Grey or white hair is not caused by a true grey or white pigment, but is due to a lack of pigmentation and melanin. The clear hairs appear as grey or white because of the way light is reflected from the hairs. The change in hair colour occurs when melanin ceases to be produced in the hair root and new hairs grow in without pigment. The
stem cells at the base of
hair follicles produce
melanocytes, the cells that produce and store pigment in hair and skin. The death of the melanocyte
stem cells causes the onset of greying. It remains unclear why the stem cells of one hair follicle may fail to activate well over a decade before those in adjacent follicles less than a millimeter apart. In non-balding individuals, hair may grow faster once it turns grey. Unlike in the skin where pigment production is continuous,
melanogenesis in the hair is closely associated with stages of the hair cycle. Hair is actively pigmented in the
anagen phase and is "turned off" during the
catagen phase, and absent during
telogen. Thus, a single hair cannot be white on the root side, and colored on the terminal side. Several
genes appear to be responsible for the process of greying.
Bcl2 and
Bcl-w were the first two discovered, then in 2016, the
IRF4 (interferon regulatory factor 4) gene was announced after a study of 6,000 people living in five
Latin American countries. However, it found that
environmental factors controlled about 70% of cases of hair greying. Greying of hair may be triggered by the accumulation of
hydrogen peroxide and abnormally low levels of the enzyme
catalase, which breaks down hydrogen peroxide and relieves
oxidative stress in patients with
vitiligo. Since vitiligo can cause eyelashes to turn white, the same process is believed to be involved in hair on the head (and elsewhere) due to aging. In some cases, grey hair segments due to stress, chemicals, or a nutrient deficiency may reverse when the issue resolves.
Stress Anecdotes report that
stress, both chronic and acute, may induce achromotrichia earlier in individuals than it otherwise would have. There is some evidence for chronic stress causing premature achromotrichia, but no definite link has been established. It is known that the stress
hormone cortisol accumulates in human hair over time, but whether this has any effect on hair color has not yet been resolved. A 2020 paper, published in the journal
Nature reported that stress can cause hair to lose its pigment. An overactive immune response can destroy melanocytes and melanocyte stem cells in black-haired rats. When intentionally subjecting them to panic, they bleached their coat. The next time the rats' coat grew, there were no melanocyte stem cells in these damaged follicles, so white hairs sprouted, and the color loss was permanent.
UV damage Excessive exposure to the sun is the most common cause of structural damage of the hair shaft. Photochemical hair damage encompasses hair protein degradation and loss, as well as hair pigment deterioration. Photobleaching is common among people with European ancestry. Around 72 percent of customers who agreed to be involved in a study and have European ancestry reported in a recent
23andMe research that the sun lightens their hair. The company also have identified 48 genetic markers that may influence hair photobleaching.
Medical conditions In some cases, grey hair may be caused by thyroid deficiencies,
Waardenburg syndrome or a
vitamin B12 deficiency. At some point in the human life cycle, cells that are located in the base of the hair's follicles slow, and eventually stop producing pigment.
Piebaldism is a rare
autosomal dominant disorder of
melanocyte development, which may cause a
congenital white forelock.
Albinism is a genetic abnormality in which little or no pigment is found in human hair, eyes, and skin. The hair is often white or pale blond. However, it can be red, darker blond, light brown, or rarely, even dark brown.
Vitiligo is a patchy loss of hair and skin color that may occur as the result of an
auto-immune disease. In a preliminary 2013 study, researchers treated the buildup of hydrogen peroxide which causes this with a light-activated pseudo-
catalase. This produced significant media coverage that further investigation may someday lead to a general non-dye treatment for grey hair.
Malnutrition is also known to cause hair to become lighter, thinner, and more brittle. Dark hair may turn reddish or blondish due to the decreased production of melanin. The condition is reversible with proper nutrition.
Werner syndrome and
pernicious anemia can also cause premature greying. A 2005 uncontrolled study demonstrated that people 50–70 years of age with dark eyebrows but grey hair are significantly more likely to have
type II diabetes than those with both grey eyebrows and hair.
Artificial factors A 1996
British Medical Journal study found that
tobacco smoking was correlated with premature greying. Smokers were found to be four times more likely to begin greying prematurely, compared to nonsmokers. Grey hair may temporarily darken after inflammatory processes, after electron-beam-induced alopecia, and after some chemotherapy regimens. Much remains to be learned about the physiology of human greying. There are no special diets, nutritional supplements, vitamins, or proteins that have been proven to slow, stop, or in any way affect the greying process, although many have been marketed over the years. However, French scientists treating
leukemia patients with
imatinib, a drug used in treating cancer, noted an unexpected side effect: some of the patients' hair color was restored to their pre-grey color. == Management ==