (disambiguation)]].
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'''Vitamin C''' is a water-soluble vitamin required by several mammalian species, including humans and higher primates, who mainly get it by eating fresh fruits and vegetables. It has many physiological effects and, at present, eight different well characterized roles, but it is not specifically required for any enzyme.<ref>Barja, G (1996) Ascorbic acid and aging. In {{cite book |author=Harris, James W. |title=Ascorbic acid: biochemistry and biomedical cell biology |publisher=Plenum Press |location=New York |year=1996 |pages= |isbn=0-306-45148-4 |oclc= |doi=}}</ref> As research advances, it appears that its first name, '''ignose''', meaning "I don't know", or "godnose," describes it best.<ref name="pmid10570371">{{cite journal |author=Hirschmann JV ''& al.''|title=Adult scurvy |journal=J Am Acad Dermatol |volume=41 |pages=895–906; quiz 907–10 |year=1999 |pmid=10570371}}</ref>
[[Image:VitC4.jpg|left|thumb|Vitamin C]]
:''This article is about the biochemistry of '''vitamin C''', or '''ascorbic acid'''.  For the chemical properties, see [[Ascorbic acid]].''
 
First known as the vitamin that prevents [[scurvy]] (hence its chemical name, '''ascorbic acid'''), vitamin C is an important factor in * the maintenance of good health. Vitamin C is:
* the most widely sold dietary supplement in the world;
* required for the maintenance of the most abundant protein in the body,
* the most "luminously controversial of all biological, alternative cancer therapies",<ref name="pmid11232135">{{cite journal |author=Hoffer LJ |title=Proof versus plausibility: rules of engagement for the struggle to evaluate alternative cancer therapies |journal=CMAJ : Canadian Medical Association journal &#61; journal de l'Association medicale canadienne |volume=164  |pages=351–3 |year=2001 |pmid=11232135 |doi= |issn=}}</ref>
* the vitamin which intake has declined the most drastically in the course of human evolution, and
* the vitamin which requirements have been debated for the most time and with the most intensity.
 
This article describes the debates about vitamin C, and presents the state-of-the-art in vitamin C therapeutics and the context in which knowledge on this nutrient has been produced.
 
== Description==
The evolution of vertebrates can be viewed as the history of how they responded to the "''the call for oxygen''"<ref>Krogh A (1941) ''The Comparative Physiology of Respiratory Mechanisms.'' Philadelphia: University of Pennsylvania Press</ref> -- for "the fire of life".<ref>Kleiber M (1961) ''The Fire of Life.'' New York: Wiley.</ref> Most important is the need to use this fire without being "burnt" by it.<ref name="pmid12430953">{{cite journal |author=Maina JN |title=Structure, function and evolution of the gas exchangers: comparative perspectives |journal=J Anat |volume=201 |pages=281–304 |year=2002 |pmid=12430953}}</ref> The development of antioxidant machineries is closely intertwined with the development of species. An analysis of the evolutionary record suggests that the aquatic animals that were ancestors of amphibians did not significantly increase their concentrations of [[superoxide dismutase]] (SOD), the first line of defense against oxygen toxicity, instead, to cope with the sharp, 30-fold, increase in oxygen exposure, they developed a machinery to transform glucose into ascorbic acid.<ref name="pmid9034244">{{cite journal |author=Nandi A ''et al.'' |title=Evolutionary significance of vitamin C biosynthesis in terrestrial vertebrates |journal=Free Radic Biol Med |volume=22  |pages=1047–54 |year=1997 |pmid=9034244 |doi=}}</ref> The further evolution from reptiles to mammals was marked by a gradual increase in GULO, the fourth and last step in the vitamin C-producing machinery, and of SOD. In reptiles, about 9.4 mg/kg body weight of ascorbate is produced each day, whereas 184.2 mg/kg is produced each day in mammals (9.2 g for a 50 kg mammal).<ref name="pmid4752221">{{cite journal |author=Chatterjee IB |title=Evolution and the biosynthesis of ascorbic acid |journal=Science |volume=182 |pages=1271–2 |year=1973 |pmid=4752221}}</ref> Nonetheless, SOD tended to be favoured to the expense of GULO.
 
In exceptional cases, a complete loss of vitamin C production occurred during evolution: Old World higher primates do without endogenous vitamin C, and express roughly twice as much SOD as other mammals. Amongst those species, humans have the best SOD defense.<ref name="pmid9034244"/> It is thought that the loss of the ability to produce vitamin C occurred some 25 to 45 million years ago, when the [[natural environment]] of the common ancestor of primates was abundant in vitamin C.<ref name="OMIM - HYPOASCORBEMIA">{{cite web |url=http://www.ncbi.nlm.nih.gov/entrez/dispomim.cgi?id=240400 |title=OMIM - HYPOASCORBEMIA |accessdate=2007-11-13 |format= |work=}}</ref> Higher primates, who still live in vitamin-C rich environments, consume 2000 to 6000 mg of vitamin C per day,<ref name="pmid10378206">{{cite journal |author=Milton K |title=Nutritional characteristics of wild primate foods: do the diets of our closest living relatives have lessons for us? |journal=Nutrition |volume=15  |pages=488–98 |year=1999 |pmid=10378206 |doi= |url=http://www.direct-ms.org/pdf/EvolutionPaleolithic/primaten.pdf}}</ref>  much more than the recommended doses for modern man, which are at least 20 times lower.
 
According to the ''Online Mendeleian Inheritance in Man'' database, hypoascorbemia is a "public" inborn error of metabolism, as it affects all members of the human race.<ref name="OMIM - HYPOASCORBEMIA"/>
 
Vitamin C (chemical names ''ascorbic acid'' and ''ascorbate'') is produced from [[glucose]] in the liver of most mammals and in the kidneys of most birds and reptiles. Mammals that are unable to synthesize vitamin C include humans and other primates, guinea pigs, Indian fruit bats, rainbow trouts and Nepalese red-vented bulbols. As usually defined, a vitamin is a nutrient present in the diet that is required in small amounts for normal health; because most vertebrate species produce it in large amounts, it cannot be considered as a [[vitamin]] in these species, but a dietary intake of small amounts of vitamin C is indeed required for normal health in humans. By contrast, other vitamins are indeed required in small amounts in the diet by most mammals, including humans. Vitamin C is present in foods (particularly plants) at much higher concentrations than any other vitamin (by several ''orders of magnitude''; from 10 to 100 mg/100g).<ref name="pmid17222174">{{cite journal |author=Linster CL, Van Schaftingen E |title=Vitamin C. Biosynthesis, recycling and degradation in mammals |journal=FEBS J. |volume=274 |pages=1–22 |year=2007 |pmid=17222174}}</ref>
 
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'''Vitamin C''' is a [[nutrient]] required in very small amounts to allow a range of essential metabolic reactions in the body. Vitamin C is principally known as a [[water (molecule)|water]]-[[soluble]] anti-oxidant and has been found to prevent [[scurvy]].<ref name="UKFSA">[http://www.eatwell.gov.uk/healthydiet/nutritionessentials/vitaminsandminerals/vitaminc/ Food Standards Agency (UK)] on vitamin C</ref><ref name="UMM">[http://www.umm.edu/altmed/ConsSupplements/VitaminCAscorbicAcidcs.html University of Maryland, Medical Center] Vitamin C ( ascorbic acid). Accessed January 2007 C</ref> It is also known by the chemical name of its principal form, '''L-ascorbic acid''' or simply '''ascorbic acid'''. <ref name=" UKFSA"/> The guidance provided by the United States of America and Canada for Dietary Reference Intake (DRI) recommends 90mg per day and no more than 2g per day (2000mg/day).<ref name="US RDA">[http://www.iom.edu/Object.File/Master/7/296/webtablevitamins.pdf US Recommended Dietary Allowance (RDA)] (pdf), Page 6 on vitamin C. Accessed January 2007</ref> The article on [[ascorbic acid]] contains information on its chemical properties. This article describes its biological functions, discovery and the continuing scientific debate on how it is used by society, including its widespread application in doses larger than the officially recommended upper limit.
=== Role as enzyme cofactor ===
Vitamin C is an [[electron]] donor (reducing agent, or antioxidant), and in this role it is required by several [[enzymes]], including eight in humans. These eight enzymes are either iron-dependent [[dioxygenase]]s or copper-dependent [[monooxygenase]]s, which catalyze the incorporation of oxygen into organic substrates. Many other dioxygenases and monooxygenases probably use ascorbate as a co-substrate to reduce iron or copper, [[oxygen]], and [[2-oxo-glutarate]], a [[Krebs cycle]] intermediate, in the case of dioxygenases.<ref name="pmid11853951">{{cite journal |author=Arrigoni O, De Tullio MC |title=Ascorbic acid: much more than just an antioxidant |journal=Biochim. Biophys. Acta |volume=1569 |pages=1–9 |year=2002 |pmid=11853951}}</ref><ref name="pmid17222174"/> It is at present difficult, for this reason, to characterize this ''pleiotropic'' molecule. Three of these enzymes are involved in collagen hydroxylation, and two in carnitine synthesis.
 
[[Collagen]] is the most abundant [[protein]] in the human body. The key enzyme in collagen synthesis is [[prolyl-4-hydroxylase]] (P4H). It consumes a large part of the whole vitamin C pool, and, conversely, its rate of activity reflects vitamin C availability in cells. The role of vitamin C in animal physiology and disease cannot be explored independently from collagen's role. '''(IN PROGRESS: DEVELOP COLLAGEN ARTICLE IN PARALLEL)'''
 
More recently, a new form of the dioxygenase P4H was discovered. As opposed to the ''collagen'' P4H, the ''hypoxia-inducible factor-α'' P4H (HIFα-P4H), does not bind and transform the prolines from collagen, but prolines on sites (or [[residue]]s) of proteins with a certain sequence of amino acids<ref>The sequence is -Leu-X-X-Leu-Ala-Pro-. For more details, see Hieta R (2003) [http://herkules.oulu.fi/isbn9514271793/ Prolyl 4-hydroxylase: Structural and functional characterization of the peptide-substrate-binding domain of the human enzyme, and cloning and characterization of a plant enzyme with unique properties] - 2.2.6. HIF prolyl 4-hydroxylases. Department of Medical Biochemistry and Molecular Biology, University of Oulu</ref> It is required for the regulation of hypoxia-inducible factor, a protein that functions as an [[oxygen sensor]]<ref name="pmid17627474">{{cite journal |author=Nytko KJ ''et al''|title=Regulated function of the prolyl-4-hydroxylase domain (PHD) oxygen sensor proteins |journal=Antioxid. Redox Signal. |volume=9 |pages=1329–38 |year=2007 |pmid=17627474}}</ref> and a physiological defense against cancer formation.<ref name="pmid17785204">{{cite journal |author=Gao P ''et al'' |title=HIF-dependent antitumorigenic effect of antioxidants in vivo |journal=Cancer Cell |volume=12 |pages=230–8 |year=2007 |pmid=17785204}}</ref><ref name="pmid12702559">{{cite journal |author=Knowles HJ ''et al'' |title=Effect of ascorbate on the activity of hypoxia-inducible factor in cancer cells |journal=Cancer Res. |volume=63 |pages=1764–8 |year=2003 |pmid=12702559}}</ref>
 
Tyrosine hydroxylase is rate limiting in the synthesis of all catecholamines ([[dopamine]], [[epinephrine]] (aka adrenaline), [[norepineprine]], (aka noradrenaline).<ref name="pmid11853951"/> Norepinephrine is a neurotransmitter in the central nervous system involved in many different functions, and is released into the blood as a hormone from the adrenal medulla.
 
Carnitine is the molecule that allows most fat molecules to be carried ''in'' the [[mitochondria]] where they will be transformed into energy. Carnitine is also required to carry excess organic acids ''out'' of mitochondria, where they would otherwise impair energy production. The metabolic pathway that leads from the amino acid lysine to [[carnitine]] requires vitamin C twice. The steps are the enzymes gamma-butyrobetaine hydroxylase and epsilon-N-trimethyl-lysine hydroxylase. Low vitamin C causes a decreases in carnitine production, which contributes to fat deposition and overweight. At present, whether low levels of vitamin C might contribute to obesity is not known, but the normalisation of vitamin C levels in people with low vitamin C status was shown to raise their ability to burn fat 4-fold during submaximal exercise.<ref name="pmid-16945143">{{cite journal |author=Johnston CS ''et al.''|title=Marginal vitamin C status is associated with reduced fat oxidation during submaximal exercise in young adults |journal=Nutrition & metabolism |volume=3 |pages=35 |year=2006 |pmid=16945143 |doi=10.1186/1743-7075-3-35 |issn=}}</ref>
 
=== Antioxidant functions===
(in progress)
 
Vitamin C is also a major water [[phase]] low-[[molecular weight]] [[antioxidant]].
 
In oxidation process the molecule of vitamin C step by step oxidazed with built up some active [[prooxidant]] substances. <ref name="pro-oxidant chemistry">[http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6T6D-450HJFJ-1&_user=10&_coverDate=07%2F31%2F2002&_rdoc=1&_fmt=&_orig=search&_sort=d&view=c&_acct=C000050221&_version=1&_urlVersion=0&_userid=10&md5=7a4aabec86fcb36e03032cf848bb2afa ‘’The pro-oxidant chemistry of the natural antioxidants vitamin C, vitamin E, carotenoids and flavonoids’’]  (Rietjens IMCM ''et al.'' )</ref>.
 
=== Action on receptors ===
 
At physiological concentrations, Vitamin C interacts with some receptors in a manner that should be distinguished from its antioxidant effects. Vitamin C binds to (and inhibits) the [[NMDA receptor]] - an important receptor for the [[neurotransmitter]] [[glutamate]]<ref name="pmid1983355">{{cite journal |author=Majewska MD, Bell JA |title=Ascorbic acid protects neurons from injury induced by glutamate and NMDA |journal=Neuroreport |volume=1 |pages=194–6 |year=1990 |pmid=1983355}}</ref><ref name="pmid1964838"/>. It also binds to (and enhances signalling through) adrenergic receptors<ref name="pmid14975930">{{cite journal |author=Dillon PF '' et al.''|title=Antioxidant-independent ascorbate enhancement of catecholamine-induced contractions of vascular smooth muscle |journal=Am J Physiol |volume=286 |pages=H2353–60 |year=2004 |pmid=14975930}}</ref> and some [[histamine]] receptors.<ref name="pmid16760260">{{cite journal |author=Dillon PF ''& al.''|title=Ascorbate enhancement of H1 histamine receptor sensitivity coincides with ascorbate oxidation inhibition by histamine receptors |journal=Am J Physiol |volume=291 |pages=C977–84 |year=2006 |pmid=16760260 </ref> Interestingly, considering the widespread expression of histamine and adrenergic receptors,  by binding vitamin C they might be important in protecting it from oxidation.<ref name="pmid16760260"/> In this case, the receptors and the antioxidant could be said to have a privileged relationship in which they enhance each other's specific function. For the NMDA receptor, the status of vitamin C might be relatively privileged as well. The NMDA receptor is involved in [[memory]] and [[learning]], as well as [[anxiety]], [[epilepsy]], and [[neurodegeneration]], and signalling though it is enhanced when it is reduced (not oxidized) at the so-called [[NMDA redox site]].<ref name="pmid10704515">{{cite journal |author=Sanchez RM ''et al'' |title=Novel role for the NMDA receptor redox modulatory site in the pathophysiology of seizures |journal=J Neurosci |volume=20  |pages=2409–17 |year=2000 |pmid=10704515}}</ref> However, somewhat paradoxically, signalling through the NMDA receptor is inhibited, notably, by the ''anti''oxidant ascorbate.<ref name="pmid1964838">{{cite journal |author=Majewska MD ''et al.''|title=Regulation of the NMDA receptor by redox phenomena: inhibitory role of ascorbate |journal=Brain Res |volume=537 |pages=328–32 |year=1990 |pmid=1964838}}</ref> In comparison, [[lipoic acid]] and [[glutathione]], in their reduced forms, enhance receptor function and may be involved ''in vivo'' in epileptogenesis, while their oxidized forms act oppositely.<ref name="pmid10704515"/> The inhibitory binding of ascorbate, hydroquinone and the redox cofactor [[pyrroloquinoline quinone]], are abolished if the NMDA receptor redox site is oxidized into a disulfide.<ref name="pmid10704515"/>
 
=== Biosynthesis ===
Yeasts do not synthesize vitamin C, but produce another antioxidant, [[erythorbic acid]].<ref name="pmid10094636">{{cite journal |author=Huh WK ''et al.'' |title=D-Erythroascorbic acid is an important antioxidant molecule in Saccharomyces cerevisiae |journal=Mol Microbiol |volume=30 |pages=895–903 |year=1998 |pmid=10094636 |doi=}}</ref> However, metabolic engineering of yeasts such as ''[[Saccharomyces cerevisiae]]'' can be used for the industrial production of vitamin C.<ref name="pmid15466554">{{cite journal |author=Sauer M ''et al.'' |title=Production of L-ascorbic acid by metabolically engineered Saccharomyces cerevisiae and Zygosaccharomyces bailii |journal=Appl Environ Microbiol |volume=70  |pages=6086–91 |year=2004 |pmid=15466554 |doi=10.1128/AEM.70.10.6086-6091.2004}}</ref>
 
Plants, humans' main source of vitamin C, produce it in large amounts as a defense against viruses, bacteria and other environmental challenges and to cope with the internal challenges associated with [[photosynthesis]].<ref name="pmid17517613">{{cite journal |author=Giovannoni JJ |title=Completing a pathway to plant vitamin C synthesis |journal=Proc Natl Acad Sci USA |volume=104  |pages=9109–10 |year=2007 |pmid=17517613 |doi=10.1073/pnas.0703222104}}</ref>


== General description==
In animals, vitamin C is synthesised through four enzyme-driven steps, which convert glucose to ascorbic acid. The last enzyme in the process, [[l-gulonolactone oxidase]], cannot be made by humans because the gene for this enzyme is defective (Pseudogene ΨGULO). The loss of an enzyme concerned with [[ascorbic acid]] synthesis has occurred quite frequently in [[evolution]] and has affected most [[fish]]; many birds; some [[bat]]s; [[guinea pig]]s; and most [[primates]], including humans. The [[mutation]]s have not been lethal because ascorbic acid is so prevalent in the environment.
Vitamin C is a [[weak acid]], called [[ascorbic acid]] or a salt [[ascorbate]]. It is the [[Enantiomer|<small>L</small>-enantiomer]] of [[ascorbic acid]]. The [[Enantiomer|<small>D</small>-enantiomer]] shows no biological activity. Both are mirror image forms of the same chemical molecular structure (see [[optical isomerism|optical isomers]]).


It is a carbon based compound of six carbon atoms structurally related to [[glucose]]. It exists as two inter-convertible compounds: L-ascorbic acid, which is a strong [[Redox|reducing]] agent, and its [[Redox|oxidised]] derivative, [[Dehydroascorbic acid|L-dehydroascorbic acid]].<ref name="UKFSA Risk">[http://www.food.gov.uk/multimedia/pdfs/evm_c.pdf ‘’Vitamin C – Risk Assessment’’].,  UK Food Standards Agency  (PDF) Accessed January 2007</ref>
In addition to those species who lost vitamin C synthesis during evolution, it is worth mentioning the Shionogi rat, which is used in laboratories (much like the guinea pig) to study the inability to produce vitamin C and its consequences.


The active part of the substance is the ascorbate [[ion]], which can express itself as either an acid or a salt of ascorbate that is neutral or slightly basic. Commercial vitamin C is often a mix of ascorbic acid, sodium ascorbate and/or other ascorbates.  Some supplements contain in part the <small>D</small>-enantiomer, which is useless and harmless.  See the [[ascorbic acid]] article for a full description of the molecule's chemical properties. <ref name=" UKFSA Risk"/>
'''The ODS rat'''


[[Image:VitC4.jpg|center|frame|Vitamin C]]
The newly developed model of hypoascorbemia, the [[Osteogenic Disorder Shionogi rat]] (ODS rat), provides a unique occasion to analyze the early adaptative changes occurring when a species loses endogenous vitamin C synthesis. Contrary to the long-held belief that the high vitamin C intake of early anthropoideans was alone sufficient to compensate for the mutation,<ref name="OMIM - HYPOASCORBEMIA"/> ODS rats compensate this metabolic disease through several different mechanisms, some of which are not well characterized yet.


=== Synthesis in organisms ===
====Is uric acid an antioxidant ''for'' vitamin C?====
Almost all animals and plants can synthesize vitamin C.  There are some exceptions, such as [[human]]s and a small number of other animals, including, [[ape]]s, [[guinea pig]]s, the [[red-vented bulbul]], a [[Megabat|fruit-eating bat]] and a species of [[trout]]. <ref name=" UKFSA Risk"/> This has led some scientists, including chemist [[Linus Pauling]] to [[hypothesis|hypothesize]] that these species lost the ability to produce their own vitamin C, and that if their diets were supplemented with an amount of the nutrient proportional to the amount produced in animal species that do synthesize their own vitamin C, better health would result.  The species-specific loss of the ability to synthesize ascorbate strikingly parallels the evolutionary loss of the ability to break down [[uric acid]].  Uric acid and ascorbate are both strong reducing agents (electron-donors).  This has led to the suggestion [http://www.drproctor.com/rev/ascorbicuric.htm ] that in higher primates, uric acid has taken over some of the functions of ascorbate. Ascorbic acid can be broken down by '''ascorbic acid oxidase''' an enzyme which catalyes the oxidation of ascorbic acid.


Some [[microorganism]]s such as the yeast ''[[Saccharomyces cerevisiae]]'' have been shown to be able to synthesize ascorbic acid. [http://cat.inist.fr/?aModele=afficheN&cpsidt=1486248]
It was noted in 1970 that the inability of higher primates to break down [[uric acid]], due to a mutation in the enzyme [[uricase]], parallels the well-known metabolic disease of higher primates.<ref name="Ascorbic Uric Nature 1970">{{cite web |url=http://www.drproctor.com/rev/ascorbicuric.htm |title=Ascorbic Acid and Uric Acid, Similar Functions ?}}</ref> Uric acid and ascorbate are both strong reducing agents (electron-donors): uric acid scavenges oxygen radicals, singlet oxygen, oxo-haem oxidants and hydroperoxyl radicals. In addition, uric acid can form complexes with iron and inhibit the [[lipid peroxidation | oxidation of lipids]] and vitamin C by the Fe3+ ion. Uric acid concentrations are so high in human plasma that they almost reach saturation; they are 5 to 10 times higher than those of vitamin C and several orders of magnitude higher than the concentrations of the potentially deleterious ion.<ref name="pmid3753442">{{cite journal |author=Davies KJ ''& al.'' |title=Uric acid-iron ion complexes. A new aspect of the antioxidant functions of uric acid |journal=Biochem. J. |volume=235 |pages=747–54 |year=1986 |pmid=3753442}}</ref>


=== Discovery ===
The hypothesis by Proctor that uric acid has taken over some of the functions of ascorbic acid received experimental support thirty years later, when it was shown that ODS rats spontaneously develop high plasma uric acid (without the help of a mutation in the uricase gene), amongst many other compensatory mechanisms. In further support of this hypothesis, uric acid was shown to protect different superoxide dismutases against peroxide-mediated inactivation.<ref name="pmid12231552">{{cite journal |author=Landmesser U, Drexler H |title=Toward understanding of extracellular superoxide dismutase regulation in atherosclerosis: a novel role of uric acid? |journal=Arterioscler Thromb Vasc Biol |volume=22 |pages=1367–8 |year=2002 |pmid=12231552 |doi=}}</ref><ref name="pmid12231557">{{cite journal |author=Hink HU ''et al.'' |title=Peroxidase properties of extracellular superoxide dismutase: role of uric acid in modulating in vivo activity |journal=Arterioscler Thromb Vasc Biol |volume=22  |pages=1402–8 |year=2002 |pmid=12231557 |doi=}}</ref> Hence, uric acid further improves the expression of SODs, that already tend to greater expression with the evolution of heavier animals.


:''See [[Vitamin C#Discovery and history|Discovery and history section]] below for a fuller account.''
Overall, one fundamental component of the multifaceted antioxidant protection afforded by uric acid is the formation of complexes with iron. The University of Southern California group who studied extensively the relative role of uric acid in humans, recall: "During the course of our studies we found that urate was able to inhibit a number of oxidative reactions without itself being consumed. This observation deviated from the classical mechanism for antioxidant action and was characteristically seen in radical reactions involving redox active metals, such as iron."<ref name="pmid1962559">{{cite journal |author=Sevanian A, Davies KJ, Hochstein P |title=Serum urate as an antioxidant for ascorbic acid |journal=Am. J. Clin. Nutr. |volume=54 |pages=1129S–1134S |year=1991 |pmid=1962559 |url=http://www.ajcn.org/cgi/pmidlookup?view=long&pmid=1962559}}</ref>
Vitamin C was first isolated in 1928, and in 1932 it was proved to be the agent which prevents [[scurvy]]. Both [[Charles Glen King]] at the [[University of Pittsburgh]] and [[Albert Szent-Györgyi]] (working with ex-[[Pittsburgh, Pennsylvania|Pittsburgh]] researcher [[Joseph Svirbely]]) came to discover what is now known as vitamin C around April of 1932. Although Szent-Györgyi was awarded the 1937 [[Nobel Prize in Medicine]], many feel King is as responsible for its development. <ref>[http://www.pitt.edu/history/1932.html University of Pittsburgh]"In recognition of this medical breakthrough, some scientists believe that King deserved a Nobel Prize." Accessed February 2007 </ref> A detailed history of vitamin C is provided [[Vitamin C#Discovery and history|below]].
Any antioxidant molecule that can perform this function ''without'' being used up in the process is advantageous. Uric acid is strongly correlated with cardiovascular events as well as mortality in type 2 diabetes.<ref name="pmid17976199">{{cite journal |author=Ioachimescu AG, Brennan DM, Hoar BM, Kashyap SR, Hoogwerf BJ |title=Serum uric acid, mortality and glucose control in patients with Type 2 diabetes mellitus: a PreCIS database study |journal=Diabet. Med. |volume=24 |issue=12 |pages=1369–74 |year=2007 |pmid=17976199 |doi=10.1111/j.1464-5491.2007.02302.x}}</ref> Future intervention studies will allow to tell if the rise in uric acid is pathogenic or, on the contrary, adaptative and if so, whether it behaves as an "antioxidant ''for'' ascorbate," by protecting it from iron-mediated oxidation.


=== Vitamin C deficiency ===
[[Pauling, Linus|Linus Pauling]] specified that the machinery for producing vitamin C was a burden that handicapped vitamin C-synthesizing individuals.  In times of stress, the synthesis of vitamin C from glycogen can raise sharply: an adult [[goat]], who manufactures more than 13,000 mg of vitamin C per day in normal health, will produce as much as 100,000 mg daily when faced with life-threatening disease, trauma or stress.<ref>[http://www.siumed.edu/mrc/research/vitamins/gi13sg.html ''Vitamins and Minerals''] M. Ellert, Southern Illinois University, School of Medicine. 1998  - "However, if the ability of a 70-kg goat to synthesize endogenous ascorbate is compared with the RDA of a 70-kg human, there is a 300-fold difference (13,000 mg vs. 45 mg)." To be more accurate, the difference is much greater, since those 13,000 mg are amounts directly released in the circulation, and are thus equivalent to intravenous, and not oral, doses.</ref>
No bodily organ stores ascorbate as a primary function, and so the body soon depletes itself of ascorbate if fresh supplies are not consumed through the digestive system, eventually leading to the deficiency disease known as [[scurvy]] (a form of [[avitaminosis]]), which results in illness and death if consumption of vitamin C is not resumed in time.


== Daily requirements and dose dependent effects ==
When vitamin C-synthesizing species are exposed to high dietary levels of vitamin C, vitamin C concentrations decrease disproportionately in various organs, suggesting that endogenous synthesis of the vitamin is downregulated (it responds by decreasing) and/or that catabolism (destruction) or elimination of the vitamin are increased.<ref name="pmid3559744">{{cite journal |author=Tsao CS ''et al.'' |title=Effect of dietary ascorbic acid intake on tissue vitamin C in mice |journal=J Nutr |volume=117 |pages=291–7 |year=1987 |pmid=3559744 |doi= |issn=}}</ref> Whether this "overreaction", in an environment providing large amounts of vitamin C, contributed to the selection of individuals with low or absent vitamin C synthesis is an open question.
There is continuing debate within the scientific community over the best dose schedule (the amount and frequency of intake) of vitamin C for maintaining optimal health in humans.<ref name="PR Newswire">[http://www.prnewswire.com/cgi-bin/stories.pl?ACCT=109&STORY=/www/story/07-06-2004/0002204911&EDATE= PR Newswire Association] British pharmacology professors debate with the US National Institutes of Health over the optimum vitamin C dose - (6th July 2004'') </ref>


=== Government agency recommended intake levels ===
Another possible compensatory mechanism is the synthesis of lipoprotein(a). Lipoprotein(a), which is almost exclusively present in primates, might strengthen the extracellular matrix and compensate to some extent the relative lack of collagen and elastin synthesis. In addition, evidence suggests that, in some circumstances, lp(a), like vitamin C, delays lipid oxidation (peroxidation).<ref name="pmid10700477">{{cite journal |author=Lippi G, Guidi G |title=Lipoprotein(a): from ancestral benefit to modern pathogen? |journal=QJM |volume=93  |pages=75–84 |year=2000 |pmid=10700477 |doi= |url=http://qjmed.oxfordjournals.org/cgi/content/full/93/2/75#top}}</ref>
A balanced diet without supplementation contains enough vitamin C to prevent acute scurvy in an average healthy adult. People who smoke, those under stress, and pregnant women require slightly more vitamin C.


Recommendations for vitamin C intake have been set by various national agencies as described below:
Amongst higher primates, those who became [[omnivore]]s ([[human]]s, [[chimpanzee]]s, and [[orangutan]]s, but not [[gorilla]]s) apparently developed ways to cope with periods of vitamin C shortages. In these species, alterations in [[osteocalcin]] vitamin C-dependent hydroxylation appear to be responses to a "selective pressure to limit hydroxylation."<ref name="pmid15753298">{{cite journal |author=Nielsen-Marsh CM ''& al.'' |title=Osteocalcin protein sequences of Neanderthals and modern primates |journal=Proc. Natl. Acad. Sci. U.S.A. |volume=102 | pages=4409–13 |year=2005 |pmid=15753298}}</ref>
:*40 mg per day: United Kingdom - [[Food Standards Agency]] <ref name=" UKFSA"/>
:*45 mg per day: Recommended nutrient intake from the [[World Health Organization]] <ref>[http://whqlibdoc.who.int/publications/2004/9241546123_chap7.pdf Vitamin and mineral requirements in human nutrition, 2nd edition] World Health Organization and Food and Agriculture Organization, 2004 - Retrieved January 2007</ref>
:*60&ndash;95 mg per day, United States - [[Dietary Reference Intake]] (DRI), Recommended Daily Allowance (RDA) by the Food and Nutrition Board of the (US) [[United States National Academy of Sciences|National Academy of Sciences]]. 2004. <ref name="US RDA "/>
The U.S. [[Dietary Reference Intake|Tolerable Upper Intake Level]] (UL) for a 25-year old male is 2000 mg/day. Vitamin C is recognized to be one of the least toxic substances known to medicine. <ref name="US RDA "/> Its [[LD50]] for rats is 11,900 mg kg<sup>-1</sup>. <ref>[http://ptcl.chem.ox.ac.uk/MSDS/AS/ascorbic_acid.html Safety data for ascorbic acid ] The Physical and Theoretical Chemistry Laboratory, Oxford University. Retrieved January 2007</ref> <ref>[http://www.inchem.org/documents/jecfa/jecmono/v05je20.htm Toxicological evaluation of some food additives including anticaking agents, antimicrobials, antioxidants, emulsifiers and thickening agents] ADDITIVES SERIES NO. 5, Ascorbic Acid And Its Potassium And Sodium Salts,  World Health Organization, Geneva, 1974 - Retrieved January 2007</ref>


=== Independent dose recommendations ===
=== Transport ===
Some researchers have calculated the amount needed for an adult human to achieve similar blood serum levels as vitamin C synthesising mammals as follows:
Vitamin C, being water soluble, does not cross lipid-rich membranes easily: it must follow specific paths through plasma membranes to enter and leave cells. It is thus important to understand the transport of vitamin C in the various cells of the body to comprehend its role in health and disease. Another molecule must also be taken into account: dehydroascorbic acid (DHAA; vitamin C which has undergone oxidation).  
:*400 mg per day &ndash; [[Linus Pauling Institute]] & US National Institutes of Health (NIH) Recommendation.
:*500 mg twice per day &ndash; Professor [[Roc Ordman]]'s recommendation in free radical research. <ref>[http://www.beloit.edu/~nutritio/vitCdose.htm Beloit College] The Scientific Basis Of The Vitamin C Dosage Of Nutrition Investigator by Professor [[Roc Ordman]]. Accessed Nov 2006</ref>
:*3000 mg per day or more during illness or pregnancy (up to 300g for some illnesses) &ndash; Vitamin C Foundation's recommendation. <ref>[http://[[www.vitamincfoundation.org/vitcrda.htm]] Vitamin C Foundation's RDA - </ref>
:*6000–12000 mg per day &ndash; Thomas Levy, Colorado Integrative Medical Centre recommendation.
:*6000–18000 mg per day &ndash; [[Linus Pauling]]'s own daily recommendation
:*from 3000 mg to 200,000 mg per day based on a protocol described by [[Robert Cathcart]]<ref name="Cathcart">Robert F. Cathcart III M.D., ''[http://www.orthomed.com/titrate.htm Vitamin C, Titrating To Bowel Tolerance, Anascorbemia, and Acute Induced Scurvey]'', Allergy, Environmental, and Orthomolecular Medicine</ref> known as a vitamin C flush wherin escalating doses of vitamin C are given until diarrhea develops, then choosing the highest dose that does not cause diarrhea (bowel tolerance threshold). High doses (thousands of milligrams) may result in [[diarrhea]], which is harmless if the dose is reduced immediately. Some researchers<ref name="Cathcart"/> claim the onset of diarrhea to be an indication of where the body’s true vitamin C requirement lies. Both Cathcart<ref name="Cathcart"/> and Cameron have demonstrated that very sick patients with cancer or influenza do not display any evidence of diarrhea at all until ascorbate intake reaches levels as high as 200 grams (½ pound).


=== High dose advocacy arguments ===
'''[[Active transport]]''' requires energy. Two transporters with extreme specificity for vitamin C, sodium-dependent vitamin C transporters 1 and 2 (SVCT1 and SVCT2) have been characterized. Recently, the sodium dependence of SVCT2 has been questioned. It appears that at least this transporter subtype is [[calcium]]/[[magnesium]] dependent.<ref name="pmid17012227">{{cite journal |author=Godoy A ''et al.'' |title=Mechanistic insights and functional determinants of the transport cycle of the ascorbic acid transporter SVCT2. Activation by sodium and absolute dependence on bivalent cations |journal=J Biol Chem |volume=282  |pages=615–24 |year=2007 |pmid=17012227 |doi=10.1074/jbc.M608300200}}</ref> Intracellular and extracellular concentrations of both divalent ions thus condition the transport of vitamin C through these transporters. The presence of sodium at a certain threshold makes SVCT2 more efficient: vitamin C and sodium work cooperatively to achieve a high rate of transport of both molecules. The SVCTs have limited capacities, as they tend to decrease in number the more vitamin C is accumulated in cells, and with increasing concentrations of the vitamin in circulation.<ref name="pmid16011461">{{cite journal |author=Wilson JX |title=Regulation of vitamin C transport |journal=Annu Rev Nutr |volume=25  |pages=105–25 |year=2005 |pmid=16011461 |doi=10.1146/annurev.nutr.25.050304.092647 |issn=}}</ref> SVCT1 is mostly found in the liver and the kidneys (worthy of note, these are the two sites for vitamin C synthesis in the animal kingdom); SVCT2 dominates in the brain, skeletal muscles, and the spleen.


There is a strong advocacy movement for large doses of vitamin C (see [[#Advocacy arguments|Advocacy arguments]] below), although not all purported benefits are supported by the medical establishment.  Many pro-vitamin C organizations promote usage levels well beyond the current [[Dietary Reference Intake]] (DRI).
A lesser known, but important, mode of transport of vitamin C is '''[[exocytosis]]'''. In this process, vesicles  filled with vitamin C are secreted from cells, allowing vitamin C to influence neighboring cells. This secretion appears to be coordinated with the secretion of [[biologically active polypeptides]] from various glands, notably the [[pituitary gland]]; the metabolism of those polypeptides requires vitamin C as a cofactor (peptidyl-glycine α-amidating mono-oxygenase, vitamin C-requiring).<ref name="pmid3458183">{{cite journal |author=von Zastrow M ''et al.''  |title=Exocrine secretion granules contain peptide amidation activity |journal=Proc Natl Acad Sci USA |volume=83 |pages=3297–301 |year=1986 |pmid=3458183 |doi=}}</ref>


There exists an extensive and growing literature critical of governmental agency dose recommendations.
'''[[Facilitated diffusion]]''' is the process whereby molecules move from a compartment where there is more of the molecule to a compartment where there is less of it. Facilitated diffusion lets DHAA (but not vitamin C) enter cells, and lets vitamin C (but not DHAA) leave cells. The latter process is less understood than the former, but is essential in cells which deliver and keep vitamin C in the blood, i.e. the enterocytes (intestinal cells) and renal tubular cells (kidney cells). Once DHAA has entered a cell, it is recycled back to vitamin C.
<ref name="PR Newswire"/>
 
<ref> [http://www.seanet.com/~alexs/ascorbate/198x/forman-r-med_hypotheses-1981-v7-n8-p1009.htm Seanet] ''Medical Resistance To Innovation'', Robert Forman, The University of Toledo. Vitamin C Accessed November 2006</ref>
The fact that glucose transporters also transport the glucose derivative DHAA explains a paradoxical finding made my James Lind in his ''Treatise of the Scurvy'':
<ref name="VitC Foundation"> [http://www.vitamincfoundation.org/ Vitamin C Foundation] A consortium of physicians and other practitioners, healthcare activists, and other concerned Individuals, as well as of health and nutrition oriented organizations and nutrient suppliers—all of whom are dedicated to promoting the extraordinary therapeutic value of vitamin C. </ref>
:''(Victims of scurvy had) ravaged bodies (but) what was very surprising, the brains of those poor creatures were always sound and entire (...)''<ref>Stewart CP,  Guthrie D (1953) ''Lind's Treatise on Scurvy.'' Edinburgh University Press, Edinburgh. 227-231.
<ref> [http://www.orthomed.com/ Orthomed] ORTHOMOLECULAR MEDICINE
VITAMIN C by Robert F. Cathcart, M.D. Accessed November 2006</ref>
<ref> [http://lpi.oregonstate.edu/ Linus Pauling Institute] At Oregan State University Accessed November 2006</ref>
<ref> [http://www.megac.org/ Megac.org] Campaigns for Oral and/or Intravenous use of ascorbate (vitamin C) to improve health AND to treat a variety of infections, diseases and other medical conditions. Accessed November 2006</ref>
<ref> [http://www.cforyourself.com/ cforyourself.com] Educational site which aims to increase the knowledge of visitors concerning vitamin C and to promote dietary supplementation, both for general good health and for the treatment of disease.
</ref>
</ref>
<ref> [http://www.orthomed.org/ Orthomolecular Medicine Online] Thie International Society for Orthomolecular Medicine. The purpose of the Society is to further the advancement of orthomolecular medicine throughout the world, to raise awareness of this rapidly growing and cost effective practice of health care, and to unite the many and various groups already operating in this field.</ref>
It thus appears that the glucose transporters, by transporting oxidized vitamin C, allow organs to quickly store vitamin C at times of increased oxidative stress.<ref name="pmid-9389750">{{cite journal |author=Agus DB ''et al.'' |title=Vitamin C crosses the blood-brain barrier in the oxidized form through the glucose transporters |journal=J Clin Invest |volume=100 |pages=2842–8 |year=1997 |pmid=9389750 |doi= |issn=}}</ref> Once dehydroascorbic acid has crossed the blood-brain barrier and is in the brain, it is recycled (reduced) back to vitamin C, and retained in this compartment.<ref name="pmid-9389750"/>  
Conversely, conditions associated with low insulin, insulin resistance, high glucose and/or inflammation (diabetes, type 1 and 2, trauma, sepsis) impact on DHAA uptake and intracellular vitamin C status (also see Therapeutic uses).
[[Adipocytes]], [[astrocytes]], [[endothelial cells]], [[erythrocytes]], [[granulosa cells]], [[hepatocytes]], [[neutrophils]], [[osteoblasts]] and [[smooth muscle]] cells accumulate DHAA for the accumulation of vitamin C.


In summary the [[biological halflife]] for vitamin C is quite short, about 30 minutes in blood plasma, a fact which high dose advocates say NIH and IM researchers have failed to recognize. NIH researchers established the current RDA based upon tests conducted 12 hours (24 half lives) after consumption. "To be blunt," says Hickey, "the NIH gave a dose of vitamin C, waited until it had been excreted, and then measured blood levels." <ref> [http://www.newmediaexplorer.org/chris/2004/07/09/the_vitamin_c_fanatics_were_right_all_along.htm Newmedia explorer] The Vitamin C Fanatics Were Right All Along - Accessed Nov 2006 </ref>
'''(in progress:)''' The pro-inflammatory shift seen in vitamin C deficient species (see The Shionogi rat) may enhance the compensatory transport and recycling of vitamin C, as shown in a mouse model of sublethal endotoxin exposure (in which GULO, the final step in vitamin C biosynthesis, was inhibited).<ref name="pmid16177205">{{cite journal |author=Kuo SM ''et al.'' |title=Endotoxin increases ascorbate recycling and concentration in mouse liver |journal=J Nutr |volume=135 |pages=2411–6 |year=2005 |pmid=16177205 }}</ref>
NIH don't take into account individual differences such as age, weight, etc.  For example, heavier individuals generally need more vitamin C.
They point out the figures represent the amount needed to prevent the acute form of deficiency disease, while subclinical levels of the disease are not even acknowledged.
That the amount needed to prevent other diseases is not considered.
The established RDA is one that will prevent the onset of [[scurvy]] and is not necessarily the most optimal dosage.


=== Testing for ascorbate levels in the body ===
=== Distribution ===
Simple tests exist which measure levels of ascorbate ion in [[urine]], [[serum]] or [[blood plasma]]. However, these tests do not accurately reflect actual tissue ascorbate levels. Reverse phase high performance [[liquid chromatography]] (HPLC) is used for determining vitamin C levels within [[lymphocyte]]s and other tissue.
'''In the blood'''
It has been observed that while serum or blood plasma levels follow the [[circadian rhythm]] or short term dietary changes, those within tissues themselves are more stable and give a better determination of ascorbate availability within the organism. However, very few hospital laboratories are adequately equipped and trained to carry out such detailed analyses, and require samples to be analyzed in specialized laboratories.
<ref>{{cite journal | author = Emadi-Konjin P, Verjee Z, Levin A, Adeli K | title = Measurement of intracellular vitamin C levels in human lymphocytes by reverse phase high performance liquid chromatography (HPLC). | journal = Clin Biochem | volume = 38 | issue = 5 | pages = 450-6 | year = 2005 | id = PMID 15820776}}  </ref>
<ref>{{cite journal | author= Yamada H, Yamada K, Waki M, Umegaki K.
| title= Lymphocyte and Plasma Vitamin C Levels in Type 2 Diabetic Patients With and Without Diabetes Complications | journal= Diabetes Care” | year=2004 | volume=27 | issue = | pages=2491–2 | url= http://care.diabetesjournals.org/cgi/reprint/27/10/2491.pdf
| format=PDF}} {{cquote|the plasma concentration of vitamin C is considered to be strongly correlated with transient consumption of foods. The measurement of lymphocyte vitamin C might be expected to be a more reliable antioxidant biomarker than plasma vitamin C level. In this report, we demonstrated that the lymphocyte vitamin C level is significantly lower in type 2 diabetic patients, but we could not observe such an association in plasma vitamin C levels. In diabetes, therefore, the measurement of lymphocyte vitamin C might be expected to be a more reliable antioxidant biomarker than plasma vitamin C level.}} </ref>


=== Therapeutic applications and doses ===
Vitamin C concentrations in the blood are usually between 10 and 160 micromol/L,<ref name="pmid11984580">{{cite journal |author=Hediger MA |title=New view at C |journal=Nat Med |volume=8 |pages=445–6 |year=2002 |pmid=11984580 |url=http://www.nature.com/nm/journal/v8/n5/full/nm0502-445.html}}</ref> and seldom exceed 80 micromol/L after most meals<ref name="pmid17616774">{{cite journal |author=Padayatty SJ ''et al.'' |title=Human adrenal glands secrete vitamin C in response to adrenocorticotrophic hormone |journal=Am J Clin Nutr |volume=86 |pages=145–9 |year=2007 |pmid=17616774}}</ref> Oral supplementation can raise levels to 220 micromol/L, while intravenous infusion  can raise concentrations to 13 400 micromol/L.<ref name="pmid8623000">{{cite journal |author=Levine M ''et al.'' |title=Vitamin C pharmacokinetics in healthy volunteers: evidence for a recommended dietary allowance |journal=Proc Natl Acad Sci USA |volume=93 |pages=3704–9 |year=1996 |pmid=8623000 |doi=}}</ref>
Vitamin C is needed in the diet to prevent [[scurvy]]. However, from the time it became available in pure form in the [[1930s]], some practitioners experimented with vitamin C as a treatment for diseases other than scurvy. <ref name="UMM"/>


==== Colds ====
Leukocytes (white blood cells) use oxidants to destroy microbes.<ref name="pmid1562664">{{cite journal |author=Park MK ''et al.'' |title=Oxygen tensions and infections: modulation of microbial growth, activity of antimicrobial agents, and immunologic responses |journal=Clin Infect Dis |volume=14  |pages=720–40 |year=1992 |pmid=1562664 |doi= |issn=}}</ref>; they can tolerate high levels of oxidative stress and have transport systems that allow large amounts of vitamin C to be mobilized quickly (concentrations of the vitamin can reach 50 times those found in the blood).<ref name="pmid2681206">{{cite journal |author=Washko P ''et al.''  |title=Ascorbic acid transport and accumulation in human neutrophils |journal=J Biol Chem |volume=264  |pages=18996–9002 |year=1989 |pmid=2681206 |doi= |issn=}}</ref> Although lymphocytes are used to evaluate the body's need for vitamin C, they are not especially representative of the needs of organs and tissues.
A recent 55-study review <ref>[http://medicine.plosjournals.org/perlserv/?request=get-document&doi=10.1371/journal.pmed.0020168 Douglas RM, Hemilä H (2005) Vitamin C for Preventing and Treating the Common Cold]. PLoS Med 2(6): e168</ref> found little positive effect of a vitamin C intake on common cold at low doses, but indication of [[prophylaxis]] benefits at higher doses especially where the subjects were in stressful situations.  
 
'''In urine and feces'''
 
Determining the concentrations of vitamin C in urine and feces allows for a basic evaluation of the amounts that were absorbed by the body. However, vitamin C-synthecizing species continually excrete vitamin C in their urine. The mere urinary excretion of vitamin is a normal part of its metabolism and not a sign of excess consumption, and the relationship between the intake of the vitamin and its excretion varies widely.
 
'''In organs and tissues'''
 
Some glands, organs and tissues contain 100 times more vitamin C than the blood, including the adrenal glands, pituitary gland, thymus, retina, corpus luteum, and various types of neurons.<ref name="pmid11984580"/>
 
High concentrations of vitamin C are required for the adequate synthesis of [[catecholamines]] and [[steroids]] in the [[adrenal gland]] ([[adrenal cortex]] and [[adrenal medulla]]).<ref name="pmid15666839">{{cite journal |author=Patak P''et al.'' |title=Vitamin C is an important cofactor for both adrenal cortex and adrenal medulla |journal=Endocr Res |volume=30 |pages=871–5 |year=2004 |pmid=15666839 |doi=}}</ref> In response to stress, the adrenals secrete vitamin C locally, creating high concentrations that act at the adrenal gland in a [[paracrine]] manner.<ref name="pmid17616774"/>
 
In the ovaries, the [[corpus luteum]] produces the steroid hormone [[progesterone]], which is particularly important for maintaining pregnancy. Different enzymes involved in progesterone synthesis are enhanced by vitamin C at concentrations of 100 micromol/L (in the higher nutritional range).<ref name="pmid17901237">{{cite journal |author=Wu X ''et al.'' |title=Ascorbic acid transported by sodium-dependent vitamin C transporter 2 stimulates steroidogenesis in human choriocarcinoma cells |journal=Endocrinology |volume= |pages= |year=2007 |pmid=17901237 |doi=10.1210/en.2007-0262 |issn=}}</ref> Also see Therapeutic uses - Pregnancy. Conversely, prostaglandin PGF2 alpha, which is important for the initiation of parturition at the end of a normal pregnancy, increases the secretion of vitamin C by the corpus luteum.<ref name="pmid9640263">{{cite journal |author=Petroff BK ''et al.''  |title=Depletion of vitamin C from pig corpora lutea by prostaglandin F2 alpha-induced secretion of the vitamin |journal=J Reprod Fertil|volume=112 |pages=243–7 |year=1998 |pmid=9640263 |doi= |issn=}}</ref>
 
The brain contains on average 10 times more vitamin C than the blood, and species that are exceptionally tolerant to oxygen deprivation concentrate even higher amounts of vitamin C.<ref name="pmid12458180">{{cite journal |author=Rice ME ''et al.''  |title=Brain antioxidant regulation in mammals and anoxia-tolerant reptiles: balanced for neuroprotection and neuromodulation |journal=Comp Biochem Physiol C  |volume=133 |pages=515–25 |year=2002 |pmid=12458180 |doi= |issn=}}</ref> In animal models of diabetes, where blood glucose levels are abnormally high, a drastic inhibition of vitamin C transport to the brain (through its oxidized form) is observed.<ref name="pmid17015969"/>
 
The retina, like the brain, accumulates high concentrations of vitamin C using GLUT1 glucose transporters,  on the [[blood-retinal barrier]]. An experimental model of diabetes showed vitamin C concentrations in the retina to be drastically reduced by the high concentrations of glucose seen in diabetes, as a result of the competition of glucose with dehydroascorbic acid for entry in the retina (in this study, the transport of DHA was decreased by two thirds).<ref name="pmid17015969">{{cite journal |author=Minamizono A ''et al.''|title=Inhibition of dehydroascorbic acid transport across the rat blood-retinal and -brain barriers in experimental diabetes |journal=Biol Pharm Bull|volume=29 |pages=2148–50 |year=2006 |pmid=17015969 |doi= |issn=}}</ref>
 
=== Food sources===
The richest natural sources are fruits and vegetables, and of those, the [[camu camu]] fruit , the [[billygoat plum]] and the [[Indian gooseberry]] or [[amla]] (''Emblica officinalis'') contain the highest concentration of the vitamin (about 30 times more than oranges). Vitamin C is the most widely taken [[nutritional supplement]].


At least 29 controlled clinical trials (many [[double-blind]] and [[placebo]]-controlled) involving a total of over 11,000 participants have been conducted into vitamin C and the [[Common cold]].  These trials were reviewed in the 1990s<ref name="Hemilia>H. Hemilia, Does Vitamin C Alleviate the Symptoms of the Common Cold?, Scand J Infect Dis: 26:1 (1996)</ref><ref name="Hemilia>H. Hemilia, Vitamin C Supplementation and Common Cold Symptoms: Problems with Inaccurate Reviews, Nutrition, Vol. 12, No. 11, p. 804 (1996)</ref> and again more recently.<ref>[http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=15495002&query_hl=8&itool=pubmed_docsum Douglas RM, et al, "Vitamin C for preventing and treating the common cold,"
'''Plants'''
National Centre for Epidemiology and Population Health, Australian National University, 2000, URL accessed Jan 25, 2006]</ref> The trials show that vitamin C reduces the duration and severity of colds but not the frequency. The data indicate that there is a normal dose-response relationship. Vitamin C is more effective the higher the dose. <ref>[http://www.supplementwatch.com/suplib/supplement.asp?DocId=1278&templateId=100 Supplementwatch.com] Vitamin C -  Scientific Support  Section - "At least 3 controlled studies have shown an 80% reduction in the incidence of pneumonia among vitamin C users. In one large study (over 700 students), vitamin C (1000 mg per hour for the first 6 hours followed by 3000 mg per day), reduced cold and flu symptoms by 85%." Accessed February 2007.</ref>
The vast majority of the trials were limited to doses below 1 g/day. As doses rise, it becomes increasingly difficult to keep the trials double blind because of the obvious gastro-intestinal side effects of heavy doses of Vitamin C. So, the most effective trials at doses between 2 and 10 g/day are generally met with skepticism. 


The controlled trials and clinical experience prove that vitamin C in doses ranging from 0.1 to 2.0 g/day have a relatively small effect.  The duration of colds was reduced by 7% for adults and 15% for children. The studies provide ample justification for businesses to encourage their employees to take 1 to 2 g/day during the cold season to improve workplace productivity and reduce sick days. The clinical reports provide the strongest possible evidence that vitamin C at higher doses is significantly more effective. However, the effectiveness typically comes at the price of gastro-intestinal side effects. It is easy for physicians to minimize these side effects since they cause no lasting harm. Adult patients, however, have proven reluctant to subject themselves to gas and cramping to deliver an unknown benefit (the duration and severity of colds is highly variable so the patient never knows what he/she is warding off). It is well worth the effort of identifying the small subset of individuals who can benefit from high daily doses (>10 g/day) of vitamin C without side effects and training them to regularly take 5 g/day during cold season and to increase the dose at the onset of a cold.
There is an enormous difference in vitamin C content between cultivated fruits and fruits found in the wild, especially those that Human's ancestors consumed when they got rid of endogenous capacity. Amongst fruits commonly found on the market, citrus fruits and small fruits (such as strawberries or blueberries) are relatively good sources of vitamin C. The amount of vitamin C in foods of plant origin depends on the variety of the plant, the soil condition and the climate in which it grew, the length of time since it was picked and the storage conditions, and the method of preparation. Cooking in particular is often said to destroy vitamin C&nbsp;&mdash; but see Food preparation, below.


==== Polio ====
With the gradual recognition that vitamin C prevents more than the sailor's disease, and in response to the general trends in consumer demands, the biotechnological industry has realized the commercial possibilities of new, patented, plant species with an enhanced ability to make vitamin C.<ref name="pmid12624189">{{cite journal |author=Chen Z ''et al.''|title=Increasing vitamin C content of plants through enhanced ascorbate recycling |journal=Proc Natl Acad Sci USA |volume=100 |issue=6 |pages=3525–30 |year=2003 |pmid=12624189 |doi=10.1073/pnas.0635176100}}</ref>
Most notable was [[Fred R. Klenner]], a doctor in general practice in [[Reidsville, North Carolina]]. He utilized both oral and intravenous vitamin C to treat a wide range of infections and poisons. He published a paper in 1949 that described how he had seen [[poliomyelitis]] yield to vitamin C in sufficiently large doses.[http://www.vitamincfoundation.org/expert.htm#KLENNER] No controlled clinical trials have been conducted to confirm effectiveness.[http://www.seanet.com/~alexs/ascorbate/198x/smith-lh-clinical_guide_1988.htm]


==== Heart disease ====
Vitamin C is the main component of the three ingredients in [[Linus Pauling]]'s patented preventive cure for Lp(a)<ref>Rath MW, Pauling LC. US Patent 5,278,189. [http://patimg2.uspto.gov/.piw?PageNum=1&docid=US005278189&IDKey=863A8B6F2A5F&HomeUrl=http%3A%2F%2Fpatft.uspto.gov%2Fnetacgi%2Fnph-Parser%3FSect1%3DPTO1%2526Sect2%3DHITOFF%2526d%3DPALL%2526p%3D1%2526u%3D%25252Fnetahtml%25252FPTO%25252Fsrchnum.htm%2526r%3D1%2526f%3DG%2526l%3D50%2526s1%3D5278189.PN.%2526OS%3DPN%2F5278189%2526RS%3DPN%2F5278189  Prevention and treatment of occlusive cardiovascular disease with ascorbate and substances that inhibit the binding of lipoprotein(A)]. USPTO. 11 Jan 1994.</ref> related heart disease, the other two being the amino acid [[lysine]] and [[nicotinic acid]] (a form of Vitamin B3).  Lp(a) as an atherosclerotic, evolutionary substitute for ascorbate<ref>
Rath M, Linus P. [http://www.pnas.org/cgi/reprint/87/16/6204 Hypothesis: Lipoprotein (a) is a surrogate for ascorbate]. Proc Natl Acad Sci USA. Vol 87, 6204–6207, Aug 1990.</ref> is still discussed as a hypothesis by mainstream medical science<ref>Kniffin CL, McKusick VA, Brennan P. [http://www.ncbi.nlm.nih.gov/entrez/dispomim.cgi?id=152200 APOLIPOPROTEIN(a); LPA].  OMIMTM - Online Mendelian Inheritance in Man, Johns Hopkins University. 1986–2006</ref> and the Rath-Pauling related protocols<ref>[http://www.vrp.com/art/798.asp?c=1162763143031&k=/det/2100.asp&m=/includes/vrp.css&o=0&p=no&s=0] </ref> have not been rigorously tested and evaluated as conventional medical treatment by the FDA.


==== Viral diseases, and poisons ====
'''Animals'''
[[Orthomolecular medicine]] and a minority of scientific opinion sees vitamin C as being a low cost and safe way to treat viral disease and to deal with a wide range of poisons.


Vitamin C has a growing reputation for being useful in the treatment of [[common cold|cold]]s and [[flu]], owing to its recommendation by prominent biochemist [[Linus Pauling]]. In the years since Pauling's popular books about vitamin C, general agreement by medical authorities about larger than RDA amounts of vitamin C in health and medicine has remained elusive.  Ascorbate usage in studies of up to several grams per day, however, have been associated with decreased cold duration and severity of symptoms, possibly as a result of an [[antihistamine]] effect [http://lpi.oregonstate.edu/infocenter/vitamins/vitaminC/].  The highest dose treatments, published clinical results of specific orthomolecular therapy regimes pioneered by Drs. Klenner (repeated IV treatments, 400–700+ (mg/kg)/day [http://www.seanet.com/~alexs/ascorbate/197x/klenner-fr-j_int_assn_prev_med-1974-v1-n1-p45.htm][http://www.seanet.com/~alexs/ascorbate/197x/klenner-fr-j_appl_nutr-1971-v23-n3&4-p61.htm#appendix]) and Cathcart (oral use to bowel
Some cuts of meat are sources of vitamin C for humans. The muscle and fat that make up the modern western diet are, however, poor sources. As with fruit and vegetables, cooking degrades the vitamin C content.
tolerance,<ref name="Cathcart"/> up to ~150 grams ascorbate per day for flu), have remained experimentally unaddressed by conventional medical authorities for decades.


The Vitamin C Foundation recommends an initial usage of up to 8 grams of vitamin C every 20–30 minutes [http://www.vitamincfoundation.org/surefire.htm] in order to show an effect on the symptoms of a cold infection that is in progress. Most of the studies showing little or no effect employ doses of ascorbate such as 100 mg to 500 mg per day, considered "small" by vitamin C advocates. Equally importantly, the plasma half life of high dose ascorbate is approximately 30 minutes, which implies that most high dose studies have been methodologically defective and would be expected to show a minimum benefit. Clinical studies of divided dose supplementation, predicted on pharmacological grounds to be effective, have only rarely been reported in the literature. Essentially all the claims for high dose vitamin C remain to be scientifically refuted. The clinical effectiveness of large and frequent doses of vitamin C is an open scientific question.
Vitamin C is present in [[Breastfeeding#Benefits|mother's milk]] and in less amounts in [[Milk#Nutritional benefits|raw cow's milk]] (but pasteurized milk contains only trace amounts of the vitamin). <ref>[http://www.saanendoah.com/compare.html Comparing Milk: Human, Cow, Goat & Commercial Infant Formula] Compiled and referenced by Associate Professor Stephanie Clark, Ph.D Assistant Professor, Dept. of Food Science and Human Nutrition, Washington State University.
Accessed January 2007.</ref>


In 2002 a [[meta-study]] into all the published research on effectiveness of ascorbic acid in the treatment of infectious disease and toxins was conducted, by Thomas Levy, Medical Director of the Colorado Integrative Medical Centre in Denver. He claimed that evidence exists for its therapeutic role in a wide range of viral infections and for the treatment of snake bites.
'''Food preparation'''


==== Lead poisoning ====
Recent observations suggest that the impact of temperature and cooking on vitamin C may have been overestimated, since it decomposes around 190–192&deg;C, well above the boiling point of water:
There is also evidence that vitamin C is useful in preventing [[lead poisoning]], possibly helping to [[Chelation|chelate]] the toxic heavy metal from the body. [http://www.seanet.com/~alexs/ascorbate/193x/holmes-hn-etal_j_lab_clin_med-1939-v23-n11-p1119.html]
* Since it is water soluble, vitamin C will strongly leach into the cooking water, but this doesn't necessarily mean the vitamin is destroyed.
* Contrary to what is commonly assumed, it can take much longer than 2-3 min to destroy vitamin C at boiling point.
* Cooking doesn't leach vitamin C in all vegetables at the same rate; for instance, it has been suggested that the vitamin is not destroyed when boiling [[broccoli]].<ref name=Combs>Combs GF. The Vitamins, Fundamental Aspects in Nutrition and Health. 2nd ed. San Diego, CA: Academic Press, 2001:245–272</ref> This may be a result of vitamin C leaching into the cooking water at a slower rate from this vegetable.


==== Cancer ====
Consistent with the interaction of vitamin C with copper metals in physiology, pots made with alloys of this metal will destroy the vitamin.<ref>[http://ptcl.chem.ox.ac.uk/MSDS/AS/ascorbic_acid.html Safety data]  University of Oxford Physical & Theoretical Chemistry Lab. Safety home page. </ref>
Two placebo-controlled trials <ref>Creagan ET, Moertel CG, O'Fallon JR, et al. Failure of high-dose vitamin C (ascorbic acid) therapy to benefit patients with advanced cancer. A controlled trial. N Engl J Med 1979;301:687–90</ref> <ref>Moertel CG, Fleming TR, Creagan ET, et al. High-dose vitamin C versus placebo in the treatment of patients with advanced cancer who have had no prior chemotherapy. A randomized double-blind comparison. N Engl J Med 1985;312:137–41</ref> could not show any positive effect of vitamin C in cancer patients.


In 2005 [[in vitro]] (test tube) research by the [[National Institutes of Health]] indicated that vitamin C administered in pharmacological concentrations (i.e. [[intravenous]]) was preferentially toxic to several strains of [[cancer]] cells.  The authors noted: "These findings give plausibility to intravenous ascorbic acid in cancer treatment, and have unexpected implications for treatment of infections where H<sub>2</sub>O<sub>2</sub> may be beneficial." This research appeared to support Linus Pauling's claims that vitamin C can be used to fight cancer.<ref> [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=16157892&dopt=Abstract  Qi Chen and others.  Pharmacologic ascorbic acid concentrations selectively kill cancer cells: Action as a pro-drug to deliver hydrogen peroxide to tissues. Proceedings of the National Academy of Sciences of the United States of America (PNAS) | September 20, 2005 | vol. 102 | no. 38 | 13604–13609] </ref>
Fresh-cut fruit may not lose much of its nutrients when stored in the refrigerator for a few days.<ref>[http://www.webmd.com/content/article/123/115022.htm WebMD Medical News] ''Fresh-Cut Fruit May Keep Its Vitamins'', Miranda Hitti</ref>


In 2006 the Canadian Medical Association Journal published [[in vivo]] research that demonstrated that intravenous vitamin C can subdue advanced-stage cancer. <ref>[http://www.cmaj.ca/cgi/content/full/174/7/937  Sebastian J. Padayatty and others. Vitamin C documented to quell advanced-stage cancer in three cases involving bladder, lung, kidney and lymphoma tumors.  Canadian Medical Assn Journal 174: 937–42, 2006]  <br> The study underwent rigorous case reporting standards as outlined by the U.S. National Cancer Institute.</ref>
'''Supplements'''


==== Cataracts ====
Vitamin C is the most widely taken dietary supplement.<ref> [http://www.thedietchannel.com/Vitamin-C.htm The Diet Channel] Vitamin C might be the most widely known and most popular vitamin purchased as a supplement. </ref> It is available in many forms including caplets, tablets, capsules, drink mix packets, in multi-vitamin formulations, in multiple anti-oxidant formulations, as chemically pure crystalline powder, time release versions, and also including [[bioflavonoids]] such as quercetin, hesperidin and rutin. Tablet and capsule sizes range from 25 mg to 1500 mg. Vitamin C (ascorbic acid) crystals are typically available in bottles containing 300 g to 1 kg of powder (a teaspoon of vitamin C crystals equals 5,000 mg). Other forms of Vitamin C as [[sodium ascorbate]], [[magnesium ascorbate]], [[calcium ascorbate]], mixed mineral ascorbates (e.g. Na, K, Mg, Ca, Zn), and [[Ester-C]] are also available, though less popular.
It has been also suggested that vitamin C might prevent the formation of [[cataract]]s.<ref> Tessier, F., et al. Decrease in vitamin C concentrations in human lenses during cataract progression. Int. J. Vitamino Nutr Res 1998;68:309-15 </ref>


==== Autism ====
Vitamin C-enriched teas and infusions are increasingly appearing in markets. If boiling temperatures did indeed destroy vitamin C at the rate that had previously been suggested, using such products would be nonsensical. As note above, boiling is not as potently detrimental to the integrity of the vitamin C as was previously assumed.
A recent internet survey found that 30.8% of parents use vitamin C as a therapy for their child with autism (Green 2006). So far, however, only one study has shown that vitamin C can help treat behavioral problems associated with autism. While this small double-blind trial found that high doses of vitamin C had a significant positive effect on behavior in children with autism, it has not been replicated (Dolske 1993). The study used approximately 2 grams daily (divided into 2 or 3 doses) for a 40-pound child.


== Other effects ==
=== History===
=== Contraindications ===
{{main|History of vitamin C}}
A [[Contraindication]] is a condition which makes an individual more likely to be harmed by a dose of vitamin C than an average person.


* A primary concern is people with unusual or unaddressed iron overload conditions, including [[hemochromatosis]]. Vitamin C enhances iron absorption. If sufferers of iron overload conditions take gram sized doses of vitamin C, they may worsen the iron overload due to enhanced iron absorption.
Scurvy is a disease resulting from a deficiency of vitamin C that leads to spots on the skin, spongy gums, and bleeding from the mucous membranes. Those afflicted are pale, feel depressed, and are partially immobilized; in serious cases there can be open wounds and loss of teeth. Scurvy was once common among sailors, when at sea for longer than fresh fruit and vegetables could then be stored.  


* Inadequate [[Glucose-6-phosphate dehydrogenase]] enzyme (G6PD) levels, a genetic condition, may predispose some individuals to [[hemolytic anemia]] after intake of specific oxidizing substances present in some food and drugs. This includes repeated, very large intravenous or oral dosages of vitamin C. There is a test available for G6PD deficiency [http://brightspot.org/cresearch/intravenousc2.shtml]. High dose of [[Vitamin E]] has been proposed as a potential protective factor.
[[James Lind]] (1716-1794) was a Scottish doctor and a pioneer of naval hygiene. In 1747, while serving as surgeon on HMS Salisbury in the Channel Fleet, he carried out experiments to find a rational treatment for scurvy; he already knew of the benefits of lime juice; [[John Woodall]] (1556-1643) in his book ''The Surgeon's Mate'' had written of "the scurvy called in Latine Scorbutum" and noted that natural remedies included "the Lemmons, Limes, Tamarinds, Oranges, and other choices of good helps from the Indies....", but Lind did not know why these were effective or whether they were any more effective than other "remedies" of the time. He speculated that limes might be effective because of their acidity, and so in his experiment he treated two of the patients with vinegar. He chose 12 men from the ship, all suffering from scurvy, and divided them into pairs, giving each pair different additions to their basic diet - cider; seawater; a mixture of garlic, mustard and horseradish; vinegar, and oranges and lemons. Those fed citrus fruits experienced a remarkable recovery. By this test Lind had, in a carefully controlled manner, established the superiority of citrus fruits above all other 'remedies'.


=== Side-effects ===
Vitamin C was first isolated in 1928, and in 1932 it was shown to prevent [[scurvy]]. Both [[Charles Glen King]] at the [[University of Pittsburgh]] and [[Albert Szent-Györgyi]] (working with ex-[[Pittsburgh, Pennsylvania|Pittsburgh]] researcher [[Joseph Svirbely]]) came to discover what is now known as vitamin C around April of 1932. Although Szent-Györgyi was awarded the 1937 [[Nobel Prize in Medicine]], many feel King is as responsible for its development. <ref>[http://www.pitt.edu/history/1932.html University of Pittsburgh]"In recognition of this medical breakthrough, some scientists believe that King deserved a Nobel Prize." Accessed February 2007 </ref>
* Vitamin C causes [[diarrhea]] if taken in quantities beyond a certain limit, which varies by individual. Cathcart<ref name="Cathcart"/> has called this limit the [[Bowel tolerance|Bowel Tolerance Limit]] and observed that it is higher in people with serious illness than those in good health. It ranges from 5 to 25 grams per day in healthy individuals to 300 grams per day in the seriously ill people, such as those with [[AIDS]] and [[cancer]]. The diarrhea side-effect is harmless, though it can be inconvenient. The diarrhea will cease as soon as the dose is reduced.


* Large doses of vitamin C may cause acid indigestion, particularly when taken on an empty stomach.  This unpleasant but harmless side-effect can be avoided by taking the vitamin along with meals or by offsetting its acidity by taking an antacid such as baking soda or calcium carbonate.
== Recommended daily requirements ==


=== Effects of overdose ===
{|align="right" cellpadding="10" style="background-color:#FFFFCC; width:40%; border: 1px solid #aaa; margin:20px; font-size: 92%;"
Vitamin C exhibits remarkably low toxicity. For example, in a rat, the [[LD50]] (the dose that will kill 50% of a population) has been reported as 11900 mg/kg.<ref>{{cite web|url=http://physchem.ox.ac.uk/MSDS/AS/ascorbic_acid.html|title=Safety (MSDS) data for ascorbic acid}}</ref> For a 70 kg (155 pound) human, this means that 833,000 mg (0.833kg or 1.8 pounds) of vitamin C would need to be [[ingestion|ingested]] to stand a 50% chance of killing the person. However, vitamin C could not result in death when administered orally as large amounts of the vitamin cause [[diarrhea]] and are not absorbed.<ref>{{cite web|url=http://www.crnusa.org/safetypdfs/007CRNSafetyvitaminC.pdf|title=Council for Responsible Nutrition: Vitamin C safety}}</ref> An extremely large amount of vitamin C would need to be rapidly [[Injection (medicine)|injected]] by [[Intravenous therapy|IV]] to stand any chance of killing a person. [[Robert Cathcart]], MD, has used intravenous doses of vitamin C of 250 grams and reports that he has had no problems.<ref>{{cite web|url=http://orthomed.com/civprep.htm|title=Robert F. Cathcart III, M.D. }}</ref> The [[Council for Responsible Nutrition]] has set an Upper Level (UL) of 2 grams, based on transient diarrhea. Their publication on vitamin C safety notes that <ref>{{cite web|url=http://www.crnusa.org/safetypdfs/007CRNSafetyvitaminC.pdf|title=Council for Responsible Nutrition: Vitamin C safety}}</ref>
|''The Food and Nutrition Board at the Institute of Medicine advise that he best way to get the daily requirement of essential vitamins, including vitamin C, is to eat a balanced diet. A healthy diet should contain the following amounts of vitamin C:
{{cquote| ...very large doses of vitamin C have been taken daily over the course of many years, and only minor undesirable effects have been attributed with any certainty to the vitamin’s use[...] Clearly, vitamin C has a low order of toxicity.}}


=== Alleged harmful effects ===
Infants and Children
Reports of harmful effects of vitamin C tend to receive prominent media coverage. As such, these reports tend to generate much debate and more research into vitamin C. Some of the harmful effects described below were proven invalid in later studies, while other effects are still being analysized.


*In April 1998, the journal ''Nature'' reported alleged [[carcinogen]]ic and [[teratogenic]] effects of excessive doses of vitamin C. The effects were noted in test tube experiments and on only two of the 20 markers of free radical damage to DNA. These results have not been observed in living organisms.<ref> [http://lpi.oregonstate.edu/f-w01/cancer.html  Oregon State University - Vitamin C and cancer]</ref>
* 0 - 6 months: 40 mg/day 
* 7 - 12 months: 50 mg/day
* 1 - 3 years: 15 mg/day
* 4 - 8 years: 25 mg/day
* 9 - 13 years: 45 mg/day


*The authors of the "Nature" study later clarified their position, stating that their results "show a definite increase in 8-oxoadenine after supplementation with vitamin C. This lesion is at least ten times less mutagenic than 8-oxoguanine, and hence our study shows an overall profound protective effect of this vitamin".<ref> [Nature; Volume 395; Page 232; 17 September 1998] </ref>
Adolescents


*In April 2000, [[University of Southern California]] researchers reported a thickening of the arteries of the neck in persons taking high vitamin C doses. It was later pointed out by vitamin C advocates that this can be explained by vitamin C's collagen synthesising role leading to thicker and stronger artery walls. (ref.<ref name="fn_6">[http://www.vitamincfoundation.org/faq.htm FAQ] provided by The Vitamin C Foundation.</ref> para 10)
* Girls 14 - 18 years: 65 mg/day
* Boys 14 - 18 years: 75 mg/day


*In June 2004, [[Duke University]] researchers reported an increased susceptibility to osteo-arthritis in guinea pigs fed a diet high in vitamin C. However, a 2003 study at [[Umeå University]] in [[Sweden]], found that "the plasma levels of vitamin C, retinol and uric acid were inversely correlated to variables related to rheumatoid arthritis disease activity."
Adults


*A speculated increased risk of [[kidney stone]]s may be a side effect of taking vitamin C in larger than normal amounts (>1 g). The potential mechanism of action is through the [[metabolism]] of vitamin C ([[ascorbic acid]]) to [[dehydroascorbic acid]], which is then metabolized to [[oxalic acid]],<ref>Hokama S, Toma C, Jahana M, Iwanaga M, Morozumi M, Hatano T, Ogawa Y. [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=11156698&dopt=Abstract Ascorbate conversion to oxalate in alkaline milieu and Proteus mirabilis culture.] Mol Urol. 2000 Winter;4(4):321–8.</ref> a known constituent of kidney stones.  However, this oxalate issue is still controversial, with evidence being presented for<ref> [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=15987848&query_hl=11 Massey LK, Liebman M, Kynast-Gales SA.] Ascorbate increases human oxaluria and kidney stone risk, J Nutr. 2005 Jul;135(7):1673–7.</ref> and against<ref> [http://lpi.oregonstate.edu/f-w99/kidneystones.html Stephen Lawson]  What About Vitamin C and Kidney Stones? Linus Pauling Institute Administrative Officer] </ref> the possibility of this side effect. Vitamin C has long been advocated,<ref>McCormick, W J (1946) Lithogenesis and hypovitaminosis. Medical Record. 159:7, July, p 410–413) "I have observed that a cloudy urine, heavy with phosphates and epithelium, is generally associated with a low vitamin C status. . . and that as soon as corrective administration of the vitamin effects a normal ascorbic acid (vitamin C) level the crystalline and organic sediment disappears like magic from the urine. I have found that this change can usually be brought about in a matter of hours by large doses of the vitamin, 500 to 2,000 mg, oral or parenteral." (p. 411)</ref> and used,<ref>[http://www.orthomolecular.org/resources/omns/v02n02.shtml VITAMIN C HAS BEEN KNOWN TO FIGHT 30 MAJOR DISEASES ... FOR OVER 50 YEARS]. Orthomolecular Medicine News Service, March 15, 2006."...Robert F. Cathcart III, MD...: 'I estimate that I have put 25,000 patients on massive doses of vitamin C and none have developed kidney stones.'"</REF> by some less conventional physicians to prevent or alleviate some kinds of '''''non'''''-oxalate kidney stone formation.<ref>Schwille PO, Schmiedl A, Herrmann U, Wipplinger J. [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=9079746&dopt=Abstract Postprandial hyperinsulinaemia, insulin resistance and inappropriately high phosphaturia] are features of younger males with idiopathic calcium urolithiasis: attenuation by Ascorbic acid supplementation of a test meal. Urol Res 1997;25(1):49–58</ref><REF>S. Hickey, H. Roberts. [http://orthomolecular.org/resources/omns/v01n07.shtml VITAMIN C DOES NOT CAUSE KIDNEY STONES] Orthomolecular Medicine News Service, July 5, 2005.</ref> after addressing the oxalate issue.<ref>Klenner FR, [http://www.orthomed.com/klenner.htm Observations On the Dose and Administration of Ascorbic Acid When Employed Beyond the Range Of A Vitamin In Human Pathology] Journal of Applied Nutrition Vol. 23, No's 3 & 4, Winter 1971</ref><ref>Levy TE (September 2002) ''[http://www.doctoryourself.com/levy.html Vitamin C, Infectious Diseases, and Toxins: Curing the Incurable.]'' Livon Books. ISBN 1-4010-6963-0. </ref>  [[Vitamin B6]] may mitigate the general risk of oxalate stones by decreasing oxalate production.<ref>Curhan GC, Willett WC, Speizer FE, Stampfer MJ.[http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=10203369&query_hl=13 Intake of vitamins B6 and C and the risk of kidney stones in women.] J Am Soc Nephrol. 1999 Apr;10(4):840–5.</ref> Additionally, [[thiamine]] may inhibit oxalate formation. Furthermore, correcting any magnesium deficiency<ref>[http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=16100850&query_hl=28 NCBI] Magnesium therapy for nephrolithiasis. Massey L.2005 June
* Men age 19 and older: 90 mg/day
</ref> may decrease the risk of kidney stones by decreasing oxalate crystallization.  Increasing one's fluid intake also helps to prevent oxalate crystallization in the kidney. There is evidence that certain intestinal flora influence how much oxalate is destroyed and that their absence is a significant causal risk factor in oxalate stone formers.<ref>A Mikami et al, [http://www.blackwell-synergy.com/doi/abs/10.1046/j.1442-2042.2003.00634.x;jsessionid=b_EoSm_yAUR5RH3MWW?cookieSet=1&journalCode=iju  ''Association of absence of intestinal oxalate degrading bacteria with urinary calcium oxalate stone formation,''] International Journal of Urology,
* Women age 19 and older: 75 mg/day
Volume 10, pp 293–296, June 2003</ref> Patients with a predispostion to form oxalate stones or those on hemodialysis <ref>Sullivan JF, Eisenstein AB. [http://www.ajcn.org/cgi/content/abstract/23/10/1339 Ascorbic acid depletion in patients undergoing chronic hemodialysis.] Am. J. Clin. Nutr. 1970; 23:1339–1341</ref><ref> Deicher R, Horl WH.[http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=12771534&dopt=Abstract Vitamin C in chronic kidney disease and hemodialysis patients.] Kidney Blood Press Res. 2003;26(2):100–6.</ref> should avoid excess use of vitamin C.
* Women who are pregnant or breastfeeding and those who smoke need higher amounts.  
|}


* "Rebound scurvy" is a theoretical, never observed, condition that could occur when daily intake of vitamin C is rapidly reduced from a very large amount to a relatively low amount. Advocates suggest this is an exaggeration of the ''rebound effect'' which occurs because ascorbate-dependent enzyme reactions continue for 24–48 hours after intake is lowered, and use up vitamin C which is not being replenished. The effect is to lower one's serum vitamin C blood concentration to less than normal for a short amount of time. During this period of time there is a slight risk of cold or flu infection through reduced resistance. Within a couple of days the enzyme reactions shut down and blood serum returns to the normal level of someone not taking large supplements. This is not scurvy, which takes weeks of zero vitamin C consumption to produce symptoms. It is something people who take large vitamin C supplements need to be aware of in order to gradually reduce dosage rather than quit taking vitamin C suddenly. (ref.<ref name="fn_6" /> para 4) This is a theoretical risk for those taking supplements, e.g., if they find themselves severely ill, and in a hospital without the supplements, at a time when they need normal or better levels of vitamin C to fight the disease <small>(ref.<ref name="Cathcart"/> and search for "The major problem")</small>.  At this time, many doctors and hospital staff do not know much about nor administer megadosing of supplements, so that patients may have to rely on friends or relatives to bring them their supplements.
As emphasised above, the optimum daily dose of vitamin C has been debated for decades. There was an upward trend in the recommendations issued by public health advisory boards and a growing tendency to distinguish between vitamin C as the anti-scorbutic ''vitamin'' and vitamin C as a ''nutrient'' required to prevent or delay a range of diseases unrelated to scurvy. Most scientists now agree that scurvy is not a proper framework to study the role of this molecule in health, but the implications of the 10 to 20-fold decrease in ascorbate intake during evolution are still under scrutiny, 60 years after its discovery.


*Some writers<ref>[http://www.acu-cell.com/vitc.html acu-cell]</ref> have identified a theoretical risk of poor [[copper]] absorption from high doses of vitamin C, although little experimental evidence supports this. However, [[ceruloplasmin]] levels seem specifically lowered by high vitamin C intake. In one study, 600 milligrams of vitamin C daily did not decrease copper absorption or overall body copper status in young men, but led to lower [[ceruloplasmin]] levels similar to those caused by copper deficiency.<ref>[http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=3694287&query_hl=11 NCBI]</ref> In another, ceruloplasmin levels were significantly reduced.<ref>[http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=6837490&dopt=Abstract NCBI]</ref>
''Also see [[evolutionary medicine]] and [[evolutionary biology]]''


*There are stories circulating among some folk remedy proponents that doses of around 12 grams per day of vitamin C can induce an abortion in women under 4 weeks of pregnancy.<ref> [http://www.sisterzeus.com/Hsp1shlp.htm Home Abortion Remedy - Vitamin C, 8 March 2006]
Different health advisory bodies offer different advice regarding the daily requirement for vitamin C, and the USA and Canada recommend about twice the amount that the World Health Organization (WHO)recommends.  
</ref> This is not supported by scientific research however.<ref> [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=988001&dopt=Abstract ''Vitamins C and E in spontaneous abortion''] Int J Vitam Nutr Res. 1976;46(3):291–6.</ref>


* Recent studies into the use of a combination of [[Vitamin E]] ("natural" ''source isomer moiety, d-alpha tocopheryl'' ester) and vitamin C (unspecified ascorbate) in preventing oxidative stress leading to [[pre-eclampsia]] have failed to show ''significant'' (p=0.05) positive benefit at the dosage tested, <ref name="NEJM2006-Rumbold">{{cite journal | author=Rumbold A, Crowther C, Haslam R, Dekker G, Robinson J | title=Vitamins C and E and the risks of preeclampsia and perinatal complications. | journal=N Engl J Med | volume=354 | issue=17 | pages=1796-806 | year=2006|id=PMID 16641396}}</ref><!--
The Linus Pauling Institute recommends more than four times the amount that the USA and Canada recommend, or ten times what the WHO recommends. However, after the death of Pauling, the Linus Pauling Institute came to diverge from Linus Pauling himself, who recommended doses in the same range as what other primates consume in the wild (also see [http://en.citizendium.org/wiki/Vitamin_C#Biosynthesis Biosynthesis], above).
--> Drs. Padayatty and Levine with NIH in a "Letter to the Editor" stated that the studies and another "Letter to the Editor" ''overlooked a key reason for the lack of vitamin C on the prevention of preeclampsia. Because plasma ascorbate concentrations were not reported, we estimated them from known data, the placebo and treatment groups in the study probably had similar plasma and tissue ascorbate concentrations. Doses of 1 g per day have little effect on plasma or intracellular ascorbate concentrations.''<!--
--><ref name="Padayatta”>{{cite journal | author= Padayatty SJ, Levine M. |  title=Vitamin C and E and the Prevention of Preeclampsia&nbsp;&mdash; Letter | journal=NEJM | volume=355 | issue=10 | pages=1065–1066 | url=http://www.health.adelaide.edu.au/og/research/ACTS%20Published%20letter1065.pdf | year=2006}}</ref><!--
--> In another study the same dosage did decrease average gestational time resulting in a higher incidence of [[Birth weight|low birthweight]] babies in one study.<!--
  --><ref name="Lancet2006-Poston">{{cite journal | author=Poston L, Briley A, Seed P, Kelly F, Shennan A | title=Vitamin C and vitamin E in pregnant women at risk for pre-eclampsia (VIP trial): randomised placebo-controlled trial. | journal=Lancet | volume=367 | issue=9517 | pages=1145–54 | year=2006 | id=PMID 16616557}}</ref> Several other studies have been more favorable but large studies into antioxidants for pre-eclampsia are continuing.<ref>Rumbold A, Duley L, Crowther C, Haslam R, [http://www.cochrane.org/reviews/en/ab004227.html Antioxidants for preventing pre-eclampsia], The Cochrane Database of Systematic Reviews, 2006 Issue 4, The Cochrane Collaboration. John Wiley and Sons, Ltd.</ref>


=== Conflicts with prescription drugs ===
Pharmaceuticals designed to reduce stomach acid such as the [[proton pump inhibitor]]s (PPIs), are among the most widely-sold drugs in the world. One PPI, [[omeprazole]], has been found to lower the bioavailability of vitamin C by 12%, independent of dietary intake. This means that one would have to consume 14% more vitamin C to counteract the use of 40 mg/day of omeprazole. The probable mechanism of vitamin C reduction, intragastric pH elevated into alkalinity, would apply to all other PPI drugs, though not necessarily to doses of PPIs low enough to keep the stomach slightly acidic. <ref>[http://www.blackwell-synergy.com/doi/abs/10.1111/j.1365-2036.2005.02568.x?cookieSet=1&journalCode=apt E. B. Henry, and others ''Proton pump inhibitors reduce the bioavailability of dietary vitamin C''] "The gastric juice concentration of vitamin C is reduced in subjects with elevated intragastric pH. This is probably because of the fact that the vitamin is unstable at non-acidic pH and undergoes irreversible denaturation.<br>
.... After 28 days of 40 mg/day of omeprazole the mean plasma vitamin C level had fallen by 12.3% (P = 0.04)." Alimentary Pharmacology & Therapeutics Volume 22 Page 539 - September 2005 doi:10.1111/j.1365-2036.2005.02568.x  Accessed Nov 2006 </ref>


== Sources of vitamin C ==
Vitamin C is obtained through the diet by the vast majority of the world's population. The richest natural sources are fruits and vegetables, and of those, the [[camu camu]] fruit and the [[billygoat plum]] contain the highest concentration of the vitamin.  It is also present in some cuts of meat, especially liver.  Vitamin C as ascorbic acid is the most widely taken [[nutritional supplement]] and is available in a variety of forms from tablets and drink mixes to pure ascorbic acid crystals in capsules or as plain powder.


=== Plant sources ===
{| class="wikitable"
Citrus fruits ([[orange (fruit)|orange]], [[lemon]], [[grapefruit]], [[Lime (Citrus aurantifolia)|lime]]), [[tomato]]es, and [[potato]]es are good common sources of vitamin C. Other foods that are good sources of vitamin C include [[papaya]], [[broccoli]], [[brussels sprout]]s, [[black currant]]s, [[strawberry|strawberries]], [[cauliflower]], [[spinach]], [[cantaloupe]], [[kiwifruit]], [[Cranberry|cranberries]] and [[Capsicum|red peppers]].
|-
!
! Guinea pigs
! UK
! USA
! WHO
! Linus Pauling Institute
! Vitamin C Foundation
! Linus Pauling
! Other primates
|-
| Daily vitamin C intake (mg)
| 10-30<ref name="titleGuinea Lynx">{{cite web |url=http://www.guinealynx.com/scurvy.html |title=Guinea Lynx :: Scurvy -- Vitamin C Deficiency |accessdate=2007-12-22 |format= |work=}}</ref>
| 40
| 95
| 45<ref>[http://whqlibdoc.who.int/publications/2004/9241546123_chap7.pdf Vitamin and mineral requirements in human nutrition, 2nd edition] World Health Organization and Food and Agriculture Organization, 2004 - Retrieved January 2007</ref>
| 400
| 3000 <ref>[http://www.vitamincfoundation.org/vitcrda.htm Vitamin C Foundation's RDA - </ref>
| 6000-18000
| 2000-6000<ref name="pmid-10378206">{{cite journal |author=Milton K |title=Nutritional characteristics of wild primate foods: do the diets of our closest living relatives have lessons for us? |journal=Nutrition |volume=15 |pages=488–98 |year=1999 |pmid=10378206 |doi= |issn=}}</ref>
|}


[[Emblica officinalis]] often referred to as [[Indian gooseberry]] or [[amla]], is one of the richest known sources of vitamin C (720 mg/100 g of fresh pulp or up to 900 mg/100 g of pressed juice.&nbsp;&mdash; it contains 30 times the amount found in oranges.


The amount of vitamin C in foods of plant origin depends on:
=== Scurvy ===
Scurvy is a potentially serious condition that results from inadequate consumption of fresh fruit and vegetables, usually because of ignorance about proper nutrition, psychiatric disorders, alcoholism, or social isolation. It was once a common disease of sailors on long voyages, who had to subsist for long periods on dried beef and biscuits, and was a feature of the Irish famine in the 19th century. The symptoms of scurvy first appear only after many weeks of low intake. The first symptom is fatigue, followed by a wide variety of cutaneous symptoms, including follicular hyperkeratosis, perifollicular hemorrhages, ecchymoses, xerosis, leg edema, and bent or coiled body hairs. Scurvy is associated with generally poor wound healing. Gum abnormalities include gingival swelling, purplish discoloration, and hemorrhages. The patient with scurvy commonly reports pain in the back and joints, that is sometimes accompanied by hemorrhage into the soft tissue and joints. Anemia is a common symptom, and leukopenia an occasional symptom. Scurvy is life-threatening; syncope and sudden death may occur. However, treatment with vitamin C results in rapid, often dramatic, improvement. <ref name="pmid10570371"/>


* the precise variety of the plant,
While Hippocrates described a case of scurvy in about 400 BCE, the cause of this disease was first clearly established by a surgeon in the British Royal Navy, [[James Lind]], in 1747. In one of the earliest "controlled experiments", Lind gave some of the crew two oranges and one lemon per day, in addition to normal rations, while others (the control group) continued with their normal rations. The results showed that citrus fruits prevented scurvy, and Lind published his work in 1753 as his ''Treatise on the Scurvy.''
* the soil condition
* the climate in which it grew,
* the length of time since it was picked,
* the storage conditions,
* the method of preparation. Cooking in particular is often said to destroy vitamin C&nbsp;&mdash; but see the section on Food preparation.


The following table is approximate and shows the relative abundance in different raw plant sources. The amount is given in milligrams per 100 grams of fruit or vegetable (for comparison, one 5 ml teaspoon of pure vitamin C powder weighs 5,000 milligrams).
This disease is still the basis of some recommended dietary allowances throughout the world. The studies of Krebs ''et al.'' <ref>Krebs NA (1948) Vitamin C requirements of human adults: experimental studies of vitamin C deprivation in man. ''Lancet'' 254:853-6</ref> and later studies in Iowa were the first attempts to quantify vitamin C requirements, and led to the conclusion that between 6.5 and 10 mg per day is needed to prevent or cure early signs of deficiency. The Iowa studies showed that, at tissue saturation, the body contains a total of about 20 mg/kg vitamin C (about 1.5 g in total), and that vitamin C is lost at a rate of about 3% per day. Symptoms of scurvy appear when the whole body content falls below about 300 mg.
In 1999,the WHO and the UK recommended 30 mg as a safeguard for most of the population.<ref name="pmid10570371"/> RDAs have been slightly raised since.


<div style="float:left; padding: 1em;">
In 1974, Linus Pauling pointed out that amounts of recommended vitamin C in the range of 45 mg per day (for adults) should be renamed ''Minimum Dietary Allowances'' to reflect the fact that they were only intended to prevent a deficiency disease.<ref name="pmid4612519">{{cite journal |author=Pauling L |title=Are recommended daily allowances for vitamin C adequate? |journal=Proc Natl Acad Sci USA |volume=71  |pages=4442–6 |year=1974 |pmid=4612519 |url=http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=4612519}}</ref>
{| class="wikitable" border="1" cellpadding="2"
Although this suggestion was not accepted by health authorities, more recent recommendations reflect the notion that vitamin C not only prevents scurvy but contributes to the attainment of the "best of health".
!Plant source
!Amount<br> (mg/100 g)
|-
|[[Billy Goat plum]] || 3150
|-
|[[Camu Camu]] || 2800
|-
|[[Wolfberry]] || 2500
|-
|[[Rose hip]] || 2000
|-
|[[Acerola]] || 1600
|-
|[[Amla]] || 720
|-
|[[Jujube]] || 500
|-
|[[Baobab]] || 400
|-
|[[Blackcurrant]] || 200
|-
|[[Red pepper]] || 190
|-
|[[Parsley]] || 130
|-
|[[Seabuckthorn]] || 120
|-
|[[Guava]] || 100
|-
|[[Kiwifruit]] || 90
|-
|[[Broccoli]] || 90
|-
|[[Loganberry]] || 80
|-
|[[Redcurrant]] || 80
|-
|[[Brussels sprout]]s ||80
|-
|[[Lychee]] || 70
|-
|[[Cloudberry]] || 60
|-
|[[Persimmon]] || 60


|}
=== Based on pharmacokinetics ===
</div>
Some authors have argued that many studies of vitamin C are methodologically flawed, for a variety of reasons, and argue that more studies are needed to determine physiological daily requirements  <ref>e.g. {{cite journal | author= Padayatty SJ, Levine M |  title=Vitamin C and E and the Prevention of Preeclampsia&nbsp;&mdash; Letter | journal=NEJM | volume=355  | pages=1065–6 | url=http://www.health.adelaide.edu.au/og/research/ACTS%20Published%20letter1065.pdf | year=2006}}</ref>
In line with Pauling's suggestion, Levine ''et al.'' pioneered the use of pharmacokinetic studies to base recommended dietary allowances on physiological requirements.<ref name="Mark Levine">{{cite web |url=http://intramural.niddk.nih.gov/research/faculty.asp?People_ID=1492 |title= Mark Levine, NIDDK, National Institutes of Health |accessdate=2007-11-19 |author= |authorlink= |coauthors= |date= |format= |work= |publisher= |pages= |language= |archiveurl= |archivedate= |quote="Recommended dietary allowances (RDAs) for vitamin C (ascorbate) have been based on preventing the deficiency disease scurvy. We proposed that new RDAs for vitamin C and other vitamins could be determined using in situ kinetics, a concept developed by this laboratory."}}</ref> This approach gave solid support to the ''5 servings of fruits and vegetables a day'' recommandation<ref name="Mark Levine"/><ref name="pmid16522902">{{cite journal |author=Wannamethee SG ''et al.'' |title=Associations of vitamin C status, fruit and vegetable intakes, and markers of inflammation and hemostasis |journal=Am J Clin Nutr |volume=83  |pages=567–74; quiz 726–7 |year=2006 |pmid=16522902 |doi= |issn=}}</ref> made by the World Health Organization.


<div style="float:left; padding: 1em;">
{| class="wikitable" border="1" cellpadding="2"
!Plant source
!Amount<br> (mg/100 g)
|-
|[[Papaya]] || 60
|-
|[[Strawberry]] || 60
|-
|[[Orange (fruit)|Orange]] || 50
|-
|[[Lemon]] || 40
|-
|[[Melon]], cantaloupe || 40
|-
|[[Cauliflower]] || 40
|-
|[[Grapefruit]] || 30
|-
|[[Raspberry]] || 30
|-
|[[Tangerine]] || 30
|-
|[[Mandarin orange]] || 30
|-
|[[Passion fruit]] || 30
|-
|[[Spinach]] || 30
|-
|[[Cabbage]] raw green || 30
|-
|[[Lime (fruit)|Lime]] || 20
|-
|[[Mango]] || 20
|-
|[[Potato]] || 20
|-
|[[Melon]], honeydew || 20


|-
Vitamin C intake recommendations are now set to levels necessary to attain the "best state of physical and mental health,"<ref>Article 12, International Covenant on Economic, Social and Cultural Rights, United Nations, resolution 2200A (XXI), 16 December 1966 [http://www.unhchr.ch/html/menu3/b/a_cescr.htm]</ref>. The international consensus is that increasing fruit and vegetable consumption is an essential part of the prevention and management of chronic diseases
|[[Mango]] || 16
(cardiovascular diseases, cancer, diabetes and obesity)<ref>WHO/FAO release independent Expert Report on diet and chronic disease. March 3rd, 2003. World Health Organization [http://www.who.int/mediacentre/news/releases/2003/pr20/en/]</ref>
|-
|[[Tomato]] || 10
|-
|[[Blueberry]] || 10
|-
|[[Pineapple]] || 10
|}
</div>


<div style="float:left; padding: 1em;">
=== Based on evolutionary biology ===
{| class="wikitable" border="1" cellpadding="2"
The notion that the genome of Man has not evolved as rapidly as his methods to produce food is commonly recognized, in particular in [[evolutionary biology]] and [[evolutionary medicine]]. The [[thrifty gene hypothesis]] is an example of an evolutionary biology theory that is based on the discrepancies between genetic evolution and historical evolution.  
!Plant source
!Amount<br> (mg/100 g)
|-
|[[Pawpaw]] || 10
|-
|[[Grape]] || 10
|-
|[[Apricot]] || 10
|-
|[[Plum]] || 10
|-
|[[Watermelon]] || 10
|-
|[[Banana]] || 9
|-
|[[Carrot]] || 9
|-
|[[Avocado]] || 8
|-
|[[Crabapple]] || 8
|-
|[[Peach]] || 7
|-
|[[Apple]] || 6
|-
|[[Blackberry]] || 6
|-
|[[Beetroot]] || 5
|-
|[[Pear]] || 4
|-
|[[Lettuce]] || 4
|-
|[[Cucumber]] || 3
|-
|[[Eggplant]] || 2
|-
|[[Fig]] || 2
|-
|[[Bilberry]] || 1
|-
|[[Horned melon]] || 0.5
|-
|[[Medlar]] || 0.3
|-
|[[cranberries]] || ?
|}
</div>
<br clear="both" />


=== Animal sources ===
As early as 1949, Bourne<ref>Bourne, GH (1949) ''Brit J Nutr'' 2:346 quoted in {{cite journal |author=Pauling L |title=Evolution and the need for ascorbic acid |journal=Proc Natl Acad Sci USA|volume=67  |pages=1643–8 |year=1970 |pmid=5275366 |doi= |issn=}}</ref> pointed out the magnitude of the decrease in vitamin C intake that occurred as the human lineage left the environment in which the vitamin C machinery had been lost. Most recent data confirm the initial statements by Bourne, Stone<ref name="pmid6063937">{{cite journal |author=Stone I |title=The genetic disease, Hypoascorbemia. A fresh approach to an ancient disease and some of its medical implications |journal=Acta geneticae medicae et gemellologiae |volume=16 |issue=1 |pages=52–62 |year=1967 |pmid=6063937 |url=http://www.seanet.com/~alexs/ascorbate/196x/stone-i-acta_genet_med_et_gemell-1967-v16-n1-p52.htm |issn=}}</ref> and Pauling<ref>{{cite journal |author=Pauling L |title=Evolution and the need for ascorbic acid |journal=Proc Natl Acad Sci USA|volume=67  |pages=1643–8 |year=1970 |pmid=5275366 |doi= |issn=}}</ref> that the environment in which vitamin C production was lost provided gram amounts of vitamin C (between 2 and 6 g).<ref name="pmid10378206"/>


The overwhelming majority of species of animals and plants synthesise their own vitamin C. Synthesis is achieved through a sequence of four [[enzyme]] driven steps, which convert [[glucose]] to ascorbic acid. It is carried out either in the [[kidney]]s, in [[reptiles]] and [[birds]], or the [[liver]], in [[mammals]] and [[perching birds]]. The last enzyme in the process, [[l-gulonolactone oxidase]], cannot be made by humans because the gene for this enzyme is defective (Pseudogene ΨGULO). The loss of an enzyme concerned with [[ascorbic acid]] synthesis has occurred quite frequently in [[evolution]] and has affected most [[fish]]; many [[bird]]s; some [[bat]]s; [[guinea pig]]s; and most [[primates]], including [[human]]s. The [[mutation]]s have not been lethal because ascorbic acid is so prevalent in the surrounding food sources (it may be noted that many of these species' diet consists largely of fruit).
Stone called hypoascorbemia, the inability to produce vitamin C, an [[inborn error of metabolism]], comparable to [[lactose intolerance]], for example. The Online Mendeleian Inheritance in Man database (National Center for Biotechnology Information)<ref name="OMIM - HYPOASCORBEMIA"/> considers this analysis to be valid, and adds that it could be called a "''public'' inborn error of metabolism". Although the basic postulate of Stone, which was later strongly supported by Pauling, is now accepted by OMIM, the implications of the evolutionary ''discordance'' remain to be explored.


For example an adult [[goat]] will manufacture more than 13,000 mg of vitamin C per day in normal health and as much as 100,000 mg daily when faced with life-threatening disease, trauma or stress. <ref>[http://www.siumed.edu/mrc/research/vitamins/gi13sg.html ''Vitamins and Minerals''] M. Ellert, Southern Illinois University, School of Medicine. 1998  - "However, if the ability of a 70-kg goat to synthesize endogenous ascorbate is compared with the RDA of a 70-kg human, there is a 300-fold difference (13,000 mg vs. 45 mg)." Accessed January 2007</ref>
''For a discussion on the latency time between the formulation of evolutionary biology hypotheses and their testing, see [http://en.citizendium.org/wiki/Evolutionary_medicine#Older_evolutionary_hypotheses Older evolutionary hypotheses], in [[evolutionary medicine]].''


Trauma or injury has been demonstrated to use up large quantities of vitamin C in animals, including humans.  
== Therapeutic uses ==
<ref>[http://linkinghub.elsevier.com/retrieve/pii/S0022480402000835 ''Ascorbic acid dynamics in the seriously ill and injured.''] Journal of Surgical Research, Volume 109, Issue 2, Pages 144–148 C. Long. - "Our results show that plasma ascorbic acid levels following trauma and during infection are extremely low and are not normalized with 300 or even 1000 mg/day supplemented TPN. " Accessed January 2007</ref>
===Critical care===
"''RECENT FINDINGS: In critically ill patients and after severe burns, the rapid restoration of depleted ascorbate levels with high-dose parenteral vitamin C may reduce circulatory shock, fluid requirements and oedema. ... The rapid replenishment of ascorbate is of special clinical significance in critically ill patients who experience drastic reductions in ascorbate levels, which may be a causal factor in the development of circulatory shock. Supraphysiological levels of ascorbate, which can only be achieved by the parenteral and not by the oral administration of vitamin C, may facilitate the restoration of vascular function in the critically ill patient.''"<ref name="pmid17053422">{{cite journal |author=McGregor GP ''et al.''|title=Rationale and impact of vitamin C in clinical nutrition |journal=Curr Opin Clin Nutr Metab Care |volume=9 |pages=697–703 |year=2006 |pmid=17053422 |doi=10.1097/01.mco.0000247478.79779.8f}}</ref>
===Post-operative complications===
''A reduction of plasma ascorbic acid concentration in the post-operative period has been well documented and is associated with an increase in post-operative complications ... Doses of approximately 1150 mg ascorbic acid would be necessary to compensate for the observed loss and to raise plasma ascorbic acid to high normal values. CONCLUSIONS: There is a significantly increased post-operative metabolic clearance of ascorbic acid that might be considered when framing future dose recommendations in post-operative patients.''<ref name="pmid16085104">{{cite journal |author=Rümelin A ''et al.''|title=Metabolic clearance of the antioxidant ascorbic acid in surgical patients |journal=J. Surg. Res. |volume=129 |pages=46–51 |year=2005 |pmid=16085104 |doi=10.1016/j.jss.2005.03.017}}</ref>
===Anemia===
''The present study also demonstrated that for populations receiving an abundant supply of non-heme iron, it is possible to control anemia in a simple, safe, and inexpensive manner by adding ascorbic acid to drinking water.''<ref name="pmid16222916">{{cite journal |author=de Almeida CA ''et al'' |title=Effect of fortification of drinking water with iron plus ascorbic acid or with ascorbic acid alone on hemoglobin values and anthropometric indicators in preschool children in day-care centers in Southeast Brazil |journal=Food Nutr Bull |volume=26 |pages=259–65 |year=2005 |pmid=16222916 |doi=}}</ref>
=== Viral diseases ===


It was only realised in the 1920s that some cuts of meat and fish are also a source of vitamin C for humans. The muscle and fat that make up the modern western diet are, however, poor sources. As with fruit and vegetables, cooking degrades the vitamin C content.
Vitamin C has a very interesting [[therapeutic index]] in viral infections, and has been claimed to be effective against a very broad variety of viruses, including [[herpes simplex virus | herpes simplex]], [[vaccinia]], [[Dog_bite#Rabies | rabies]], [[herpes zoster virus | herpes zoster]] (shingles), [[measles virus | measles ]], [[influenza]], [[foot-and-mouth virus | foot-and-mouth]], [[hepatitis viruses | hepatitis]], [[HIV]], [[poliomyelitis virus | polio virus]] and so forth <ref name="isbn0-8247-9313-7">Jariwalla RJ, Harakeh, S. "Mechanisms underlying the action of vitamin C in viral and immunodeficiency diseases"{{cite book |author=Fuchs, Jurgen; Packer, Lester; Fuchs, Jürgen |title=Vitamin C in health and disease |publisher=M. Dekker |location=New York |year=1997 |pages=309-10 |isbn=0-8247-9313-7 |url=http://books.google.com/books?id=4nODCOzu2n8C}}</ref>.  


Vitamin C is present in [[Breastfeeding#Benefits|mother's milk]] and in less amounts in [[Milk#Nutritional benefits|raw cow's milk]] (but pasteurized milk contains only trace amounts of the vitamin). <ref>[http://www.saanendoah.com/compare.html Comparing Milk: Human, Cow, Goat & Commercial Infant Formula] Compiled and referenced by Associate Professor Stephanie Clark, Ph.D Assistant Professor, Dept. of Food Science and Human Nutrition, Washington State University.
Vitamin C acts in conjunction with copper (and perhaps other transition metals such as iron) and oxygen to produce hydroxyl radicals, which are the most toxic free radicals.<ref name="pmid6317379">{{cite journal |author=Samuni A ''et al.'' |title=On the cytotoxicity of vitamin C and metal ions. A site-specific Fenton mechanism |journal=Eur J Biochem |volume=137  |pages=119–24 |year=1983 |pmid=6317379 |doi=}}</ref> As emphacized above (see Description -- Antioxidant properties of vitamin C), most of the enzymatic and non-enzymatic effects of vitamin C are due to its antioxidant properties, and in particular to its ability to reduce iron and copper. In viruses, transition metal chemistry is not regulated in the same way as in mammalian cells. Concentrations of vitamin C that will lead to viral DNA damage (through copper reduction and subsequent generation of hydroxyl radical from hydrogen peroxide) can be attained in the body through supplementation.<ref>Harakeh and Jariwalla. (1996) "Antiviral and Immunomodulatory Activities of Ascorbic Acid" in {{cite book |author=Harris, James W. |title=Ascorbic acid: biochemistry and biomedical cell biology |publisher=Plenum Press |location=New York |year=1996 |isbn=0-306-45148-4 }}</ref>
Accessed January 2007.</ref>


The following table shows the relative abundance of vitamin C in various foods of animal origin, given in mg of vitamin C per 100 grams of food:


<div style="float:left; padding: 1em;">
''(WP content under revision:''
{| class="wikitable" border="1" cellpadding="2"
Ascorbate usage in studies of up to several grams per day, have been associated with decreased cold duration and severity of symptoms, possibly as a result of an [[antihistamine]] effect <ref>[http://lpi.oregonstate.edu/infocenter/vitamins/vitaminC/]</ref>
!Food
!Amount<br> (mg/100 g)
|-
|[[Calf]] [[liver]] (raw) || 36
|-
|[[Beef]] liver (raw) || 31
|-
|[[Oyster]]s (raw) || 30
|-
|[[Cod]] [[roe]] (fried) || 26
|-
|[[Pork]] liver (raw) || 23
|-
|[[Lamb]] [[brain]] (boiled) || 17
|-
|[[Chicken]] liver (fried) || 13
|-
|Lamb liver (fried) || 12
|-
|Lamb [[heart]] (roast) || 11
|}
</div>


<div style="float:left; padding: 1em;">
In 2002 a [[meta-study]] into all the published research on effectiveness of ascorbic acid in the treatment of infectious disease and toxins was conducted, by Thomas Levy, Medical Director of the Colorado Integrative Medical Centre in Denver. He claimed that evidence exists for its therapeutic role in a wide range of viral infections and for the treatment of snake bites.
{| class="wikitable" border="1" cellpadding="2"
!Food
!Amount<br> (mg/100 g)
|-
|Lamb [[tongue]] (stewed) || 6
|-
|[[Breastfeeding|Human milk]] (fresh) || 4
|-
|Goat milk (fresh) || 2
|-
|Cow milk (fresh) || 2
|-
|Beef [[steak]] (fried) || 0
|-
|Hen's egg (raw) || 0
|-
|Pork [[bacon]] (fried) || 0
|-
|Calf veal cutlet (fried) || 0
|-
|Chicken leg (roast) || 0
|}
</div>
<br clear="both" />


=== Food preparation ===
It is important to choose a suitable method of food preparation that conserves vitamin C content. When cooking vegetables, one should seek to minimize temperature and duration of cooking and not discard water used in preparation (e.g., by [[steaming|steam cooking]] or by making soup). Food source vitamin C is identical to that in supplements.  The structure of vitamin C is well understood, see [[ascorbic acid]], and there is no difference in benefit between natural and synthetic forms (although fruits and vegetables contain various other nutrients, and vitamin C is not their only health benefit).


Recent observations suggest that the impact of temperature and cooking on vitamin C may have been overestimated, since it decomposes around 190–192&deg;C, well above the boiling point of water:
'''Colds'''
#Since it is water soluble, vitamin C will strongly leach into the cooking water while cooking most vegetables &mdash; but this doesn't necessarily mean the vitamin is destroyed &mdash; it's still there, but it's in the cooking water. (This may also suggest how the apparent misconception about the extent to which boiling temperatures destroy vitamin C might have been the result of flawed research: If the vitamin C content of vegetables (and not of the water) was measured subsequent to cooking them, then that content would have been much lower, though the vitamin has not actually been destroyed.)
A recent 55-study review <ref>[http://medicine.plosjournals.org/perlserv/?request=get-document&doi=10.1371/journal.pmed.0020168 Douglas RM, Hemilä H (2005) Vitamin C for Preventing and Treating the Common Cold]. PLoS Med 2(6): e168</ref> found little positive effect of a vitamin C intake on common cold at low doses, but indication of [[prophylaxis]] benefits at higher doses especially where the subjects were in stressful situations.  
#Not only the temperature, but also the exposure time is significant. Contrary to what was previously and is still commonly assumed, it can take much longer than two or three minutes to destroy vitamin C at boiling point


It also appears that cooking doesn't necessarily leach vitamin C in all vegetables at the same rate; it has been suggested that the vitamin is not destroyed when boiling [[broccoli]].<ref name=Combs>Combs GF. The Vitamins, Fundamental Aspects in Nutrition and Health. 2nd ed. San Diego, CA: Academic Press, 2001:245–272</ref> This may be a result of vitamin C leaching into the cooking water at a slower rate from this vegetable.
At least 29 controlled clinical trials (many [[double-blind]] and [[placebo]]-controlled) involving a total of over 11,000 participants have been conducted into vitamin C and the [[Common cold]]. These trials were reviewed in the 1990s<ref name="Hemilia>H. Hemilia, Does Vitamin C Alleviate the Symptoms of the Common Cold?, Scand J Infect Dis: 26:1 (1996)</ref><ref>H. Hemilia H (1996) Vitamin C supplementation and common cold symptoms: problems with inaccurate reviews. Nutrition, 12: 804 </ref> and again more recently.<ref>Douglas RM ''et al.'' "[http://www.ncbi.nlm.nih.gov/sites/entrez?cmd=Retrieve&db=pubmed&dopt=AbstractPlus&list_uids=15495002&query_hl=8&itool=pubmed_docsum Vitamin C for preventing and treating the common cold]," National Centre for Epidemiology and Population Health, Australian National University, 2000, URL accessed Jan 25, 2006]</ref> The trials show that vitamin C reduces the duration and severity of colds but not the frequency. The data indicate that there is a normal dose-response relationship. Vitamin C is more effective the higher the dose. <ref>[http://www.supplementwatch.com/suplib/supplement.asp?DocId=1278&templateId=100 Supplementwatch.com] Vitamin C -  Scientific Support  Section - "At least 3 controlled studies have shown an 80% reduction in the incidence of pneumonia among vitamin C users. In one large study (over 700 students), vitamin C (1 g per hour for the first 6 hours followed by 3 g per day), reduced cold and flu symptoms by 85%." </ref>
The controlled trials and clinical experience show that vitamin C in doses ranging from 0.1 to 2 g/day have little effect. 
The vast majority of the trials were limited to doses below 1 g/day. As doses rise, it becomes increasingly difficult to keep the trials double blind because of the obvious gastro-intestinal side effects of heavy doses of vitamin C. So, the most effective trials at doses between 2 and 10 g/day are generally met with skepticism.


Copper pots will destroy the vitamin.<ref>[http://ptcl.chem.ox.ac.uk/MSDS/AS/ascorbic_acid.html Safety data]  University of Oxford Physical & Theoretical Chemistry Lab. Safety home page. </ref>


Some research shows that fresh-cut fruit may not lose much of its nutrients when stored in the refrigerator for a few days.<ref>[http://www.webmd.com/content/article/123/115022.htm WebMD Medical News] ''Fresh-Cut Fruit May Keep Its Vitamins'', Miranda Hitti</ref>
'''Hepatitis C virus infection'''
A phase I clinical trial was conducted to determine whether antioxidants could be beneficial in hepatitis C virus infection (HCV infection). This infection leads to a lack of antiviral defenses and to oxidative stress in the liver. Ultimately, oxidative stress, notably lipid-mediated oxidative stress (lipid peroxidation), causes liver cells to degenerate and die. Vitamin C was part of the protocol. The trial yielded favourable changes : normalization of liver enzymes (ALT returned to normal in 44 % of those who had abnormal ALT); decrease in viral load (25 % of patients); tissue changes (36.1 % had improvements histologic parameters); and 58 % of patients saw their quality of life improve with the antioxidant treatment (increase in the [[SF-36]]<ref name="International Quality of Life Assessment - The SF Instruments">{{cite web |url=http://www.iqola.org/instruments.aspx |title=International Quality of Life Assessment - The SF Instruments |accessdate=2007-11-19 |format= |work=}}</ref> score).<ref name="pmid16082287">{{cite journal |author=Melhem A ''et al.'' |title=Treatment of chronic hepatitis C virus infection via antioxidants: results of a phase I clinical trial |journal=J Clin Gastroenterol |volume=39  |pages=737–42 |year=2005 |pmid=16082287 |doi=}}</ref>


Vitamin C enriched teas and infusions have increasingly appeared on supermarket shelves. Such products would be nonsense if boiling temperatures did indeed destroy vitamin C at the rate it had previously been suggested. It should be noted however that as of 2004 most academics not directly involved in vitamin C research still teach that boiling temperatures will destroy vitamin C ''very'' rapidly.
=== Toxics ===
'''Lead'''  


=== Vitamin C supplements ===
(in progress)
Vitamin C is the most widely taken dietary supplement.<ref> [http://www.thedietchannel.com/Vitamin-C.htm The Diet Channel] Vitamin C might be the most widely known and most popular vitamin purchased as a supplement. </ref> It is available in many forms including caplets, tablets, capsules, drink mix packets, in multi-vitamin formulations, in multiple anti-oxidant formulations, as chemically pure crystalline powder, time release versions, and also including [[bioflavonoids]] such as quercetin, hesperidin and rutin.  Tablet and capsule sizes range from 25 mg to 1500 mg.  Vitamin C (ascorbic acid) crystals are typically available in bottles containing 300 g to 1 kg of powder (a teaspoon of vitamin C crystals equals 5,000 mg). Other forms of Vitamin C as [[sodium ascorbate]], [[magnesium ascorbate]], [[calcium ascorbate]], mixed mineral ascorbates (e.g. Na, K, Mg, Ca, Zn), and [[Ester-C]] are also available, though less popular.


=== Methods of manufacture (chemical synthesis) ===
There is also evidence that vitamin C is useful in preventing [[lead poisoning]], possibly helping to [[Chelation|chelate]] the toxic heavy metal from the body. [http://www.seanet.com/~alexs/ascorbate/193x/holmes-hn-etal_j_lab_clin_med-1939-v23-n11-p1119.html]
Vitamin C is produced from [[glucose]] by two main routes. The Reichstein process developed in the 1930s uses a single pre-fermentation followed by a purely chemical route. The more modern two-step fermentation process was originally developed in [[China]] in the 1960s, uses additional fermentation to replace part of the later chemical stages.  Both processes yield approximately 60% vitamin C from the glucose feed.<ref>[http://www.competition-commission.org.uk/rep_pub/reports/2001/fulltext/456a4.2.pdf#search=%22Two-Step%20fermentation%20process%20vitamin%20c%201960s%22 UK Competition Commission Report on Vitamin C - 2001 ] APPENDIX 4.2.</ref>


Research is underway at the [[Scottish Crop Research Institute]] to create yeast micro organisms to synthesise ascorbic acid in a single fermentation step, a technology which is expected to reduce manufacturing costs considerably.<ref>
'''Common pesticides and contaminants'''
[http://www.scri.sari.ac.uk/SCRI/Web/Site/home/ResearchAreas/Theme2~GenestoProducts/QHN/External/vitaminC.asp Scottish Crop Research Institute] -Development of a Yeast-Based Single-Step Process for the Manufacture of L-Ascorbic Acid (vitamin C)</ref>


World production of synthesised vitamin C is currently estimated at approximately 110,000 tonnes annually.
There exists great concern about the impact of pesticides and other contaminants on the reproductive capabilities on animals, including humans.<ref name="isbn0-525-93982-2)">{{cite book |author=Myers, John E. B.; Colborn, Theo; Dumanoski, Dianne |title=Our stolen future: are we threatening our fertility, intelligence, and survival?: a scientific detective story |publisher=Dutton |location=New York |year=1996 |pages= |isbn=0-525-93982-2) |oclc= |doi=}}</ref> The toxicity of pesticides and contaminants can occur, notably, through [[endocrine disruption]] and/or [[oxidative stress]].
Main producers today are [[BASF]]/[[Takeda Chemical Industries|Takeda]], [[DSM]], [[Merck KGaA|Merck]] and the China Pharmaceutical Group Ltd. of the [[People's Republic of China]]. China is slowly becoming the major world supplier as its prices undercut those of the US and European manufacturers.<ref>[http://www.nutraingredients.com/news/ng.asp?n=63349-dsm-vitamin-c nutraingredients.com] "DSM makes last stand against Chinese vitamin C" 20/10/2005 accessed June 2006 .</ref>


== Discovery and history ==
The oxidative toxicity of [[bisphenol A]] to the epididymis and its effect on sperm motility and sperm count have been shown to be lessened by vitamin C.<ref name="pmid12937802">{{cite journal |author=Chitra KC, Rao KR, Mathur PP |title=Effect of experimental varicocele on structure and function of epididymis in adolescent rats: a histological and biochemical study |journal=Asian J. Androl. |volume=5 |issue=3 |pages=203–8 |year=2003 |pmid=12937802 |doi=}}</ref> The oxidative toxicities of [[endosulfan]], [[phosphamidon]],[[mancozeb]] and PCB (Aroclor 1254) were also neutralized by vitamin C.<ref name="pmid8671712">{{cite journal |author=Khan PK, Sinha SP |title=Ameliorating effect of vitamin C on murine sperm toxicity induced by three pesticides (endosulfan, phosphamidon and mancozeb) |journal=Mutagenesis |volume=11 |issue=1 |pages=33–6 |year=1996 |pmid=8671712 |doi=}}</ref><ref name="pmid17267175">{{cite journal |author=Krishnamoorthy G, Venkataraman P, Arunkumar A, Vignesh RC, Aruldhas MM, Arunakaran J |title=Ameliorative effect of vitamins (alpha-tocopherol and ascorbic acid) on [[PCB]] (Aroclor 1254) induced oxidative stress in rat epididymal sperm |journal=Reprod. Toxicol. |volume=23 |issue=2 |pages=239–45 |year=2007 |pmid=17267175 |doi=10.1016/j.reprotox.2006.12.004}}</ref> It is important to note that the protective effects occurred irrespective of the chemical structure of the toxics, but rather addressed a common pathway of injury, i.e. oxidative stress, considering the very broad variety of chemical properties of toxics commonly encountered in the environment and in humans.
The need to include fresh plant food or raw animal flesh in the diet to prevent disease was known from ancient times. Native peoples living in marginal areas incorporated this into their medicinal lore. For example, infusions of spruce needles were used in the temperate zones, or the leaves from species of drought-resistant trees in desert areas. In 1536, the French explorer Jacques Cartier, exploring the [[Saint Lawrence River|St. Lawrence River]], used the local natives' knowledge to save his men who were dying of scurvy. He boiled the needles of the [[Thuja|arbor vitae]] tree to make a tea that was later shown to contain 50 mg of vitamin C per 100 grams.<ref> [http://www3.sympatico.ca/goweezer/canada/z00cartier3.htm Jacques Cartier's Second Voyage] , 1535 Winter & Scurvy </ref><ref> [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=12422875&dopt=Abstract Jacques Cartier witnesses a treatment for scurvy.] NCBI Pb Med, 2002 Jun, Martini E. </ref>
'''


Through history the benefit of plant food for the survival of sieges and long sea voyages was recommended by enlightened authorities. [[John Woodall]], the first appointed surgeon to the [[British East India Company]], recommended the use of [[lemon]] juice as a preventive and cure in his book "The Surgeon's Mate" of 1617. The [[Netherlands|Dutch]] writer, [[Johann Bachstrom]] of Leyden, in 1734, gave the firm opinion that ''"scurvy is solely owing to a total abstinence from fresh vegetable food, and greens; which is alone the primary cause of the disease."''
=== Medications (reduction of adverse effects) ===
'''Reduction of gentamicin nephrotoxicity'''


The first attempt to give scientific basis for the cause of scurvy was by a ship's surgeon in the British [[Royal Navy]], [[James Lind]]. While at sea in May 1747, Lind provided some crewmembers with two oranges and one lemon per day, in addition to normal rations, while others continued on [[cider]], [[vinegar]] or seawater, along with their normal rations. In the [[history of science]] this is considered to be the first example of a controlled experiment comparing results on two populations of a factor applied to one group only with all other factors the same. The results conclusively showed that citrus fruits prevented the disease. Lind wrote up his work and published it in 1753, in ''[[Treatise on the Scurvy]]''.
Vitamin C has been found to be effective in reducing or protecting against nephrotoxicity caused by the aminoglycoside antibiotic [[gentamicin]].<ref name="pmid12962996">{{cite journal |author=Ali BH |title=Agents ameliorating or augmenting experimental gentamicin nephrotoxicity: some recent research |journal=Food Chem. Toxicol. |volume=41 |issue=11 |pages=1447–52 |year=2003 |pmid=12962996 |doi= |issn=}}</ref>


Lind's work was slow to be noticed, partly because he gave conflicting evidence within the book and partly because of social inertia in some elements at the British admiralty who saw care for the well-being of ships' crew as a sign of weakness. There was also the fact that fresh fruit was very expensive to keep on board, whereas boiling it down to juice allowed easy storage but destroyed the vitamin. Ships' captains assumed wrongly that it didn't work, because the juice failed to cure scurvy.  (Indeed, boiling in copper kettles may have destroyed the vitamin.  See reference under [[Vitamin C#Food preparation|Food preparation]], above.)
=== Cardiovascular disease and fat intake===
After a high-fat meal, [[triglycerides]] raise and the flow of blood through the arteries is impaired. Two grams of vitamin C largely suppress the impairment in [[flow-mediated dilatation]] in people with coronary heart disease as well as in healhty persons.<ref name="pmid12018880">{{cite journal |author=Ling L, Zhao SP, Gao M, Zhou QC, Li YL, Xia B |title=Vitamin C preserves endothelial function in patients with coronary heart disease after a high-fat meal |journal=Clinical cardiology |volume=25 |issue=5 |pages=219–24 |year=2002 |pmid=12018880 |doi=}}</ref> In persons using a high-fat, low carbohydrate diet to lose weight, 1 g of vitamin C combined to 800 IU of vitamin E was successfully used to lower C-reactive protein, a confirmation of previous studies on the acute CRP-lowering effect of high, but physiological post-meal intakes of vitamin C.  


It was 1795 before the British navy adopted lemons or [[Lime (fruit)|lime]] as standard issue at sea. Limes were more popular as they could be found in British West Indian Colonies, unlike lemons which weren't found in British Dominions, and were therefore more expensive. (This practice led to the nickname [[Alternative words for British|limey]] for British people, especially British sailors.) Captain James Cook had previously demonstrated and proven the principle of the advantages of fresh and preserved foods, such as [[sauerkraut]], by taking his crews to the Hawaiian Islands and beyond without losing any of his men to scurvy. For this otherwise unheard of feat, the British Admiralty awarded him a medal. So, the Navy was certainly well aware of the principle. The cost of providing fresh fruit on board was probably a factor in this long delay. The Captains usually provided luxuries or non-standard supplies not provided by the Admiralty.
Overall, these finding indicate that previous trials of vitamin C must be reinterpreted in function of the timing of the supplementation and in function of the amount of fat consumed.  


=== Cardiovascular disease as a long latency collagen disease ===
(Under revision:
Nobel laureate chemist Linus Pauling stated that "chronic scurvy" or "subclinical scurvy" is a condition of vitamin C deficiency which is not as easily noticeable as acute scurvy (because chronic scurvy is mostly internal), characterized by micro lesions of tissues (such as that caused by blood pulsing through arteries, which stretches the arterial walls causing them to tear slightly), due to suboptimal collagen synthesis (see [http://en.citizendium.org/wiki/Vitamin_C#Collagen_synthesis Collagen synthesis], above). Pauling and Rath stated that cardiovascular disease is primarily a collagen defect in the vasculature, and that plaque deposits were consequences. In support of this notion, the Proceedings of the National Academy of Sciences published in 2000 evidence that Shionogi rats (see [http://en.citizendium.org/wiki/Vitamin_C#Biosynthesis Biosynthesis], above), a scurvy-prone species like Man, had a tendency to develop damage to the aorta, low HDL cholesterol and high total cholesterol, in a manner akin to typical human heart disease, under suboptimal vitamin C nutriture.<ref name="pmid10639167">{{cite journal |author=Maeda N, Hagihara H, Nakata Y, Hiller S, Wilder J, Reddick R |title=Aortic wall damage in mice unable to synthesize ascorbic acid |journal=Proc. Natl. Acad. Sci. U.S.A. |volume=97 |issue=2 |pages=841–6 |year=2000 |pmid=10639167 |doi= |issn=}}</ref>


The name "antiscorbutic" was used in the eighteenth and nineteenth centuries as general term for those foods known to prevent scurvy, even though there was no understanding of the reason for this. These foods include lemons, limes, and oranges; [[sauerkraut]], salted cabbage, malt, and [[portable soup]] were employed with variable effect.
Vitamin C is the main component of the three ingredients in Pauling and Rath's patented preventive cure for Lp(a)<ref>Rath MW, Pauling LC. US Patent 5,278,189. [http://patimg2.uspto.gov/.piw?PageNum=1&docid=US005278189&IDKey=863A8B6F2A5F&HomeUrl=http%3A%2F%2Fpatft.uspto.gov%2Fnetacgi%2Fnph-Parser%3FSect1%3DPTO1%2526Sect2%3DHITOFF%2526d%3DPALL%2526p%3D1%2526u%3D%25252Fnetahtml%25252FPTO%25252Fsrchnum.htm%2526r%3D1%2526f%3DG%2526l%3D50%2526s1%3D5278189.PN.%2526OS%3DPN%2F5278189%2526RS%3DPN%2F5278189  Prevention and treatment of occlusive cardiovascular disease with ascorbate and substances that inhibit the binding of lipoprotein(a)]. USPTO. 11 Jan 1994.</ref> related heart disease, the other two being the amino acid [[lysine]] and [[nicotinic acid]] (a form of Vitamin B3).  Lp(a) as an atherosclerotic, evolutionary substitute for ascorbate<ref>
Rath M, Linus P. [http://www.pnas.org/cgi/reprint/87/16/6204 Hypothesis: Lipoprotein (a) is a surrogate for ascorbate]. Proc Natl Acad Sci USA. Vol 87, 6204–6207, Aug 1990.</ref> is still discussed as a hypothesis by mainstream medical science<ref>Kniffin CL, McKusick VA, Brennan P. [http://www.ncbi.nlm.nih.gov/entrez/dispomim.cgi?id=152200 APOLIPOPROTEIN(a); LPA].  OMIMTM - Online Mendelian Inheritance in Man, Johns Hopkins University. 1986–2006</ref> and the Rath-Pauling related protocols<ref>[http://www.vrp.com/art/798.asp?c=1162763143031&k=/det/2100.asp&m=/includes/vrp.css&o=0&p=no&s=0] </ref> have not been rigorously tested and evaluated as conventional medical treatment by the FDA.
)


In 1907, [[Axel Holst]] and [[Theodor Frølich]], two [[Norway|Norwegian]] physicians studying [[beriberi]] contracted aboard ship's crews in the Norwegian Fishing Fleet, wanted a small test mammal to substitute for the [[pigeon]]s they used. They fed [[guinea pig]]s the test diet, which had earlier produced beriberi in their pigeons, and were surprised when scurvy resulted instead. Until that time scurvy had not been observed in any organism apart from humans, and it was considered an exclusively human disease.
=== Cancer ===
Although abundant biochemical reasons exist why vitamin C may help prevent and treat [[cancer]], [[randomized controlled trial]]s of supplementation in humans have not found benefit.


In the early [[twentieth century]], the [[Polish-American]] scientist [[Casimir Funk]] conducted research into deficiency diseases, and in 1912 Funk developed the concept of vitamins, for the elements in food which are essential to health. Then, from 1928 to 1933, the [[Hungary|Hungarian]] research team of [[Joseph L Svirbely]] and [[Albert Szent-Györgyi]] and, independently, the [[United States|American]] [[Charles Glen King]], first isolated vitamin C and showed it to be ascorbic acid.
====Biochemistry====
As noted above, at physiologically attainable concentrations, vitamin C suppresses the deleterious effects of oxidative stress. As oxidative stress is thought to increase the risk of several cancers, it has been suggested that vitamin C might help prevent such cancers (see '''''Toxics -- Common pesticides and contaminants'''''). There is evidence that a diet rich in fresh fruit and vegetables - prominent sources of antioxidants - can reduce the risk of some cancers, but no clear evidence that taking vitamin C supplements is protective.


In 1928 the arctic anthropologist and adventurer [[Vilhjalmur Stefansson]] attempted to prove his theory of how [[Eskimo]] ([[Inuit]]) people are able to avoid scurvy with almost no plant food in their dietThis had long been a puzzle because the disease had struck European Arctic explorers living on similar high-meat diets. Stefansson theorised that the native peoples of the Arctic got their vitamin C from fresh meat that was raw or minimally cookedStarting in February 1928, for one year he and a colleague lived on an animal-flesh-only diet under medical supervision at [[New York]]'s [[Bellevue Hospital]]; they remained healthy.
In 2005 [[in vitro]] (test tube) research by the [[National Institutes of Health]] indicated that, at high concentrations, vitamin C was preferentially toxic to several strains of [[cancer]] cells, supporting Linus Pauling's claims that vitamin C can be used to fight cancer.<ref> [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=16157892&dopt=Abstract  Qi Chen ''et al.'' Pharmacologic ascorbic acid concentrations selectively kill cancer cells: Action as a pro-drug to deliver hydrogen peroxide to tissues. Proc Natl Acad Sci USA | 2005 | vol. 102  | 13604–13609] "These findings give plausibility to intravenous ascorbic acid in cancer treatment, and have unexpected implications for treatment of infections where H<sub>2</sub>O<sub>2</sub> may be beneficial." </ref>


In 1933&nbsp;&ndash; 1934, the British chemists Sir [[Walter Norman Haworth]] and Sir [[Edmund Hirst]] and, independently, the [[Poland|Polish]] [[Tadeus Reichstein]], succeeded in synthesizing the vitamin, the first to be artificially produced. This made possible the cheap mass production of vitamin C. Haworth was awarded the 1937 [[Nobel Prize in Chemistry]] largely for this work. The synthetic form of the vitamin is identical to the natural form.
Vitamin C does inhibit some intracellular signalling pathways that are important in the proliferation of cancer cells, including the [[PI3K/AKT pathway]] <ref name="pmid17909035">{{cite journal |author=Zhao Y ''et al.'' |title=Cancer resistance in transgenic mice expressing the SAC module of Par-4 |journal=Cancer Res |volume=67  |pages=9276–85 |year=2007 |pmid=17909035 |doi=10.1158/0008-5472.CAN-07-2124}}</ref> Vitamin C inhibits this pathway ''in vitro'' as well as ''in vivo''.<ref name="pmid16475700">{{cite journal |author=Fang Q ''et al.'' |title=Ascorbyl stearate inhibits cell proliferation and tumor growth in human ovarian carcinoma cells by targeting the PI3K/AKT pathway |journal=Anticancer Res. |volume=26 |issue=1A |pages=203–9 |year=2006 |pmid=16475700 |doi= |issn=}}</ref> The form of vitamin C used to demonstrate these effects is ascorbyl stearate, a lipophilic, vitamin C derivative, which is termed a [[nutraceutical]].  


The Swiss pharmaceutical company [[Hoffmann-La Roche]] was the first to mass-produce synthetic vitamin C, under the brand name of [[Redoxon]], in 1934.
[[Hypoxia-inducible factor-1]] (HIF-1) is another well known protein involved in carcinogenisis. Vitamin C inhibits its expression, leading researchers to question whether it is the antioxidant and DNA-protective effect of vitamin C that really explains its anticancer effects. <ref name="pmid17785204" />


In 1959 the American [[J.J. Burns]] showed that the reason some mammals were susceptible to scurvy was the inability of their [[liver]] to produce the active [[enzyme]] [[L-gulonolactone oxidase]], which is the last of the chain of four enzymes which synthesize ascorbic acid.
====Trials of cancer treatment in humans====
In 1979 and 1985, two [[randomized controlled trial]]s found no beneficial effect of vitamin C supplementation in cancer patients<ref name="pmid384241">{{cite journal |author=Creagan ET, Moertel CG, O'Fallon JR, ''et al'' |title=Failure of high-dose vitamin C (ascorbic acid) therapy to benefit patients with advanced cancer. A controlled trial |journal=N. Engl. J. Med. |volume=301 |issue=13 |pages=687–90 |year=1979 |month=September |pmid=384241 |doi= |url= |issn=}}</ref><ref name="pmid3880867">{{cite journal |author=Moertel CG, Fleming TR, Creagan ET, Rubin J, O'Connell MJ, Ames MM |title=High-dose vitamin C versus placebo in the treatment of patients with advanced cancer who have had no prior chemotherapy. A randomized double-blind comparison |journal=N. Engl. J. Med. |volume=312 |issue=3 |pages=137–41 |year=1985 |month=January |pmid=3880867 |doi= |url= |issn=}}</ref>, as a result, interest for vitamin C in cancer declined markedly, although there have since been occasional case reports suggesting that there might be benefits in some cases <ref>[http://www.cmaj.ca/cgi/content/full/174/7/937  Sebastian J ''et al.'' Vitamin C documented to quell advanced-stage cancer in three cases involving bladder, lung, kidney and lymphoma tumors. ''Can Med Assn J'' 174: 937–42, 2006] </ref>


American biochemist [[Irwin Stone]] was the first to exploit vitamin C for its food preservative properties and held patents on this. He developed the theory that vitamin C was an essential nutrient deficient in humans as a result of a genetic defect that afflicted the whole human race.
====Trials of cancer prevention in humans====
Vitamin C cannot prevent cancer in men according to [[randomized controlled trial]]s.<ref name="pmid19066368">{{cite journal |author=Gaziano JM, Glynn RJ, Christen WG, ''et al'' |title=Vitamins E and C in the prevention of prostate and total cancer in men: the Physicians' Health Study II randomized controlled trial |journal=JAMA |volume=301 |issue=1 |pages=52–62 |year=2009 |month=January |pmid=19066368 |doi=10.1001/jama.2008.862 |url=http://jama.ama-assn.org/cgi/pmidlookup?view=long&pmid=19066368 |issn=}}</ref><ref name="pmid19066370">{{cite journal |author=Lippman SM, Klein EA, Goodman PJ, ''et al'' |title=Effect of selenium and vitamin E on risk of prostate cancer and other cancers: the Selenium and Vitamin E Cancer Prevention Trial (SELECT) |journal=JAMA |volume=301 |issue=1 |pages=39–51 |year=2009 |month=January |pmid=19066370 |doi=10.1001/jama.2008.864 |url=http://jama.ama-assn.org/cgi/pmidlookup?view=long&pmid=19066370 |issn=}}</ref><ref name="pmid8127329">{{cite journal |author= |title=The effect of vitamin E and beta carotene on the incidence of lung cancer and other cancers in male smokers. The Alpha-Tocopherol, Beta Carotene Cancer Prevention Study Group |journal=N. Engl. J. Med. |volume=330 |issue=15 |pages=1029–35 |year=1994 |month=April |pmid=8127329 |doi= |url=http://content.nejm.org/cgi/pmidlookup?view=short&pmid=8127329&promo=ONFLNS19 |issn=}}</ref> Although analysis of secondary outcomes in the earliest trial suggested a reduction in prostate cancer and colorectal cancer <ref name="pmid8127329"/>, this was not confirmed in prespecified analyses in the latter trials.<ref name="pmid19066368"/><ref name="pmid19066370"/>


== Vitamin C hypothesis ==
=== Cataracts ===
Since its discovery vitamin C has been considered a universal panacea by some, although this led to suspicions of it being overhyped by others. <ref>[http://ethesis.helsinki.fi/julkaisut/laa/kansa/vk/hemila/ Hemilä H., "Do vitamins C and E affect respiratory infections?" Univ. of Helsinki, Dissertation, Faculty of Medicine, Dept. of Public Health. 2006.]</ref>
A decrease in lens vitamin C concentrations in the course of cataract progression was shown.<ref name="pmid9789763">{{cite journal |author=Tessier F ''et al.''|title=Decrease in vitamin C concentration in human lenses during cataract progression |journal=Int J Vitam Nutr Res |volume=68  |pages=309–15 |year=1998 |pmid=9789763 |doi=}}</ref>


The fact that man possesses three of the four enzymes that animals employ to manufacture ascorbates in relatively large amounts, has led researchers such as [[Irwin Stone]] and [[Linus Pauling]] to hypothesize that man's ancestors once manufactured this substance in the body millions of years ago in quantities roughly estimated at 3,000–4,000 mg daily, but later lost the ability to do this through a chance of evolution. If true, this would mean that vitamin C was misnamed as a [[vitamin]] and is in fact a vital [[macronutrient]] like fat or carbohydrate. {Irwin Stone: "The Healing Factor"}
The 'Jean Mayer USDA Human Nutrition Research Center on Aging' showed that, in the 'Nurses' Health Study' cohort, practically all older women who consumed vitamin C supplements for more than 10 years were protected from lense opacities,<ref name="pmid9322567">{{cite journal |author=Jacques PF ''et al'' |title=Long-term vitamin C supplement use and prevalence of early age-related lens opacities |journal=Am J Clin Nutr |volume=66 |issue=4 |pages=911–6 |year=1997 |pmid=9322567 |doi=}}</ref> thus confirming earlier epidemiological evidence on the benefits of vitamin C supplementation in the prevention of cataracts.<ref name="pmid1985408">{{cite journal |author=Robertson JM ''et al.'' |title=A possible role for vitamins C and E in cataract prevention |journal=Am J Clin Nutr |volume=53 |issue=1 Suppl |pages=346S–351S |year=1991 |pmid=1985408 |doi=}}</ref>


Dr. Hickey, of Manchester Metropolitan University, believes that man carries a mutated and ineffective form of the genetic machinery for manufacturing the fourth of the four enzymes used by all mammals to make ascorbic acid. Cosmic rays or a [[retrovirus]] could have caused this mutation, millions of years ago. {Hickey: "Ascorbate"} In humans the three surviving enzymes continue to produce the precursors to ascorbic acid but the process is incomplete and the body then disassembles them.
The finding, made in 1998, that cataract is associated with lens vitamin C deficiency<ref name="pmid9789763"/> received support in 2004. While concentrations of vitamin C in the healthy [[aqueous humour]] are between 60 and 85 mg/dL (about 20 to 30 times those in plasma), they average just 4.3 mg/dL in people with cataract.<ref>Miratashi SAM (2004) [http://www.seagig.org/toc/v6n2/v6n2p6.pdf Vitamin C concentration of aqueous humour and plasma in patients with senile cataract]. ''Asian J Ophtalmol'' 6:6-9.</ref> This, together with the fact that the transport of vitamin C from the aqueous humour to the lens is rather slow in humans,<ref name="pmid9288446">{{cite journal |author=Taylor A ''et al'' |title=Vitamin C in human and guinea pig aqueous, lens and plasma in relation to intake |journal=Curr Eye Res |volume=16  |pages=857–64 |year=1997 |pmid=9288446 |doi=}}</ref> indicates that the lens is a tissue that needs high intakes of vitamin C.


In the [[1960s]] [[Nobel Prize|Nobel-Prize]] winning chemist Linus Pauling, after contact with Irwin Stone, began actively promoting vitamin C as a means to greatly improve human health and resistance to disease. His book ''How to Live Longer and Feel Better'' was a bestseller and advocated taking more than 10,000 milligrams per day. It sold widely and many advocates today see its influence as the reason there was a marked downward trend in US [[heart disease]] from the early [[1980s]] onwards.
=== Obstetrics and gynaecology ===


Stone's work also informed the practise of Dr. [[Robert Cathcart|Robert F. Cathcart III]], in the [[1970s]] and [[1980s]]. He applied extremely large doses of ascorbate (300 grams = 0.66 pounds per day) to a wide range of viral diseases with successful results. Cathcart developed the concept of [[Bowel tolerance]], the use of the onset of [[diarrhea]] as an indication of when the body's true requirement of ascorbic acid had been reached. He found that seriously ill people could often tolerate levels of tens of grams per day before their tolerance limit is reached.
Recent studies into the use of a combination of [[Vitamin E]] ("natural" ''source isomer moiety, d-alpha tocopheryl'' ester) and vitamin C in preventing oxidative stress leading to [[pre-eclampsia]] failed to show significant benefit at the dosage tested, <ref>{{cite journal | author=Rumbold A ''et al.'' | title=Vitamins C and E and the risks of preeclampsia and perinatal complications. | journal=N Engl J Med | volume=354 | pages=1796-806 | year=2006|id=PMID 16641396}}</ref> In another study the same dosage did decrease average gestational time resulting in a higher incidence of [[Birth weight|low birthweight]] babies in one study.<ref>{{cite journal | author=Poston L ''et al.'' | title=Vitamin C and vitamin E in pregnant women at risk for pre-eclampsia (VIP trial): randomised placebo-controlled trial. | journal=Lancet | volume=367  | pages=1145–54 | year=2006 | id=PMID 16616557}}</ref> Studies into antioxidants for pre-eclampsia are continuing.<ref>Rumbold A ''et al.'' [http://www.cochrane.org/reviews/en/ab004227.html Antioxidants for preventing pre-eclampsia], The Cochrane Database of Systematic Reviews, 2006 Issue 4</ref>


[[Matthias Rath]] is a controversial German physician who once worked with Pauling. He is an active proponent and publicist for high dose vitamin C. He has published a theory that deaths from scurvy in humans during the ice age, when vitamin C was scarce, selected for individuals who could repair arteries with a layer of [[cholesterol]]. He theorises that, although eventually harmful, cholesterol lining of artery walls would be beneficial in that it would keep the individual alive until access to vitamin C allowed arterial damage to be repaired. [[Atherosclerosis]] is thus a vitamin C deficiency disease. Rath has also argued publicly that high doses of vitamin C can be effectively used against viral epidemics such as [[HIV]]<ref> [http://allafrica.com/stories/200605220885.html Nigeria: Vitamin C Can Suppress HIV/Aids Virus] all Africa.com 22 May 2006, accessed 16 June 2006 </ref>, [[SARS]] and [[bird flu]]<ref> [http://www.guardian.co.uk/aids/story/0,7369,1483821,00.html Discredited doctor's 'cure' for Aids ignites life-and-death struggle in South Africa] Saturday May 14, 2005 [[The Guardian]] </ref><ref> [http://www4.dr-rath-foundation.org/THE_FOUNDATION/openletter_20060407.htm Open letter from Dr. Matthias Rath MD to German Chancellor Merkel] Rath's own website 2005, downloaded June 2006 </ref>.
== Side effects and contraindications==
'''Contraindications'''
A [[Contraindication]] is a condition which makes an individual more likely to be harmed by a dose of vitamin C than an average person.


It has been suggested by some advocates that ascorbic acid is really a [[food group]] in its own right like [[carbohydrate]]s or [[protein]] and should not be seen as a pharmaceutical or vitamin at all. {Irwin Stone: "The Healing Factor"}
* A primary concern is people with unusual or unaddressed iron overload conditions, including [[hemochromatosis]]. Vitamin C enhances iron absorption. If sufferers of iron overload conditions take gram sized doses of vitamin C, they may worsen the iron overload due to enhanced iron absorption.


=== Chronic scurvy ===
* Inadequate [[Glucose-6-phosphate dehydrogenase]] enzyme (G6PD) levels, a genetic condition, may predispose some individuals to [[hemolytic anemia]] after intake of specific oxidizing substances present in some food and drugs. This includes repeated, very large intravenous or oral dosages of vitamin C. There is a test available for G6PD deficiency [http://brightspot.org/cresearch/intravenousc2.shtml].  
Nobel laureate chemist Linus Pauling stated that "chronic scurvy" or "subclinical scurvy" is a condition of vitamin C deficiency which is not as easily noticeable as acute scurvy (because chronic scurvy is mostly internal), characterized by micro lesions of tissues (such as that caused by blood pulsing through arteries, which stretches the arterial walls causing them to tear slightly). It is a major contributing factor to cardiovascular disease.  Pauling stated that this condition is almost entirely preventable with supplementation of larger doses of vitamin C (8 grams or more per day). Chronic scurvy is believed by high-dose advocates to be commonplace, even in industrialized countries.


== Politics of vitamin C ==
'''Side-effects'''
=== Regulation ===
* Vitamin C causes [[diarrhea]] if taken in quantities beyond a certain limit, which varies by individual. The diarrhea will cease as soon as the dose is reduced.
There are regulations in most countries which limit the claims on the treatment of disease that can be placed on food, drug, and nutrient product labels. Regulations include:
*Claims of therapeutic effect with respect to the treatment of any medical condition or disease are prohibited by the Food and Drug Administration (in the USA, and by the corresponding regulatory agencies in other countries) unless the substance has gone through a lengthy (10+ years) and expensive (200 million US dollars+) approval process, for which the applicant seeking approval must pay.
*In the United States, the following notice is mandatory on food, drug, and nutrient product labels which make health claims: ''These statements have not been evaluated by the Food and Drug Administration. This product is not intended to diagnose, treat, cure or prevent any disease.''  This statement must be included even if substantial scientific evidence exists showing that the message isn't true.  This may lead consumers to the false belief that vitamin C has no value in preventing or treating diseases other than scurvy (for which treatment claims are allowed).


=== Advocacy arguments ===
* Large doses of vitamin C may cause acid indigestion, particularly when taken on an empty stomach. 
Vitamin C advocates argue that there is a large body of scientific evidence that the vitamin has a wide range of health and therapeutic benefits but which they claim have been ignored. They claim the following factors affect the marketing and distribution of vitamin C, and the dissemination of information concerning the nutrient:


*There is increasing evidence of the applications and efficacy of vitamin C, but governmental agency dose and frequency of intake recommendations have remained relatively fixed.  This has lead some researchers to challenge the recommendations. In 2003 Steve Hickey and Hilary Roberts of the Manchester Metropolitan University published a fundamental criticism of the approach taken to fix the nutritional requirement of vitamin C. They again argued in 2004 that the RDA which is based on blood plasma and white blood cell saturation data from the [[National Institutes of Health]] (NIH) was based on flawed data.<ref name="Hickey & Hilary"> Hickey, Steve & Roberts, Hilary; (March, 2005), Ridiculous Dietary Allowance, Lulu Press, Inc. ISBN 1-4116-2221-9.''(Note: [http://www.lulu.com Lulu] is a [[print on demand]] [[self-publishing]] house.)''</ref> According to these authors, the doses required to achieve blood, tissue and body "saturation" are much larger than previously believed. They allege that the [[Institute of Medicine]] (IoM) and the NIH have failed to respond to an open letter from a number of scientists and medical researchers, notably Doctors Steve Hickey, Hilary Roberts, Ian Brighthope, Robert Cathcart, [[Abram Hoffer]], [[Archie Kalokerinos]], Tom Levy, Richard Passwater, Hugh Riordan, Andrew Saul and Patrick Holford, which called for revision of the RDI (Reference Daily Intake).
'''Toxicity'''


*Research and the treatment approval process are so expensive, pharmaceutical companies rarely apply for approval of an unpatentable product.  To do so without the protection of a patent would allow competitors to manufacture the product too, which would drive the price (and profit margin) down to a point much less desirable than the price point (and profit margin) of patentable products. The lower price would also reduce the likelihood of recuperating the company's exorbitant research funding and treatment approval costs. Vitamin C is not eligible for patenting because it is a natural substance, and because it has already been marketed to the public for some time. As of yet, no company has applied to the FDA (nor paid) for approval of vitamin C as a treatment for any disease.
Vitamin C exhibits remarkably low toxicity. For example, in a rat, the [[LD50]] (the dose that will kill 50% of a population) has been reported as 11900 mg/kg,<ref>{{cite web|url=http://physchem.ox.ac.uk/MSDS/AS/ascorbic_acid.html|title=Safety (MSDS) data for ascorbic acid}}</ref> or, for a 70 kg (155 pound) human, 833 grams of vitamin C would need to be [[ingestion|ingested]] to stand a 50% chance of killing the person.  


*Companies selling a treatment product are not required to inform consumers or patients of other treatments, even if those treatments are more effective, less expensive, and have fewer side-effects.  Medical practitioners are not required to inform their patients of treatments for which treatment approval has not been granted.  This situation, coupled with the label censorship explained above makes it more difficult to keep the public informed about the benefits of and new discoveries concerning the applications and effective dosage levels of vitamin C.
'''Harmful effects'''


*[[Matthias Rath]] and others point to low doses of vitamin C as the cause of the current epidemics of heart disease and cancer, and have termed the situation "a genocide", implying that health care providers (and particularly cardiologists and pharmaceutical companies) are aware of vitamin C's benefits and are deliberately seeking to block its acceptance as a therapeutic agent for financial gain.<ref> http://www.vitamincproject.com/ A conspiracy against vitamin C supplements has been underway for over three decades </ref> He claims that governments have also colluded in this technology blockade by their expensive and bureaucratic systems of treatment approval which place barriers to new, inexpensive but not [[patent|patentable]] approaches.
Reports of harmful effects of vitamin C tend to receive prominent media coverage. As such, these reports tend to generate much debate and more research into vitamin C. Some of the harmful effects described below were proven invalid in later studies, while other effects are still being analyzed.


== See also ==
*In April 1998, the journal ''Nature'' reported [[carcinogen]]ic and [[teratogenic]] effects of excessive doses of vitamin C. The effects were noted in test tube experiments. <ref> [http://lpi.oregonstate.edu/f-w01/cancer.html  Oregon State University - Vitamin C and cancer]</ref>
*[[Ascorbyl palmitate]]
The authors later clarified their position, stating that their results "show a definite increase in 8-oxoadenine after supplementation with vitamin C. This lesion is at least ten times less mutagenic than 8-oxoguanine, and hence our study shows an overall profound protective effect of this vitamin".<ref> [Nature; Volume 395; Page 232; 17 September 1998] </ref>
*[[Mineral ascorbates]]
*[[Nutrition]]
*[[Vitamin]]
*[[Essential fatty acid]]
*[[Essential mineral]]
*[[Exercise]]
*[[Anti-oxidant]]
*[[Life extension]]
*[[Uric acid]]


== Sources ==
*In April 2000, [[University of Southern California]] researchers reported a thickening of the arteries of the neck in persons taking high vitamin C doses. (ref.<ref name="fn_6">[http://www.vitamincfoundation.org/faq.htm FAQ] provided by The Vitamin C Foundation.</ref> para 10)
* Pauling, Linus (1986) ''[[How to Live Longer and Feel Better]]'' W. H. Freeman and Company, ISBN 0-380-70289-4
* {{cite book | author = Levy Thomas | title = Vitamin C, Infectious Diseases, and Toxins | edition = | publisher = Xlibris Corporation (Paperback) | year = 2002 | id = ISBN 1-4010-6963-0 }}(Note:  [http://www.xlibris.com Xlibris] is a [[print on demand]] [[self-publishing]] house.)''
* Hickey, Steve; Roberts, Hilary (May, 2004) ''Ascorbate: The Science of Vitamin C'', Lulu Press, Inc. ISBN 1-4116-0724-4 ''(Note: [http://www.lulu.com Lulu] is a [[print on demand]] [[self-publishing]] house.)''


== References ==
*A speculated increased risk of [[kidney stone]]s may be a side effect of taking vitamin C in larger than normal amounts (>1 g). The potential mechanism of action is through the [[metabolism]] of vitamin C ([[ascorbic acid]]) to [[dehydroascorbic acid]], which is then metabolized to [[oxalic acid]],<ref>Hokama S ''et al.'' (2000) [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=11156698&dopt=Abstract Ascorbate conversion to oxalate in alkaline milieu and Proteus mirabilis culture.] ''Mol Urol'' 4:321–8.
<references/>
Massey LK ''et al.'' (2005) [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=15987848&query_hl=11  Ascorbate increases human oxaluria and kidney stone risk] ''J Nutr'' 135:1673–7.</ref> a known constituent of kidney stones. 


Dolske, M.C., et al. 1993. "A preliminary trial of ascorbic acid as a supplemental therapy for autism." Prog. Neuropsychopharmacol. Biol. Psychiatry, 17(5):765–774.
* "Rebound scurvy" is a theoretical condition that could occur when daily intake of vitamin C is rapidly reduced from a very large amount to a relatively low amount. Advocates suggest this is an exaggeration of the ''rebound effect'' which occurs because ascorbate-dependent enzyme reactions continue for 24–48 hours after intake is lowered, and use up vitamin C which is not being replenished. The effect is to lower one's serum vitamin C blood concentration to less than normal for a short amount of time. During this period of time there is a slight risk of cold or flu infection through reduced resistance. Within a couple of days the enzyme reactions shut down and blood serum returns to the normal level of someone not taking large supplements. This is not scurvy, which takes weeks of zero vitamin C consumption to produce symptoms. It is something people who take large vitamin C supplements need to be aware of in order to gradually reduce dosage rather than quit taking vitamin C suddenly.  


Green, V.A., K.A. Pituch, J. Itchon, A. Choi, M. O'Reilly, J. Sigafoos, "Internet survey of treatments used by parents of children with autism," Res Dev Disabil, 2006, 27(1):70–84.
*Some writers<ref>[http://www.acu-cell.com/vitc.html acu-cell]</ref> have identified a theoretical risk of poor [[copper]] absorption from high doses of vitamin C. However, [[ceruloplasmin]] levels seem specifically lowered by high vitamin C intake. In one study, 600 mg of vitamin C daily did not decrease copper absorption or overall body copper status in young men, but led to lower [[ceruloplasmin]] levels similar to those caused by copper deficiency.<ref>[http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=3694287&query_hl=11 NCBI]</ref> In another, ceruloplasmin levels were significantly reduced.<ref>[http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=6837490&dopt=Abstract NCBI]</ref>


== Books ==
'''Conflicts with prescription drugs'''
*''[[Cancer and Vitamin C]]'', [[Ewan Cameron (Vitamin C)|Ewan Cameron]] and [[Linus Pauling]], [[Pauling Institute of Science and Medicine]], 1979
*''[[The Healing Factor: Vitamin C Against Disease]]'', [[Irwin Stone]], Grosset and Dunlap
*''[[How to Live Longer and Feel Better]]'', Linus Pauling, W.H. Freeman and Company, 1986, ISBN 0-380-70289-4
*''[[Life Extension: A Practical Scientific Approach]]'' '''''(Part IV, Chapter 7: Vitamin C)''''', [[Durk Pearson]] and [[Sandy Shaw]], Warner Books, 1982
*''[[Life Extension Revolution]]'', [[Saul Kent]], Morrow, 1980
*''[[Mind Food and Smart Pills|Mind Food and Smart Pills: How to Increase Your Intelligence and Prevent Brain Aging]]'' '''''(Chapter 3: Vitamin C, The Champion Free Radical Scavenger)''''', Ross Pelton, 1986
*''[[Vitamin C and the Common Cold]]'', Linus Pauling, 1970
*''[[Vitamin C, the Common Cold, and the Flu]]'', Linus Pauling, Freeman, 1976
*''Vitamin C'', Volumes I, II, III., Monograph by C.A.B Clemetson, 1989 CRC Press, Boca Raton, Florida, ISBN 0-8493-4841-2


== External links ==
Pharmaceuticals designed to reduce stomach acid such as the [[proton pump inhibitor]]s (PPIs), are among the most widely-sold drugs in the world. One PPI, [[omeprazole]], lowers the bioavailability of vitamin C by 12%, independent of dietary intake. This means that one would have to consume 14% more vitamin C to counteract the use of 40 mg/day of omeprazole. The probable mechanism of vitamin C reduction, intragastric pH elevated into alkalinity, would apply to all other PPI drugs, though not necessarily to doses of PPIs low enough to keep the stomach slightly acidic. <ref>[http://www.blackwell-synergy.com/doi/abs/10.1111/j.1365-2036.2005.02568.x?cookieSet=1&journalCode=apt E. B. Henry, and others ''Proton pump inhibitors reduce the bioavailability of dietary vitamin C''] "The gastric juice concentration of vitamin C is reduced in subjects with elevated intragastric pH. This is probably because of the fact that the vitamin is unstable at non-acidic pH and undergoes irreversible denaturation.<br>
* [http://www.seanet.com/~alexs/ascorbate/ AscorbateWeb] "An historical review of the medical & scientific literature attesting to the efficacy of Ascorbate (Ascorbic Acid, Cevitamic Acid, Sodium Ascorbate etc. a.k.a. “Vitamin C”) in the treatment and prevention of human and animal ills, conditions and diseases."
.... After 28 days of 40 mg/day of omeprazole the mean plasma vitamin C level had fallen by 12.3% (P = 0.04)." Alimentary Pharmacology & Therapeutics Volume 22 Page 539 - September 2005 doi:10.1111/j.1365-2036.2005.02568.x  Accessed Nov 2006 </ref>
* [http://www.seanet.com/~alexs/ascorbate/198x/smith-lh-clinical_guide_1988.htm Clinical Guide to the Use of Vitamin C], The Clinical Experiences of [[Fred R. Klenner|Frederick R. Klenner]], M.D., abbreviated, sumarized and annotated by Lendon H. Smith, M.D.
* [http://www.HealingThresholds.com/ Healing Thresholds] - Summaries of research on Vitamin C and other autism therapies]
* [http://patft.uspto.gov/netacgi/nph-Parser?Sect1=PTO1&Sect2=HITOFF&d=PALL&p=1&u=%2Fnetahtml%2FPTO%2Fsrchnum.htm&r=1&f=G&l=50&s1=5278189.PN.&OS=PN/5278189&RS=PN/5278189 Cure for heart disease (United States Patent 5,278,189)] ''Prevention and treatment of occlusive cardiovascular disease with ascorbate and substances that inhibit the binding of lipoprotein (A), Inventors: [[Matthias W. Rath]] and [[Linus Pauling|Linus C. Pauling]]
* [http://vitamincfoundation.org/stone/ The Healing Factor: Vitamin C Against Disease] By [[Irwin Stone]]
* [http://microscopy.fsu.edu/vitamins/pages/vitaminc.html Microscope photographs of Vitamin C cystals.] from Florida State University
* [http://www.naturalhub.com/natural_food_guide_fruit_vitamin_c.htm Natural food-Fruit Vitamin C Content]
* [http://www.eatwell.gov.uk/healthydiet/nutritionessentials/vitaminsandminerals/vitaminc/ United Kingdom Foods Standards Agency] Official UK view on vitamin C.
* [http://www.vitamincfoundation.org The Vitamin C Foundation] Vitamin C high dosage advocacy organisation with links to research supporting their view.
* [http://www.nutritionj.com/content/2/1/7 Vitamin C in human health and disease is still a mystery? An overview] among all time most-viewed articles published by BioMed Central (free access)
* [http://health.dailynewscentral.com/content/view/1153/ Vitamin C May Not Have Much Effect on Colds] health.dailynewscentral.com Finding that 200 mg per day has little effect on colds but a single dose of 8 grams does.
* [http://www.acu-cell.com/vitc.html Vitamin C Requirements: Optimal Health Benefits vs Overdose] A moderately high dose advocacy supporting site.
* [http://ptcl.chem.ox.ac.uk/MSDS/AS/ascorbic_acid.html Vitamin C toxicity data at University of Oxford]


* [http://ascorbateandcancer.org/ Ascorbate and cancer] Discussion of both historical and current uses of Vitamin C in cancer treatment
==References==
* [http://www.doctoryourself.com/vitciv.html For Doctors: Preparation of Vitamin C IV's]—information gathered and presented by Andrew W. Saul, PhD.
{{reflist|2}}
* [http://vitamincfoundation.org/stone/ The Healing Factor: Vitamin C Against Disease] By [[Irwin Stone]] 1972 ISBN 0-399-50764-7
* [http://www.orthomed.com/bird.htm Information regarding treatment of the Bird Flu with massive doses of ascorbate.] by [[Robert Cathcart|ROBERT F. CATHCART III]], M.D.


[[Category:Chemistry Workgroup]]
[[Category:Suggestion Bot Tag]]
[[Category:Biology Workgroup]]
[[Category:Health Sciences Workgroup]]

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Vitamin C is a water-soluble vitamin required by several mammalian species, including humans and higher primates, who mainly get it by eating fresh fruits and vegetables. It has many physiological effects and, at present, eight different well characterized roles, but it is not specifically required for any enzyme.[1] As research advances, it appears that its first name, ignose, meaning "I don't know", or "godnose," describes it best.[2]

Vitamin C
This article is about the biochemistry of vitamin C, or ascorbic acid. For the chemical properties, see Ascorbic acid.

First known as the vitamin that prevents scurvy (hence its chemical name, ascorbic acid), vitamin C is an important factor in * the maintenance of good health. Vitamin C is:

  • the most widely sold dietary supplement in the world;
  • required for the maintenance of the most abundant protein in the body,
  • the most "luminously controversial of all biological, alternative cancer therapies",[3]
  • the vitamin which intake has declined the most drastically in the course of human evolution, and
  • the vitamin which requirements have been debated for the most time and with the most intensity.

This article describes the debates about vitamin C, and presents the state-of-the-art in vitamin C therapeutics and the context in which knowledge on this nutrient has been produced.

Description

The evolution of vertebrates can be viewed as the history of how they responded to the "the call for oxygen"[4] -- for "the fire of life".[5] Most important is the need to use this fire without being "burnt" by it.[6] The development of antioxidant machineries is closely intertwined with the development of species. An analysis of the evolutionary record suggests that the aquatic animals that were ancestors of amphibians did not significantly increase their concentrations of superoxide dismutase (SOD), the first line of defense against oxygen toxicity, instead, to cope with the sharp, 30-fold, increase in oxygen exposure, they developed a machinery to transform glucose into ascorbic acid.[7] The further evolution from reptiles to mammals was marked by a gradual increase in GULO, the fourth and last step in the vitamin C-producing machinery, and of SOD. In reptiles, about 9.4 mg/kg body weight of ascorbate is produced each day, whereas 184.2 mg/kg is produced each day in mammals (9.2 g for a 50 kg mammal).[8] Nonetheless, SOD tended to be favoured to the expense of GULO.

In exceptional cases, a complete loss of vitamin C production occurred during evolution: Old World higher primates do without endogenous vitamin C, and express roughly twice as much SOD as other mammals. Amongst those species, humans have the best SOD defense.[7] It is thought that the loss of the ability to produce vitamin C occurred some 25 to 45 million years ago, when the natural environment of the common ancestor of primates was abundant in vitamin C.[9] Higher primates, who still live in vitamin-C rich environments, consume 2000 to 6000 mg of vitamin C per day,[10] much more than the recommended doses for modern man, which are at least 20 times lower.

According to the Online Mendeleian Inheritance in Man database, hypoascorbemia is a "public" inborn error of metabolism, as it affects all members of the human race.[9]

Vitamin C (chemical names ascorbic acid and ascorbate) is produced from glucose in the liver of most mammals and in the kidneys of most birds and reptiles. Mammals that are unable to synthesize vitamin C include humans and other primates, guinea pigs, Indian fruit bats, rainbow trouts and Nepalese red-vented bulbols. As usually defined, a vitamin is a nutrient present in the diet that is required in small amounts for normal health; because most vertebrate species produce it in large amounts, it cannot be considered as a vitamin in these species, but a dietary intake of small amounts of vitamin C is indeed required for normal health in humans. By contrast, other vitamins are indeed required in small amounts in the diet by most mammals, including humans. Vitamin C is present in foods (particularly plants) at much higher concentrations than any other vitamin (by several orders of magnitude; from 10 to 100 mg/100g).[11]

Vitamin C (Ascorbic acid)
General
Chemical formula C6H8O6
Molecular weight 176.13 g/mol
Vitamin properties
Solubility Water
RDA (adult male) 90 mg/day (US)
RDA (adult female) 75 mg/day (US)
Tolerable Upper Intake Level (UL) (adult male) 10000 mg/day
Tolerable Upper Intake Level (UL)t (adult female) 10000 mg/day
Deficiency symptoms
Excess symptoms
Common sources

Role as enzyme cofactor

Vitamin C is an electron donor (reducing agent, or antioxidant), and in this role it is required by several enzymes, including eight in humans. These eight enzymes are either iron-dependent dioxygenases or copper-dependent monooxygenases, which catalyze the incorporation of oxygen into organic substrates. Many other dioxygenases and monooxygenases probably use ascorbate as a co-substrate to reduce iron or copper, oxygen, and 2-oxo-glutarate, a Krebs cycle intermediate, in the case of dioxygenases.[12][11] It is at present difficult, for this reason, to characterize this pleiotropic molecule. Three of these enzymes are involved in collagen hydroxylation, and two in carnitine synthesis.

Collagen is the most abundant protein in the human body. The key enzyme in collagen synthesis is prolyl-4-hydroxylase (P4H). It consumes a large part of the whole vitamin C pool, and, conversely, its rate of activity reflects vitamin C availability in cells. The role of vitamin C in animal physiology and disease cannot be explored independently from collagen's role. (IN PROGRESS: DEVELOP COLLAGEN ARTICLE IN PARALLEL)

More recently, a new form of the dioxygenase P4H was discovered. As opposed to the collagen P4H, the hypoxia-inducible factor-α P4H (HIFα-P4H), does not bind and transform the prolines from collagen, but prolines on sites (or residues) of proteins with a certain sequence of amino acids[13] It is required for the regulation of hypoxia-inducible factor, a protein that functions as an oxygen sensor[14] and a physiological defense against cancer formation.[15][16]

Tyrosine hydroxylase is rate limiting in the synthesis of all catecholamines (dopamine, epinephrine (aka adrenaline), norepineprine, (aka noradrenaline).[12] Norepinephrine is a neurotransmitter in the central nervous system involved in many different functions, and is released into the blood as a hormone from the adrenal medulla.

Carnitine is the molecule that allows most fat molecules to be carried in the mitochondria where they will be transformed into energy. Carnitine is also required to carry excess organic acids out of mitochondria, where they would otherwise impair energy production. The metabolic pathway that leads from the amino acid lysine to carnitine requires vitamin C twice. The steps are the enzymes gamma-butyrobetaine hydroxylase and epsilon-N-trimethyl-lysine hydroxylase. Low vitamin C causes a decreases in carnitine production, which contributes to fat deposition and overweight. At present, whether low levels of vitamin C might contribute to obesity is not known, but the normalisation of vitamin C levels in people with low vitamin C status was shown to raise their ability to burn fat 4-fold during submaximal exercise.[17]

Antioxidant functions

(in progress)

Vitamin C is also a major water phase low-molecular weight antioxidant.

In oxidation process the molecule of vitamin C step by step oxidazed with built up some active prooxidant substances. [18].

Action on receptors

At physiological concentrations, Vitamin C interacts with some receptors in a manner that should be distinguished from its antioxidant effects. Vitamin C binds to (and inhibits) the NMDA receptor - an important receptor for the neurotransmitter glutamate[19][20]. It also binds to (and enhances signalling through) adrenergic receptors[21] and some histamine receptors.[22] Interestingly, considering the widespread expression of histamine and adrenergic receptors, by binding vitamin C they might be important in protecting it from oxidation.[22] In this case, the receptors and the antioxidant could be said to have a privileged relationship in which they enhance each other's specific function. For the NMDA receptor, the status of vitamin C might be relatively privileged as well. The NMDA receptor is involved in memory and learning, as well as anxiety, epilepsy, and neurodegeneration, and signalling though it is enhanced when it is reduced (not oxidized) at the so-called NMDA redox site.[23] However, somewhat paradoxically, signalling through the NMDA receptor is inhibited, notably, by the antioxidant ascorbate.[20] In comparison, lipoic acid and glutathione, in their reduced forms, enhance receptor function and may be involved in vivo in epileptogenesis, while their oxidized forms act oppositely.[23] The inhibitory binding of ascorbate, hydroquinone and the redox cofactor pyrroloquinoline quinone, are abolished if the NMDA receptor redox site is oxidized into a disulfide.[23]

Biosynthesis

Yeasts do not synthesize vitamin C, but produce another antioxidant, erythorbic acid.[24] However, metabolic engineering of yeasts such as Saccharomyces cerevisiae can be used for the industrial production of vitamin C.[25]

Plants, humans' main source of vitamin C, produce it in large amounts as a defense against viruses, bacteria and other environmental challenges and to cope with the internal challenges associated with photosynthesis.[26]

In animals, vitamin C is synthesised through four enzyme-driven steps, which convert glucose to ascorbic acid. The last enzyme in the process, l-gulonolactone oxidase, cannot be made by humans because the gene for this enzyme is defective (Pseudogene ΨGULO). The loss of an enzyme concerned with ascorbic acid synthesis has occurred quite frequently in evolution and has affected most fish; many birds; some bats; guinea pigs; and most primates, including humans. The mutations have not been lethal because ascorbic acid is so prevalent in the environment.

In addition to those species who lost vitamin C synthesis during evolution, it is worth mentioning the Shionogi rat, which is used in laboratories (much like the guinea pig) to study the inability to produce vitamin C and its consequences.

The ODS rat

The newly developed model of hypoascorbemia, the Osteogenic Disorder Shionogi rat (ODS rat), provides a unique occasion to analyze the early adaptative changes occurring when a species loses endogenous vitamin C synthesis. Contrary to the long-held belief that the high vitamin C intake of early anthropoideans was alone sufficient to compensate for the mutation,[9] ODS rats compensate this metabolic disease through several different mechanisms, some of which are not well characterized yet.

Is uric acid an antioxidant for vitamin C?

It was noted in 1970 that the inability of higher primates to break down uric acid, due to a mutation in the enzyme uricase, parallels the well-known metabolic disease of higher primates.[27] Uric acid and ascorbate are both strong reducing agents (electron-donors): uric acid scavenges oxygen radicals, singlet oxygen, oxo-haem oxidants and hydroperoxyl radicals. In addition, uric acid can form complexes with iron and inhibit the oxidation of lipids and vitamin C by the Fe3+ ion. Uric acid concentrations are so high in human plasma that they almost reach saturation; they are 5 to 10 times higher than those of vitamin C and several orders of magnitude higher than the concentrations of the potentially deleterious ion.[28]

The hypothesis by Proctor that uric acid has taken over some of the functions of ascorbic acid received experimental support thirty years later, when it was shown that ODS rats spontaneously develop high plasma uric acid (without the help of a mutation in the uricase gene), amongst many other compensatory mechanisms. In further support of this hypothesis, uric acid was shown to protect different superoxide dismutases against peroxide-mediated inactivation.[29][30] Hence, uric acid further improves the expression of SODs, that already tend to greater expression with the evolution of heavier animals.

Overall, one fundamental component of the multifaceted antioxidant protection afforded by uric acid is the formation of complexes with iron. The University of Southern California group who studied extensively the relative role of uric acid in humans, recall: "During the course of our studies we found that urate was able to inhibit a number of oxidative reactions without itself being consumed. This observation deviated from the classical mechanism for antioxidant action and was characteristically seen in radical reactions involving redox active metals, such as iron."[31] Any antioxidant molecule that can perform this function without being used up in the process is advantageous. Uric acid is strongly correlated with cardiovascular events as well as mortality in type 2 diabetes.[32] Future intervention studies will allow to tell if the rise in uric acid is pathogenic or, on the contrary, adaptative and if so, whether it behaves as an "antioxidant for ascorbate," by protecting it from iron-mediated oxidation.

Linus Pauling specified that the machinery for producing vitamin C was a burden that handicapped vitamin C-synthesizing individuals. In times of stress, the synthesis of vitamin C from glycogen can raise sharply: an adult goat, who manufactures more than 13,000 mg of vitamin C per day in normal health, will produce as much as 100,000 mg daily when faced with life-threatening disease, trauma or stress.[33]

When vitamin C-synthesizing species are exposed to high dietary levels of vitamin C, vitamin C concentrations decrease disproportionately in various organs, suggesting that endogenous synthesis of the vitamin is downregulated (it responds by decreasing) and/or that catabolism (destruction) or elimination of the vitamin are increased.[34] Whether this "overreaction", in an environment providing large amounts of vitamin C, contributed to the selection of individuals with low or absent vitamin C synthesis is an open question.

Another possible compensatory mechanism is the synthesis of lipoprotein(a). Lipoprotein(a), which is almost exclusively present in primates, might strengthen the extracellular matrix and compensate to some extent the relative lack of collagen and elastin synthesis. In addition, evidence suggests that, in some circumstances, lp(a), like vitamin C, delays lipid oxidation (peroxidation).[35]

Amongst higher primates, those who became omnivores (humans, chimpanzees, and orangutans, but not gorillas) apparently developed ways to cope with periods of vitamin C shortages. In these species, alterations in osteocalcin vitamin C-dependent hydroxylation appear to be responses to a "selective pressure to limit hydroxylation."[36]

Transport

Vitamin C, being water soluble, does not cross lipid-rich membranes easily: it must follow specific paths through plasma membranes to enter and leave cells. It is thus important to understand the transport of vitamin C in the various cells of the body to comprehend its role in health and disease. Another molecule must also be taken into account: dehydroascorbic acid (DHAA; vitamin C which has undergone oxidation).

Active transport requires energy. Two transporters with extreme specificity for vitamin C, sodium-dependent vitamin C transporters 1 and 2 (SVCT1 and SVCT2) have been characterized. Recently, the sodium dependence of SVCT2 has been questioned. It appears that at least this transporter subtype is calcium/magnesium dependent.[37] Intracellular and extracellular concentrations of both divalent ions thus condition the transport of vitamin C through these transporters. The presence of sodium at a certain threshold makes SVCT2 more efficient: vitamin C and sodium work cooperatively to achieve a high rate of transport of both molecules. The SVCTs have limited capacities, as they tend to decrease in number the more vitamin C is accumulated in cells, and with increasing concentrations of the vitamin in circulation.[38] SVCT1 is mostly found in the liver and the kidneys (worthy of note, these are the two sites for vitamin C synthesis in the animal kingdom); SVCT2 dominates in the brain, skeletal muscles, and the spleen.

A lesser known, but important, mode of transport of vitamin C is exocytosis. In this process, vesicles filled with vitamin C are secreted from cells, allowing vitamin C to influence neighboring cells. This secretion appears to be coordinated with the secretion of biologically active polypeptides from various glands, notably the pituitary gland; the metabolism of those polypeptides requires vitamin C as a cofactor (peptidyl-glycine α-amidating mono-oxygenase, vitamin C-requiring).[39]

Facilitated diffusion is the process whereby molecules move from a compartment where there is more of the molecule to a compartment where there is less of it. Facilitated diffusion lets DHAA (but not vitamin C) enter cells, and lets vitamin C (but not DHAA) leave cells. The latter process is less understood than the former, but is essential in cells which deliver and keep vitamin C in the blood, i.e. the enterocytes (intestinal cells) and renal tubular cells (kidney cells). Once DHAA has entered a cell, it is recycled back to vitamin C.

The fact that glucose transporters also transport the glucose derivative DHAA explains a paradoxical finding made my James Lind in his Treatise of the Scurvy:

(Victims of scurvy had) ravaged bodies (but) what was very surprising, the brains of those poor creatures were always sound and entire (...)[40]

It thus appears that the glucose transporters, by transporting oxidized vitamin C, allow organs to quickly store vitamin C at times of increased oxidative stress.[41] Once dehydroascorbic acid has crossed the blood-brain barrier and is in the brain, it is recycled (reduced) back to vitamin C, and retained in this compartment.[41] Conversely, conditions associated with low insulin, insulin resistance, high glucose and/or inflammation (diabetes, type 1 and 2, trauma, sepsis) impact on DHAA uptake and intracellular vitamin C status (also see Therapeutic uses). Adipocytes, astrocytes, endothelial cells, erythrocytes, granulosa cells, hepatocytes, neutrophils, osteoblasts and smooth muscle cells accumulate DHAA for the accumulation of vitamin C.

(in progress:) The pro-inflammatory shift seen in vitamin C deficient species (see The Shionogi rat) may enhance the compensatory transport and recycling of vitamin C, as shown in a mouse model of sublethal endotoxin exposure (in which GULO, the final step in vitamin C biosynthesis, was inhibited).[42]

Distribution

In the blood

Vitamin C concentrations in the blood are usually between 10 and 160 micromol/L,[43] and seldom exceed 80 micromol/L after most meals[44] Oral supplementation can raise levels to 220 micromol/L, while intravenous infusion can raise concentrations to 13 400 micromol/L.[45]

Leukocytes (white blood cells) use oxidants to destroy microbes.[46]; they can tolerate high levels of oxidative stress and have transport systems that allow large amounts of vitamin C to be mobilized quickly (concentrations of the vitamin can reach 50 times those found in the blood).[47] Although lymphocytes are used to evaluate the body's need for vitamin C, they are not especially representative of the needs of organs and tissues.

In urine and feces

Determining the concentrations of vitamin C in urine and feces allows for a basic evaluation of the amounts that were absorbed by the body. However, vitamin C-synthecizing species continually excrete vitamin C in their urine. The mere urinary excretion of vitamin is a normal part of its metabolism and not a sign of excess consumption, and the relationship between the intake of the vitamin and its excretion varies widely.

In organs and tissues

Some glands, organs and tissues contain 100 times more vitamin C than the blood, including the adrenal glands, pituitary gland, thymus, retina, corpus luteum, and various types of neurons.[43]

High concentrations of vitamin C are required for the adequate synthesis of catecholamines and steroids in the adrenal gland (adrenal cortex and adrenal medulla).[48] In response to stress, the adrenals secrete vitamin C locally, creating high concentrations that act at the adrenal gland in a paracrine manner.[44]

In the ovaries, the corpus luteum produces the steroid hormone progesterone, which is particularly important for maintaining pregnancy. Different enzymes involved in progesterone synthesis are enhanced by vitamin C at concentrations of 100 micromol/L (in the higher nutritional range).[49] Also see Therapeutic uses - Pregnancy. Conversely, prostaglandin PGF2 alpha, which is important for the initiation of parturition at the end of a normal pregnancy, increases the secretion of vitamin C by the corpus luteum.[50]

The brain contains on average 10 times more vitamin C than the blood, and species that are exceptionally tolerant to oxygen deprivation concentrate even higher amounts of vitamin C.[51] In animal models of diabetes, where blood glucose levels are abnormally high, a drastic inhibition of vitamin C transport to the brain (through its oxidized form) is observed.[52]

The retina, like the brain, accumulates high concentrations of vitamin C using GLUT1 glucose transporters, on the blood-retinal barrier. An experimental model of diabetes showed vitamin C concentrations in the retina to be drastically reduced by the high concentrations of glucose seen in diabetes, as a result of the competition of glucose with dehydroascorbic acid for entry in the retina (in this study, the transport of DHA was decreased by two thirds).[52]

Food sources

The richest natural sources are fruits and vegetables, and of those, the camu camu fruit , the billygoat plum and the Indian gooseberry or amla (Emblica officinalis) contain the highest concentration of the vitamin (about 30 times more than oranges). Vitamin C is the most widely taken nutritional supplement.

Plants

There is an enormous difference in vitamin C content between cultivated fruits and fruits found in the wild, especially those that Human's ancestors consumed when they got rid of endogenous capacity. Amongst fruits commonly found on the market, citrus fruits and small fruits (such as strawberries or blueberries) are relatively good sources of vitamin C. The amount of vitamin C in foods of plant origin depends on the variety of the plant, the soil condition and the climate in which it grew, the length of time since it was picked and the storage conditions, and the method of preparation. Cooking in particular is often said to destroy vitamin C — but see Food preparation, below.

With the gradual recognition that vitamin C prevents more than the sailor's disease, and in response to the general trends in consumer demands, the biotechnological industry has realized the commercial possibilities of new, patented, plant species with an enhanced ability to make vitamin C.[53]


Animals

Some cuts of meat are sources of vitamin C for humans. The muscle and fat that make up the modern western diet are, however, poor sources. As with fruit and vegetables, cooking degrades the vitamin C content.

Vitamin C is present in mother's milk and in less amounts in raw cow's milk (but pasteurized milk contains only trace amounts of the vitamin). [54]

Food preparation

Recent observations suggest that the impact of temperature and cooking on vitamin C may have been overestimated, since it decomposes around 190–192°C, well above the boiling point of water:

  • Since it is water soluble, vitamin C will strongly leach into the cooking water, but this doesn't necessarily mean the vitamin is destroyed.
  • Contrary to what is commonly assumed, it can take much longer than 2-3 min to destroy vitamin C at boiling point.
  • Cooking doesn't leach vitamin C in all vegetables at the same rate; for instance, it has been suggested that the vitamin is not destroyed when boiling broccoli.[55] This may be a result of vitamin C leaching into the cooking water at a slower rate from this vegetable.

Consistent with the interaction of vitamin C with copper metals in physiology, pots made with alloys of this metal will destroy the vitamin.[56]

Fresh-cut fruit may not lose much of its nutrients when stored in the refrigerator for a few days.[57]

Supplements

Vitamin C is the most widely taken dietary supplement.[58] It is available in many forms including caplets, tablets, capsules, drink mix packets, in multi-vitamin formulations, in multiple anti-oxidant formulations, as chemically pure crystalline powder, time release versions, and also including bioflavonoids such as quercetin, hesperidin and rutin. Tablet and capsule sizes range from 25 mg to 1500 mg. Vitamin C (ascorbic acid) crystals are typically available in bottles containing 300 g to 1 kg of powder (a teaspoon of vitamin C crystals equals 5,000 mg). Other forms of Vitamin C as sodium ascorbate, magnesium ascorbate, calcium ascorbate, mixed mineral ascorbates (e.g. Na, K, Mg, Ca, Zn), and Ester-C are also available, though less popular.

Vitamin C-enriched teas and infusions are increasingly appearing in markets. If boiling temperatures did indeed destroy vitamin C at the rate that had previously been suggested, using such products would be nonsensical. As note above, boiling is not as potently detrimental to the integrity of the vitamin C as was previously assumed.

History

For more information, see: History of vitamin C.


Scurvy is a disease resulting from a deficiency of vitamin C that leads to spots on the skin, spongy gums, and bleeding from the mucous membranes. Those afflicted are pale, feel depressed, and are partially immobilized; in serious cases there can be open wounds and loss of teeth. Scurvy was once common among sailors, when at sea for longer than fresh fruit and vegetables could then be stored.

James Lind (1716-1794) was a Scottish doctor and a pioneer of naval hygiene. In 1747, while serving as surgeon on HMS Salisbury in the Channel Fleet, he carried out experiments to find a rational treatment for scurvy; he already knew of the benefits of lime juice; John Woodall (1556-1643) in his book The Surgeon's Mate had written of "the scurvy called in Latine Scorbutum" and noted that natural remedies included "the Lemmons, Limes, Tamarinds, Oranges, and other choices of good helps from the Indies....", but Lind did not know why these were effective or whether they were any more effective than other "remedies" of the time. He speculated that limes might be effective because of their acidity, and so in his experiment he treated two of the patients with vinegar. He chose 12 men from the ship, all suffering from scurvy, and divided them into pairs, giving each pair different additions to their basic diet - cider; seawater; a mixture of garlic, mustard and horseradish; vinegar, and oranges and lemons. Those fed citrus fruits experienced a remarkable recovery. By this test Lind had, in a carefully controlled manner, established the superiority of citrus fruits above all other 'remedies'.

Vitamin C was first isolated in 1928, and in 1932 it was shown to prevent scurvy. Both Charles Glen King at the University of Pittsburgh and Albert Szent-Györgyi (working with ex-Pittsburgh researcher Joseph Svirbely) came to discover what is now known as vitamin C around April of 1932. Although Szent-Györgyi was awarded the 1937 Nobel Prize in Medicine, many feel King is as responsible for its development. [59]

Recommended daily requirements

The Food and Nutrition Board at the Institute of Medicine advise that he best way to get the daily requirement of essential vitamins, including vitamin C, is to eat a balanced diet. A healthy diet should contain the following amounts of vitamin C:

Infants and Children

  • 0 - 6 months: 40 mg/day
  • 7 - 12 months: 50 mg/day
  • 1 - 3 years: 15 mg/day
  • 4 - 8 years: 25 mg/day
  • 9 - 13 years: 45 mg/day

Adolescents

  • Girls 14 - 18 years: 65 mg/day
  • Boys 14 - 18 years: 75 mg/day

Adults

  • Men age 19 and older: 90 mg/day
  • Women age 19 and older: 75 mg/day
  • Women who are pregnant or breastfeeding and those who smoke need higher amounts.

As emphasised above, the optimum daily dose of vitamin C has been debated for decades. There was an upward trend in the recommendations issued by public health advisory boards and a growing tendency to distinguish between vitamin C as the anti-scorbutic vitamin and vitamin C as a nutrient required to prevent or delay a range of diseases unrelated to scurvy. Most scientists now agree that scurvy is not a proper framework to study the role of this molecule in health, but the implications of the 10 to 20-fold decrease in ascorbate intake during evolution are still under scrutiny, 60 years after its discovery.

Also see evolutionary medicine and evolutionary biology

Different health advisory bodies offer different advice regarding the daily requirement for vitamin C, and the USA and Canada recommend about twice the amount that the World Health Organization (WHO)recommends.

The Linus Pauling Institute recommends more than four times the amount that the USA and Canada recommend, or ten times what the WHO recommends. However, after the death of Pauling, the Linus Pauling Institute came to diverge from Linus Pauling himself, who recommended doses in the same range as what other primates consume in the wild (also see Biosynthesis, above).


Guinea pigs UK USA WHO Linus Pauling Institute Vitamin C Foundation Linus Pauling Other primates
Daily vitamin C intake (mg) 10-30[60] 40 95 45[61] 400 3000 [62] 6000-18000 2000-6000[63]


Scurvy

Scurvy is a potentially serious condition that results from inadequate consumption of fresh fruit and vegetables, usually because of ignorance about proper nutrition, psychiatric disorders, alcoholism, or social isolation. It was once a common disease of sailors on long voyages, who had to subsist for long periods on dried beef and biscuits, and was a feature of the Irish famine in the 19th century. The symptoms of scurvy first appear only after many weeks of low intake. The first symptom is fatigue, followed by a wide variety of cutaneous symptoms, including follicular hyperkeratosis, perifollicular hemorrhages, ecchymoses, xerosis, leg edema, and bent or coiled body hairs. Scurvy is associated with generally poor wound healing. Gum abnormalities include gingival swelling, purplish discoloration, and hemorrhages. The patient with scurvy commonly reports pain in the back and joints, that is sometimes accompanied by hemorrhage into the soft tissue and joints. Anemia is a common symptom, and leukopenia an occasional symptom. Scurvy is life-threatening; syncope and sudden death may occur. However, treatment with vitamin C results in rapid, often dramatic, improvement. [2]

While Hippocrates described a case of scurvy in about 400 BCE, the cause of this disease was first clearly established by a surgeon in the British Royal Navy, James Lind, in 1747. In one of the earliest "controlled experiments", Lind gave some of the crew two oranges and one lemon per day, in addition to normal rations, while others (the control group) continued with their normal rations. The results showed that citrus fruits prevented scurvy, and Lind published his work in 1753 as his Treatise on the Scurvy.

This disease is still the basis of some recommended dietary allowances throughout the world. The studies of Krebs et al. [64] and later studies in Iowa were the first attempts to quantify vitamin C requirements, and led to the conclusion that between 6.5 and 10 mg per day is needed to prevent or cure early signs of deficiency. The Iowa studies showed that, at tissue saturation, the body contains a total of about 20 mg/kg vitamin C (about 1.5 g in total), and that vitamin C is lost at a rate of about 3% per day. Symptoms of scurvy appear when the whole body content falls below about 300 mg. In 1999,the WHO and the UK recommended 30 mg as a safeguard for most of the population.[2] RDAs have been slightly raised since.

In 1974, Linus Pauling pointed out that amounts of recommended vitamin C in the range of 45 mg per day (for adults) should be renamed Minimum Dietary Allowances to reflect the fact that they were only intended to prevent a deficiency disease.[65] Although this suggestion was not accepted by health authorities, more recent recommendations reflect the notion that vitamin C not only prevents scurvy but contributes to the attainment of the "best of health".

Based on pharmacokinetics

Some authors have argued that many studies of vitamin C are methodologically flawed, for a variety of reasons, and argue that more studies are needed to determine physiological daily requirements [66] In line with Pauling's suggestion, Levine et al. pioneered the use of pharmacokinetic studies to base recommended dietary allowances on physiological requirements.[67] This approach gave solid support to the 5 servings of fruits and vegetables a day recommandation[67][68] made by the World Health Organization.


Vitamin C intake recommendations are now set to levels necessary to attain the "best state of physical and mental health,"[69]. The international consensus is that increasing fruit and vegetable consumption is an essential part of the prevention and management of chronic diseases (cardiovascular diseases, cancer, diabetes and obesity)[70]

Based on evolutionary biology

The notion that the genome of Man has not evolved as rapidly as his methods to produce food is commonly recognized, in particular in evolutionary biology and evolutionary medicine. The thrifty gene hypothesis is an example of an evolutionary biology theory that is based on the discrepancies between genetic evolution and historical evolution.

As early as 1949, Bourne[71] pointed out the magnitude of the decrease in vitamin C intake that occurred as the human lineage left the environment in which the vitamin C machinery had been lost. Most recent data confirm the initial statements by Bourne, Stone[72] and Pauling[73] that the environment in which vitamin C production was lost provided gram amounts of vitamin C (between 2 and 6 g).[10]

Stone called hypoascorbemia, the inability to produce vitamin C, an inborn error of metabolism, comparable to lactose intolerance, for example. The Online Mendeleian Inheritance in Man database (National Center for Biotechnology Information)[9] considers this analysis to be valid, and adds that it could be called a "public inborn error of metabolism". Although the basic postulate of Stone, which was later strongly supported by Pauling, is now accepted by OMIM, the implications of the evolutionary discordance remain to be explored.

For a discussion on the latency time between the formulation of evolutionary biology hypotheses and their testing, see Older evolutionary hypotheses, in evolutionary medicine.

Therapeutic uses

Critical care

"RECENT FINDINGS: In critically ill patients and after severe burns, the rapid restoration of depleted ascorbate levels with high-dose parenteral vitamin C may reduce circulatory shock, fluid requirements and oedema. ... The rapid replenishment of ascorbate is of special clinical significance in critically ill patients who experience drastic reductions in ascorbate levels, which may be a causal factor in the development of circulatory shock. Supraphysiological levels of ascorbate, which can only be achieved by the parenteral and not by the oral administration of vitamin C, may facilitate the restoration of vascular function in the critically ill patient."[74]

Post-operative complications

A reduction of plasma ascorbic acid concentration in the post-operative period has been well documented and is associated with an increase in post-operative complications ... Doses of approximately 1150 mg ascorbic acid would be necessary to compensate for the observed loss and to raise plasma ascorbic acid to high normal values. CONCLUSIONS: There is a significantly increased post-operative metabolic clearance of ascorbic acid that might be considered when framing future dose recommendations in post-operative patients.[75]

Anemia

The present study also demonstrated that for populations receiving an abundant supply of non-heme iron, it is possible to control anemia in a simple, safe, and inexpensive manner by adding ascorbic acid to drinking water.[76]

Viral diseases

Vitamin C has a very interesting therapeutic index in viral infections, and has been claimed to be effective against a very broad variety of viruses, including herpes simplex, vaccinia, rabies, herpes zoster (shingles), measles , influenza, foot-and-mouth, hepatitis, HIV, polio virus and so forth [77].

Vitamin C acts in conjunction with copper (and perhaps other transition metals such as iron) and oxygen to produce hydroxyl radicals, which are the most toxic free radicals.[78] As emphacized above (see Description -- Antioxidant properties of vitamin C), most of the enzymatic and non-enzymatic effects of vitamin C are due to its antioxidant properties, and in particular to its ability to reduce iron and copper. In viruses, transition metal chemistry is not regulated in the same way as in mammalian cells. Concentrations of vitamin C that will lead to viral DNA damage (through copper reduction and subsequent generation of hydroxyl radical from hydrogen peroxide) can be attained in the body through supplementation.[79]


(WP content under revision: Ascorbate usage in studies of up to several grams per day, have been associated with decreased cold duration and severity of symptoms, possibly as a result of an antihistamine effect [80].

In 2002 a meta-study into all the published research on effectiveness of ascorbic acid in the treatment of infectious disease and toxins was conducted, by Thomas Levy, Medical Director of the Colorado Integrative Medical Centre in Denver. He claimed that evidence exists for its therapeutic role in a wide range of viral infections and for the treatment of snake bites.


Colds A recent 55-study review [81] found little positive effect of a vitamin C intake on common cold at low doses, but indication of prophylaxis benefits at higher doses especially where the subjects were in stressful situations.

At least 29 controlled clinical trials (many double-blind and placebo-controlled) involving a total of over 11,000 participants have been conducted into vitamin C and the Common cold. These trials were reviewed in the 1990s[82][83] and again more recently.[84] The trials show that vitamin C reduces the duration and severity of colds but not the frequency. The data indicate that there is a normal dose-response relationship. Vitamin C is more effective the higher the dose. [85] The controlled trials and clinical experience show that vitamin C in doses ranging from 0.1 to 2 g/day have little effect. The vast majority of the trials were limited to doses below 1 g/day. As doses rise, it becomes increasingly difficult to keep the trials double blind because of the obvious gastro-intestinal side effects of heavy doses of vitamin C. So, the most effective trials at doses between 2 and 10 g/day are generally met with skepticism.


Hepatitis C virus infection A phase I clinical trial was conducted to determine whether antioxidants could be beneficial in hepatitis C virus infection (HCV infection). This infection leads to a lack of antiviral defenses and to oxidative stress in the liver. Ultimately, oxidative stress, notably lipid-mediated oxidative stress (lipid peroxidation), causes liver cells to degenerate and die. Vitamin C was part of the protocol. The trial yielded favourable changes : normalization of liver enzymes (ALT returned to normal in 44 % of those who had abnormal ALT); decrease in viral load (25 % of patients); tissue changes (36.1 % had improvements histologic parameters); and 58 % of patients saw their quality of life improve with the antioxidant treatment (increase in the SF-36[86] score).[87]

Toxics

Lead

(in progress)

There is also evidence that vitamin C is useful in preventing lead poisoning, possibly helping to chelate the toxic heavy metal from the body. [5]

Common pesticides and contaminants

There exists great concern about the impact of pesticides and other contaminants on the reproductive capabilities on animals, including humans.[88] The toxicity of pesticides and contaminants can occur, notably, through endocrine disruption and/or oxidative stress.

The oxidative toxicity of bisphenol A to the epididymis and its effect on sperm motility and sperm count have been shown to be lessened by vitamin C.[89] The oxidative toxicities of endosulfan, phosphamidon,mancozeb and PCB (Aroclor 1254) were also neutralized by vitamin C.[90][91] It is important to note that the protective effects occurred irrespective of the chemical structure of the toxics, but rather addressed a common pathway of injury, i.e. oxidative stress, considering the very broad variety of chemical properties of toxics commonly encountered in the environment and in humans.

Medications (reduction of adverse effects)

Reduction of gentamicin nephrotoxicity

Vitamin C has been found to be effective in reducing or protecting against nephrotoxicity caused by the aminoglycoside antibiotic gentamicin.[92]

Cardiovascular disease and fat intake

After a high-fat meal, triglycerides raise and the flow of blood through the arteries is impaired. Two grams of vitamin C largely suppress the impairment in flow-mediated dilatation in people with coronary heart disease as well as in healhty persons.[93] In persons using a high-fat, low carbohydrate diet to lose weight, 1 g of vitamin C combined to 800 IU of vitamin E was successfully used to lower C-reactive protein, a confirmation of previous studies on the acute CRP-lowering effect of high, but physiological post-meal intakes of vitamin C.

Overall, these finding indicate that previous trials of vitamin C must be reinterpreted in function of the timing of the supplementation and in function of the amount of fat consumed.

Cardiovascular disease as a long latency collagen disease

(Under revision: Nobel laureate chemist Linus Pauling stated that "chronic scurvy" or "subclinical scurvy" is a condition of vitamin C deficiency which is not as easily noticeable as acute scurvy (because chronic scurvy is mostly internal), characterized by micro lesions of tissues (such as that caused by blood pulsing through arteries, which stretches the arterial walls causing them to tear slightly), due to suboptimal collagen synthesis (see Collagen synthesis, above). Pauling and Rath stated that cardiovascular disease is primarily a collagen defect in the vasculature, and that plaque deposits were consequences. In support of this notion, the Proceedings of the National Academy of Sciences published in 2000 evidence that Shionogi rats (see Biosynthesis, above), a scurvy-prone species like Man, had a tendency to develop damage to the aorta, low HDL cholesterol and high total cholesterol, in a manner akin to typical human heart disease, under suboptimal vitamin C nutriture.[94]

Vitamin C is the main component of the three ingredients in Pauling and Rath's patented preventive cure for Lp(a)[95] related heart disease, the other two being the amino acid lysine and nicotinic acid (a form of Vitamin B3). Lp(a) as an atherosclerotic, evolutionary substitute for ascorbate[96] is still discussed as a hypothesis by mainstream medical science[97] and the Rath-Pauling related protocols[98] have not been rigorously tested and evaluated as conventional medical treatment by the FDA. )

Cancer

Although abundant biochemical reasons exist why vitamin C may help prevent and treat cancer, randomized controlled trials of supplementation in humans have not found benefit.

Biochemistry

As noted above, at physiologically attainable concentrations, vitamin C suppresses the deleterious effects of oxidative stress. As oxidative stress is thought to increase the risk of several cancers, it has been suggested that vitamin C might help prevent such cancers (see Toxics -- Common pesticides and contaminants). There is evidence that a diet rich in fresh fruit and vegetables - prominent sources of antioxidants - can reduce the risk of some cancers, but no clear evidence that taking vitamin C supplements is protective.

In 2005 in vitro (test tube) research by the National Institutes of Health indicated that, at high concentrations, vitamin C was preferentially toxic to several strains of cancer cells, supporting Linus Pauling's claims that vitamin C can be used to fight cancer.[99]

Vitamin C does inhibit some intracellular signalling pathways that are important in the proliferation of cancer cells, including the PI3K/AKT pathway [100] Vitamin C inhibits this pathway in vitro as well as in vivo.[101] The form of vitamin C used to demonstrate these effects is ascorbyl stearate, a lipophilic, vitamin C derivative, which is termed a nutraceutical.

Hypoxia-inducible factor-1 (HIF-1) is another well known protein involved in carcinogenisis. Vitamin C inhibits its expression, leading researchers to question whether it is the antioxidant and DNA-protective effect of vitamin C that really explains its anticancer effects. [15]

Trials of cancer treatment in humans

In 1979 and 1985, two randomized controlled trials found no beneficial effect of vitamin C supplementation in cancer patients[102][103], as a result, interest for vitamin C in cancer declined markedly, although there have since been occasional case reports suggesting that there might be benefits in some cases [104]

Trials of cancer prevention in humans

Vitamin C cannot prevent cancer in men according to randomized controlled trials.[105][106][107] Although analysis of secondary outcomes in the earliest trial suggested a reduction in prostate cancer and colorectal cancer [107], this was not confirmed in prespecified analyses in the latter trials.[105][106]

Cataracts

A decrease in lens vitamin C concentrations in the course of cataract progression was shown.[108]

The 'Jean Mayer USDA Human Nutrition Research Center on Aging' showed that, in the 'Nurses' Health Study' cohort, practically all older women who consumed vitamin C supplements for more than 10 years were protected from lense opacities,[109] thus confirming earlier epidemiological evidence on the benefits of vitamin C supplementation in the prevention of cataracts.[110]

The finding, made in 1998, that cataract is associated with lens vitamin C deficiency[108] received support in 2004. While concentrations of vitamin C in the healthy aqueous humour are between 60 and 85 mg/dL (about 20 to 30 times those in plasma), they average just 4.3 mg/dL in people with cataract.[111] This, together with the fact that the transport of vitamin C from the aqueous humour to the lens is rather slow in humans,[112] indicates that the lens is a tissue that needs high intakes of vitamin C.

Obstetrics and gynaecology

Recent studies into the use of a combination of Vitamin E ("natural" source isomer moiety, d-alpha tocopheryl ester) and vitamin C in preventing oxidative stress leading to pre-eclampsia failed to show significant benefit at the dosage tested, [113] In another study the same dosage did decrease average gestational time resulting in a higher incidence of low birthweight babies in one study.[114] Studies into antioxidants for pre-eclampsia are continuing.[115]

Side effects and contraindications

Contraindications A Contraindication is a condition which makes an individual more likely to be harmed by a dose of vitamin C than an average person.

  • A primary concern is people with unusual or unaddressed iron overload conditions, including hemochromatosis. Vitamin C enhances iron absorption. If sufferers of iron overload conditions take gram sized doses of vitamin C, they may worsen the iron overload due to enhanced iron absorption.
  • Inadequate Glucose-6-phosphate dehydrogenase enzyme (G6PD) levels, a genetic condition, may predispose some individuals to hemolytic anemia after intake of specific oxidizing substances present in some food and drugs. This includes repeated, very large intravenous or oral dosages of vitamin C. There is a test available for G6PD deficiency [6].

Side-effects

  • Vitamin C causes diarrhea if taken in quantities beyond a certain limit, which varies by individual. The diarrhea will cease as soon as the dose is reduced.
  • Large doses of vitamin C may cause acid indigestion, particularly when taken on an empty stomach.

Toxicity

Vitamin C exhibits remarkably low toxicity. For example, in a rat, the LD50 (the dose that will kill 50% of a population) has been reported as 11900 mg/kg,[116] or, for a 70 kg (155 pound) human, 833 grams of vitamin C would need to be ingested to stand a 50% chance of killing the person.

Harmful effects

Reports of harmful effects of vitamin C tend to receive prominent media coverage. As such, these reports tend to generate much debate and more research into vitamin C. Some of the harmful effects described below were proven invalid in later studies, while other effects are still being analyzed.

  • In April 1998, the journal Nature reported carcinogenic and teratogenic effects of excessive doses of vitamin C. The effects were noted in test tube experiments. [117]

The authors later clarified their position, stating that their results "show a definite increase in 8-oxoadenine after supplementation with vitamin C. This lesion is at least ten times less mutagenic than 8-oxoguanine, and hence our study shows an overall profound protective effect of this vitamin".[118]

  • "Rebound scurvy" is a theoretical condition that could occur when daily intake of vitamin C is rapidly reduced from a very large amount to a relatively low amount. Advocates suggest this is an exaggeration of the rebound effect which occurs because ascorbate-dependent enzyme reactions continue for 24–48 hours after intake is lowered, and use up vitamin C which is not being replenished. The effect is to lower one's serum vitamin C blood concentration to less than normal for a short amount of time. During this period of time there is a slight risk of cold or flu infection through reduced resistance. Within a couple of days the enzyme reactions shut down and blood serum returns to the normal level of someone not taking large supplements. This is not scurvy, which takes weeks of zero vitamin C consumption to produce symptoms. It is something people who take large vitamin C supplements need to be aware of in order to gradually reduce dosage rather than quit taking vitamin C suddenly.
  • Some writers[121] have identified a theoretical risk of poor copper absorption from high doses of vitamin C. However, ceruloplasmin levels seem specifically lowered by high vitamin C intake. In one study, 600 mg of vitamin C daily did not decrease copper absorption or overall body copper status in young men, but led to lower ceruloplasmin levels similar to those caused by copper deficiency.[122] In another, ceruloplasmin levels were significantly reduced.[123]

Conflicts with prescription drugs

Pharmaceuticals designed to reduce stomach acid such as the proton pump inhibitors (PPIs), are among the most widely-sold drugs in the world. One PPI, omeprazole, lowers the bioavailability of vitamin C by 12%, independent of dietary intake. This means that one would have to consume 14% more vitamin C to counteract the use of 40 mg/day of omeprazole. The probable mechanism of vitamin C reduction, intragastric pH elevated into alkalinity, would apply to all other PPI drugs, though not necessarily to doses of PPIs low enough to keep the stomach slightly acidic. [124]

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