Sunscreen

Encyclopedia : S : SU : SUN : Sunscreen

Sunscreen (also known as sunblock, suncream, suntan lotion) is a lotion, spray or other topical product that helps protect the skin from the sun's ultraviolet radiation, and which reduces sunburn and other skin damage, ultimately leading to a lower risk of skin cancer.

The best sunscreens protect against both UVB (ultraviolet radiation with wavelength between 290 and 320 nanometres), which can cause sunburn, and UVA (between 320 and 400 nanometres), which damages the skin with more long-term effects, such as premature skin aging. Most sunscreens work by containing either an organic chemical compound that absorbs ultraviolet light (such as oxybenzone) or an opaque material that reflects light (such as titanium dioxide, zinc oxide), or a combination of both. Typically, absorptive materials are referred to as chemical blocks, whereas opaque materials are mineral or physical blocks.

Dosing for sunscreen can be calculated using the formula for body surface area and subsequently subtracting the area covered by clothing. The dose used in FDA sunscreen testing is 2 mg/cm². From a sample calculation in a [FDA monograph], if one assumes an "average" adult build of height 5'4" (163 cm) and weight 150 lb (68 kg) with a 32" (82 cm)-waist, that adult wearing a bathing suit covering the groin area should apply 29 grams (approximately 1 oz) evenly to the uncovered body area.

Contrary to the common advice that sunscreen should be reapplied every 2—3 hours, research has shown that the best protection is achieved by application 15 to 30 minutes before exposure, followed by one reapplication 15 to 30 minutes after the sun exposure begins. Further reapplication is only necessary after activities such as swimming, sweating, and rubbing.

A significant reduction in sun exposure inhibits the production of vitamin D. Though excessive sun exposure has been conclusively linked to some forms of skin cancer and signs of premature aging, there is some evidence that vitamin D may help prevent other forms of cancer. Season, geographic latitude, time of day, cloud cover, smog, skin type, and sunscreen all have an effect on vitamin D production in the skin, but fifteen minutes per day of direct exposure to the sun is a generally accepted guideline to follow for optimum vitamin D production. Experts generally recommend taking a fifteen minute walk in the morning or evening without wearing sunscreen to meet this requirement.

Contents

1 History
2 Mechanism of action
3 Sun protection factor
4 Melanin
5 Possible health effects
6 References
7 See also
8 External links

History

The ancient Greeks used olive oil as a type of sunscreen. However, this was not very effective. Throughout the early twentieth century, H.A. Milton Blake, a South Australian chemist, as well as several other inventors attempted to create an effective sunscreen but failed.

It was not until 1944 that the first effective sunscreen was invented. At that time, World War II was in full swing and many soldiers were getting serious sunburn. A pharmacist named Benjamin Greene decided to create something that would save the soldiers from the sun’s harmful rays. In his wife’s oven, he created a sticky, red substance which he called "red vet pet" (red veterinary petrolatum), which worked primarily by physically blocking the sun's rays with a thick petroleum-based product similar to Vaseline. Greene tested it on his own bald head. It did not work nearly as well as modern sunscreens, but it was a start.

Sunscreen has come a long way since its initial days. Modern products have much higher protection factors than Greene's sunscreen, and modern products can also be water- and sweat-resistant. But there are also negative effects. Some people rely too much on the product and do not understand the limitations of the sun protection factor (SPF); they assume that buying anything over SPF 30 will automatically prevent them getting burnt no matter how long they can stay in the sun. Too much sunbathing is one of the major causes of skin cancer across the world.

Mechanism of action

The principal ingredients in sunscreens are usually aromatic molecules conjugated with carbonyl groups. This general structure allows the molecule to absorb high-energy ultraviolet rays and release the energy as lower-energy rays, thereby preventing the skin-damaging ultraviolet rays from reaching the skin. So, upon exposure to UV light, most of the ingredients (with the notable exception of avobenzone) do not undergo significant chemical change, allowing these ingredients to retain the UV-absorbing potency without significant photo-degradation. Further details regarding the mechanism of action of sunscreen products can be found [here].

Sun protection factor

The SPF (sun protection factor) of a sunscreen is a laboratory measure of the effectiveness of sunscreen; the higher the SPF, the more protection a sunscreen offers against UV-B (the ultraviolet radiation that causes sunburn) and UV-A (more associated with longer-term skin damage). The SPF indicates the time a person can be exposed to sunlight before getting sunburn with a sunscreen applied relative to the time he or she can be exposed without sunscreen. For example, someone who would burn after 12 minutes in the sun would expect to burn after 2 hours (120 min) if protected by a sunscreen with SPF 10. In practice, the protection from a particular sunscreen depends on factors such as:

The skin type of the user.
The amount applied and frequency of re-application.
Activities in which one engages (for example, swimming leads to a loss of sunscreen from the skin).
Amount of sunscreen the skin has absorbed.

The SPF is an imperfect measure of skin damage because invisible damage and skin aging is also caused by the very common ultraviolet type A, which does not cause reddening or pain. Conventional sunscreen does not block UVA as effectively as UVB, and an SPF rating of 30+ may translate to significantly lower levels of UVA protection according to a [2003 study] by [RAFT trust]-funded researchers. According to a 2004 [study], UVA also causes DNA damage to cells deep within the skin, increasing the risk of malignant melanomas. Even some products labeled "broad-spectrum UVA/UVB protection" do not provide good protection against UVA rays [link]. The best UVA protection is provided by products that contain zinc oxide, titanium dioxide, avobenzone or mexoryl.

Due to consumer confusion over the real degree and duration of protection offered, labeling restrictions are in force in several countries. In the United States in 1999, the Food and Drug Administration (FDA) decided to institute the labelling of SPF 30+ for sunscreens offering more protection, and a similar restriction applies in Australia. This was done to discourage companies making [unrealistic] claims about the level of protection offered (such as "all day protection"), and because an SPF over 30 does not provide significantly better protection (Needs citation).

The SPF can be measured by applying sunscreen to the skin of a volunteer and measuring how long it takes before sunburn occurs when exposed to an artificial sunlight source. In the US, such an in vivo test is required by the FDA. It can also be measured in vitro with the help of a specially designed spectrometer. In this case, the actual transmittance of the sunscreen is measured, along with the degradation of the product due to being exposed to sunlight. In this case, the transmittance of the sunscreen must be measured over all wavelengths in the UV-B range (290—350 nm), along with a table of how effective various wavelengths are in causing sunburn (the erythemal action spectrum) and the actual intensity spectrum of sunlight (see the figure). Such in vitro measurements agree very well with in vivo measurements. [link]

Mathematically, the SPF is calculated from measured data as

[\mathrm = \frac(\lambda) \, d\lambda},]

where [E(\lambda)] is the solar irradiance spectrum, [A(\lambda)] the erythemal action spectrum, and [\mathrm(\lambda)] the monochromatic protection factor, all functions of the wavelength [\lambda]. The MPF is roughly the inverse of the transmittance at a given wavelength.

The above means that the SPF is not simply the inverse of the transmittance in the UV-B region. If that were true, then applying two layers of SPF 5 sunscreen would be equivalent to SPF 25 (5 times 5). The actual combined SPF is always lower than the square of the single-layer SPF.

The following are the FDA allowable active ingredients in sunblocks:

p-Aminobenzoic acid (PABA) up to 15 %.
Avobenzone up to 3%.
Cinoxate up to 3%.
Dioxybenzone up to 3%.
Homosalate up to 15%.
Menthyl anthranilate up to 5%.
Octocrylene up to 10%.
Octyl methoxycinnamate (Octinoxate) up to 7.5%.
Octyl salicylate up to 5%.
Oxybenzone up to 6%.
Padimate O up to 8%.
Phenylbenzimidazole sulfonic acid (Ensulizole) up to 4%.
Sulisobenzone up to 10%.
Titanium dioxide up to 25%.
Trolamine salicylate up to 12 %.
Zinc oxide up to 25%.

Others include:

Tinosorb – meant to be applied to clothing via treatment/detergent
Mexoryl – not approved in the United States but available in Europe/Asia

Melanin

The hormone alpha-melanocyte stimulating hormone is made when the body is exposed to sunlight and is responsible for the development of the pigment melanin. Research is being done to create stable artificial forms of the hormone. A promising candidate, melanotan, might be useful in the prevention of skin cancer, by causing tanning without the need for exposure to dangerous levels of UV.

Possible health effects

Recently, there has been increased attention to the possibility of adverse health effects associated with the synthetic compounds in most sunscreens. [link] A study published in the American Journal of Public Health, in April 1992, entitled "Could sunscreens increase melanoma risk?" reported that the greatest increase in melanoma has occurred in countries like Australia, where sunscreen use is prevalent.

In a May 2006 report, "Nanomaterials, Sunscreens and Cosmetics: Small Ingredients, Big Risks", Friends of the Earth claimed that several types of nanoparticles— like titanium dioxide or zinc oxide— can be harmful to human tissue. Currently, there is no policy requiring mandatory product labelling on products that use these compounds.

Some individuals can have mild to moderate allergic reactions to certain ingredients in sunscreen, particularly the chemical benzophenone, which is also known as phenyl ketone, diphenyl ketone, or benzoylbenzene. It is not clear how much of benzophenone is absorbed into the bloodstream, but trace amounts can be found in urinalysis after use.

References

External links

[FDA monograph on sunscreen]
[FDA monograph on dosing, mechanism of action, and photodegradation of sunscreen (PDF file)]
[Sunscreen Manufacture]
[Sun Protection Tips]
[Sunscreen protection calculator]
[Sun Safety for Babies and Children]University of Florida/IFAS Extension Department of Family, Youth and Community Sciences

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