Fruits
and vegetables are often a good source of vitamins.
A vitamin
is an organic compound required as a nutrient in tiny amounts
by an organism.
A compound is called a vitamin when it cannot be synthesized
in sufficient quantities by an organism, and must be obtained
from the diet. Thus, the term is conditional both on the circumstances
and the particular organism. For example, ascorbic acid functions
as vitamin C for some animals but not others, and vitamins D
and K are required in the human diet only in certain circumstances.
The term vitamin does not include other essential nutrients
such as dietary minerals, essential fatty acids, or essential
amino acids, nor does it encompass the large number of other
nutrients that promote health but are otherwise required less
often.
Vitamins
are classified by their biological and chemical activity, not
their structure. Thus, each "vitamin" may refer to several vitamer
compounds that all show the biological activity associated with
a particular vitamin. Such a set of chemicals are grouped under
an alphabetized vitamin "generic descriptor" title, such as
"vitamin A," which includes the compounds retinal, retinol,
and many carotenoids.
Vitamers are often inter-converted in the body.
Vitamins
have diverse biochemical functions, including function as hormones
(e.g. vitamin D), antioxidants (e.g. vitamin E), and mediators
of cell signaling and regulators of cell and tissue growth and
differentiation (e.g. vitamin A). The largest number of vitamins
(e.g. B complex vitamins) function as precursors for enzyme
cofactor bio-molecules (coenzymes), that help act as catalysts
and substrates in metabolism. When acting as part of a catalyst,
vitamins are bound to enzymes and are called prosthetic groups.
For example, biotin is part of enzymes involved in making fatty
acids. Vitamins also act as coenzymes to carry chemical groups
between enzymes. For example, folic acid carries various forms
of carbon group – methyl, formyl and methylene - in the cell.
Although these roles in assisting enzyme reactions are vitamins'
best-known function, the other vitamin functions are equally
important.
Until the
1900s, vitamins were obtained solely through food intake, and
changes in diet (which, for example, could occur during a particular
growing season) can alter the types and amounts of vitamins
ingested. Vitamins have been produced as commodity chemicals
and made widely available as inexpensive pills for several decades,
allowing supplementation of the dietary intake.
History
The Ancient
Egyptians knew that feeding a patient liver (back, right)
would help cure night blindness.
The value
of eating a certain food to maintain health was recognized long
before vitamins were identified. The ancient Egyptians knew
that feeding a patient liver would help cure night blindness,
an illness now known to be caused by a vitamin A deficiency.
The advancement of ocean voyage during the Renaissance
resulted in prolonged periods without access to fresh fruits
and vegetables, and made illnesses from vitamin deficiency common
among ship's crew.
In 1749,
the Scottish surgeon James Lind discovered that citrus foods
helped prevent scurvy, a particularly deadly disease in which
collagen is not properly formed, causing poor wound healing,
bleeding of the gums, severe pain, and death. In 1753, Lind
published his Treatise on the Scurvy, which recommended
using lemons and limes to avoid scurvy, which was adopted by
the British Royal Navy. This led to the nickname Limey for sailors
of that organization. Lind's discovery, however, was not widely
accepted by individuals in the Royal Navy's Arctic expeditions
in the 19th century, where it was widely believed that scurvy
could be prevented by practicing good hygiene, regular exercise,
and by maintaining the morale of the crew while on board, rather
than by a diet of fresh food. As a result, Arctic expeditions
continued to be plagued by scurvy and other deficiency diseases.
In the early 20th century, when Robert Falcon Scott made his
two expeditions to the Antarctic, the prevailing medical theory
was that scurvy was caused by "tainted" canned food.
In 1881,
Russian surgeon Nikolai Lunin studied the effects of scurvy
while at the University of Tartu in present-day Estonia. He
fed mice an artificial mixture of all the separate constituents
of milk known at that time, namely the proteins, fats, carbohydrates,
and salts. The mice that received only the individual constituents
died, while the mice fed by milk itself developed normally.
He made a conclusion that "a natural food such as milk must
therefore contain, besides these known principal ingredients,
small quantities of unknown substances essential to life." However,
his conclusions were rejected by other researchers when they
were unable to reproduce his results. One difference was that
he had used table sugar (sucrose), while other researchers had
used milk sugar (lactose) that still contained small amounts
of vitamin B.
The
discovery of vitamins and their sources
| Year
of discovery |
Vitamin |
Source |
| 1909 |
Vitamin
A (Retinol) |
Cod
liver oil |
| 1912 |
Vitamin
B1 (Thiamine) |
Rice
bran |
| 1912 |
Vitamin
C (Ascorbic acid) |
Lemons |
| 1918 |
Vitamin
D (Calciferol) |
Cod
liver oil |
| 1920 |
Vitamin
B2 (Riboflavin) |
Eggs |
| 1922 |
Vitamin
E (Tocopherol) |
Wheat
germ oil, Cosmetic and Liver |
| 1926 |
Vitamin
B12 (Cyanocobalamin) |
Liver |
| 1929 |
Vitamin
K (Phylloquinone) |
Alfalfa |
| 1931 |
Vitamin
B5 (Pantothenic acid) |
Liver |
| 1931 |
Vitamin
B7 (Biotin) |
Liver |
| 1934 |
Vitamin
B6 (Pyridoxine) |
Rice
bran |
| 1936 |
Vitamin
B3 (Niacin) |
Liver |
| 1941 |
Vitamin
B9 (Folic acid) |
Liver |
In east
Asia, where polished white rice was the common staple food of
the middle class, beriberi resulting from lack of vitamin B1
was endemic. In 1884, Takaki Kanehiro, a British trained medical
doctor of the Japanese Navy, observed that beriberi was endemic
among low-ranking crew who often ate nothing but rice, but not
among crews of Western navies and officers who consumed a Western-style
diet. Kanehiro initially believed that lack of protein was the
chief cause of beriberi. With the support of the Japanese navy,
he experimented using crews of two battleships; one crew was
fed only white rice, while the other was fed a diet of meat,
fish, barley, rice, and beans. The group that ate only white
rice documented 161 crew members with beriberi and 25 deaths,
while the latter group had only 14 cases of beriberi and no
deaths. This convinced Kanehiro and the Japanese Navy that diet
was the cause of beriberi. This was confirmed in 1897, when
Christiaan Eijkman discovered that feeding unpolished rice instead
of the polished variety to chickens helped to prevent beriberi
in the chickens. The following year, Frederick Hopkins postulated
that some foods contained "accessory factors"—in addition to
proteins, carbohydrates, fats, et cetera—that were necessary
for the functions of the human body. Hopkins was awarded the
1929 Nobel Prize for Physiology or Medicine with Christiaan
Eijkman for their discovery of several vitamins.
In 1910,
Japanese scientist Umetaro Suzuki succeeded in extracting a
water-soluble complex of micronutrients from rice bran and named
it aberic acid. He published this discovery in a Japanese scientific
journal.
When the
article was translated into German, the translation failed to
state that it was a newly discovered nutrient, a claim made
in the original Japanese article, and hence his discovery failed
to gain publicity. Polish biochemist Kazimierz Funk isolated
the same complex of micronutrients and proposed the complex
be named "Vitamine" (a portmanteau of "vital amine") in 1912.
The name soon became synonymous with Hopkins' "accessory factors",
and by the time it was shown that not all vitamins were amines,
the word was already ubiquitous. In 1920, Jack Cecil Drummond
proposed that the final "e" be dropped to deemphasize the "amine"
reference after the discovery that vitamin C had no amine component.
Throughout
the early 1900s, the use of deprivation studies allowed scientists
to isolate and identify a number of vitamins. Initially, lipid
from fish oil was used to cure rickets in rats, and the fat-soluble
nutrient was called "antirachitic A". Thus, the first "vitamin"
bioactivity ever isolated, which cured rickets, was initially
called "vitamin A", although confusingly the bioactivity of
this compound is now called vitamin D.
What we now call "vitamin A" was identified in fish oil
as a separate factor that was inactivated by ultraviolet light.
In 1931, Albert Szent-Györgyi and a fellow researcher Joseph
Svirbely determined that "hexuronic acid" was actually vitamin
C and noted its anti-scorbutic activity. In 1937, Szent-Györgyi
was awarded the Nobel Prize for his discovery. In 1943 Edward
Adelbert Doisy and Henrik Dam were awarded the Nobel Prize for
their discovery of vitamin K and its chemical structure.
In
humans
Vitamins
are classified as either water-soluble or fat soluble. In humans
there are 13 vitamins: 4 fat-soluble (A, D, E and K) and 9 water-soluble
(8 B vitamins and vitamin C).
Water-soluble
Water-soluble
vitamins dissolve easily in water, and in general, are readily
excreted from the body, to the degree that urinary output is
a strong predictor of vitamin consumption. Because they are
not readily stored, consistent daily intake is important. Many
types of water-soluble vitamins are synthesized by bacteria.
Fat-soluble
Fat-soluble
vitamins are absorbed through the intestinal tract with the
help of lipids (fats). Because they are more likely to accumulate
in the body, they are more likely to lead to hypervitaminosis
than are water-soluble vitamins. Fat-soluble vitamin regulation
is of particular significance in cystic fibrosis.
List
of vitamins
Each vitamin
is typically used in multiple reactions and, therefore, most
have multiple functions.
Vitamin
generic
descriptor name |
Vitamer
chemical name(s) (list not complete) |
Solubility |
Recommended
dietary allowances
(male, age 19–70) |
Deficiency
disease |
Upper
Intake Level
(UL/day) |
Overdose
disease |
| Vitamin
A |
Retinoids
(retinol, retinoids
and carotenoids) |
Fat |
900
µg |
Night-blindness
and
Keratomalacia |
3,000
µg |
Hypervitaminosis
A |
| Vitamin
B1 |
Thiamine |
Water |
1.2
mg |
Beriberi,
Wernicke-Korsakoff syndrome |
N/D |
Rare
hypersensitive reactions resembling anaphylactic shock--
injection only;
Drowsiness
|
| Vitamin
B2 |
Riboflavin |
Water |
1.3
mg |
Ariboflavinosis |
N/D |
? |
| Vitamin
B3 |
Niacin,
niacinamide |
Water |
16.0
mg |
Pellagra |
35.0
mg |
Liver
damage (doses > 2g/day) and other problems |
| Vitamin
B5 |
Pantothenic
acid |
Water |
5.0
mg |
Paresthesia |
N/D |
? |
| Vitamin
B6 |
Pyridoxine,
pyridoxamine, pyridoxal |
Water |
1.3-1.7
mg |
Anemia |
100
mg |
Impairment
of proprioception, nerve damage (doses > 100 mg/day) |
| Vitamin
B7 |
Biotin |
Water |
30.0
µg |
Dermatitis,
enteritis |
N/D |
? |
| Vitamin
B9 |
Folic
acid, folinic acid |
Water |
400
µg |
Deficiency
during pregnancy is associated with birth defects, such
as neural tube defects |
1,000
µg |
Possible
decrease in seizure threshold |
| Vitamin
B12 |
Cyanocobalamin,
hydroxycobalamin, methylcobalamin |
Water |
2.4
µg |
Megaloblastic
anemia |
N/D |
No
known toxicity |
| Vitamin
C |
Ascorbic
acid |
Water |
90.0
mg |
Scurvy |
2,000
mg |
Vitamin
C megadosage |
| Vitamin
D |
Ergocalciferol,
cholecalciferol |
Fat |
5.0
µg-10 µg |
Rickets
and Osteomalacia |
50
µg |
Hypervitaminosis
D |
| Vitamin
E |
Tocopherols,
tocotrienols |
Fat |
15.0
mg |
Deficiency
is very rare; mild hemolytic anemia in newborn infants. |
1,000
mg |
Increased
congestive heart failure seen in one large randomized study. |
| Vitamin
K |
phylloquinone,
menaquinones |
Fat |
120
µg |
Bleeding
diathesis |
N/D |
Increases
coagulation in patients taking warfarin. |
In
nutrition and diseases
Vitamins
are essential for the normal growth and development of a multicellular
organism. Using the genetic blueprint inherited from its parents,
a fetus begins to develop, at the moment of conception, from
the nutrients it absorbs. It requires certain vitamins and minerals
to be present at certain times. These nutrients facilitate the
chemical reactions that produce among other things, skin, bone,
and muscle. If there is serious deficiency in one or more of
these nutrients, a child may develop a deficiency disease. Even
minor deficiencies may cause permanent damage.
For the
most part, vitamins are obtained with food, but a few are obtained
by other means. For example, microorganisms in the intestine—commonly
known as "gut flora"—produce vitamin K and biotin, while one
form of vitamin D is synthesized in the skin with the help of
the natural ultraviolet wavelength of sunlight. Humans can produce
some vitamins from precursors they consume. Examples include
vitamin A, produced from beta carotene, and niacin, from the
amino acid tryptophan.
Once growth
and development are completed, vitamins remain essential nutrients
for the healthy maintenance of the cells, tissues, and organs
that make up a multicellular organism; they also enable a multicellular
life form to efficiently use chemical energy provided by food
it eats, and to help process the proteins, carbohydrates, and
fats required for respiration.
Deficiencies
Deficiencies
of vitamins are classified as either primary or secondary. A
primary deficiency occurs when an organism does not get
enough of the vitamin in its food. A secondary deficiency
may be due to an underlying disorder that prevents or limits
the absorption or use of the vitamin, due to a “lifestyle factor”,
such as smoking, excessive alcohol consumption, or the use of
medications that interfere with the absorption or use of the
vitamin. People who eat a varied diet are unlikely to develop
a severe primary vitamin deficiency. In contrast, restrictive
diets have the potential to cause prolonged vitamin deficits,
which may result in often painful and potentially deadly diseases.
Because
human bodies do not store most vitamins, humans must consume
them regularly to avoid deficiency. Human bodily stores for
different vitamins vary widely; vitamins A, D, and B12
are stored in significant amounts in the human body, mainly
in the liver, and an adult human's diet may be deficient in
vitamins A and B12 for many months before developing
a deficiency condition. Vitamin B3 is not stored
in the human body in significant amounts, so stores may only
last a couple of weeks.
Well-known
human vitamin deficiencies involve thiamine (beriberi), niacin
(pellagra), vitamin C (scurvy) and vitamin D (rickets). In much
of the developed world, such deficiencies are rare; this is
due to (1) an adequate supply of food; and (2) the addition
of vitamins and minerals to common foods, often called fortification.
Some evidence
also suggests that there is a link between vitamin deficiency
and mental disorders.
Side
effects and overdose
In large
doses, some vitamins have documented side effects that tend
to be more severe with a larger dosage. The likelihood of consuming
too much of any vitamin from food is remote, but overdosing
from vitamin supplementation does occur. At high enough dosages
some vitamins cause side effects such as nausea, diarrhea, and
vomiting.
When side
effects emerge, recovery is often accomplished by reducing the
dosage. The concentrations of vitamins an individual can tolerate
vary widely, and appear to be related to age and state of health.
In the United States, overdose exposure to all formulations
of vitamins was reported by 62,562 individuals in 2004 (nearly
80% of these exposures were in children under the age of 6),
leading to 53 "major" life-threatening outcomes and 3 deaths;
a small number in comparison to the 19,250 people who died of
unintentional poisoning of all kinds in the U.S. in the same
year (2004).
Supplements
Dietary
supplements, often containing vitamins, are used to ensure that
adequate amounts of nutrients are obtained on a daily basis,
if optimal amounts of the nutrients cannot be obtained through
a varied diet. Scientific evidence supporting the benefits of
some dietary supplements is well established for certain health
conditions, but others need further study.
A meta-analysis in 2006 suggested that Vitamin A and
E supplements not only provide no tangible health benefits for
generally healthy individuals, but may actually increase mortality,
although two large studies included in the analysis involved
smokers, for which it was already known that beta-carotene supplements
can be harmful.
In the United
States, advertising for dietary supplements is required to include
a disclaimer that the product is not intended to treat, diagnose,
mitigate, prevent, or cure disease, and that any health claims
have not been evaluated by the Food and Drug Administration.
In some cases, dietary supplements may have unwanted
effects, especially if taken before surgery, with other dietary
supplements or medicines, or if the person taking them has certain
health conditions.
Vitamin supplements may also contain levels of vitamins
many times higher, and in different forms, than one may ingest
through food.
Intake of
excessive quantities can cause vitamin poisoning, often due
to overdose of Vitamin A and Vitamin D (The most common poisoning
with multinutrient supplement pills does not involve a vitamin,
but is rather due to the mineral iron). Due to toxicity, most
common vitamins have recommended upper daily intake amounts.
Since 2005,
suppliers have distinguished their products as either Medical
Grade or Pharmaceutical Grade products. Both of these classifications
indicate products that are manufactured to be easily absorbed
by the body. Normal vitamin manufacturing is not regulated in
the United States to the same standards as are medicinal pharmaceuticals,
although U.S. vitamins which are manufactured for food consumption
by humans or animals must be manufactured to Food Chemicals
Codex (FCC), grade, commonly called "food grade".
Governmental
regulation of vitamin supplements
Most countries
place dietary supplements in a special category under the general
umbrella of foods, not drugs. This necessitates that
the manufacturer, and not the government, be responsible for
ensuring that its dietary supplement products are safe before
they are marketed. Unlike drug products, which must explicitly
be proven safe and effective for their intended use before marketing,
there are often no provisions to "approve" dietary supplements
for safety or effectiveness before they reach the consumer.
Also unlike drug products, manufacturers and distributors of
dietary supplements are not generally required to report any
claims of injuries or illnesses that may be related to the use
of their products.
Names
in current and previous nomenclatures
The reason
the set of vitamins seems to skip directly from E to K is that
the vitamins corresponding to "letters" F-J were either reclassified
over time, discarded as false leads, or renamed because of their
relationship to "vitamin B", which became a "complex" of vitamins.
The German-speaking scientists who isolated and described vitamin
K (in addition to naming it as such) did so because the vitamin
is intimately involved in the Koagulation of blood following
wounding. At the time, most (but not all) of the letters from
F through to J were already designated, so the use of the letter
K was considered quite reasonable.
The following
table lists chemicals that had previously been classified as
vitamins, as well as the earlier names of vitamins that later
became part of the B-complex:
| Previous
name |
Chemical
name |
Reason
for name change |
| Vitamin
B4 |
Adenine |
DNA
metabolite |
| Vitamin
B8 |
Adenylic
acid |
DNA
metabolite |
| Vitamin
F |
Essential
fatty acids |
Needed
in large quantities (does
not fit the definition of a vitamin). |
| Vitamin
G |
Riboflavin |
Reclassified
as Vitamin B2 |
| Vitamin
H |
Biotin |
Reclassified
as Vitamin B7 |
| Vitamin
J |
Catechol,
Flavin |
Protein
metabolite |
| Vitamin
L1 |
Anthranilic
acid |
Protein
metabolite |
| Vitamin
L2 |
Adenylthiomethylpentose |
RNA
metabolite |
| Vitamin
M |
Folic
acid |
Reclassified
as Vitamin B9 |
| Vitamin
O |
Carnitine |
Protein
metabolite |
| Vitamin
P |
Flavonoids |
No
longer classified as a vitamin |
| Vitamin
PP |
Niacin |
Reclassified
as Vitamin B3 |
| Vitamin
U |
S-Methylmethionine |
Protein
metabolite |
Weight
Loss 
