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| Photo Credit: encolombia.com |
Direct effects of UV radiation
Cornea~ photokeratitis
UV radiations are absorbed by the corneal epithelium, which
results in a reduction of the cell division in mild cases or, in severe cases,
in complete death of the epithelial cells and loss of injured cells. Corneal
ulceration may occur in extreme cases. The accumulation of damaged and
exfoliated cells on the surface of the cornea can act as an effective filter to
limit the total exposure dose and filter specific wavelength of UV radiation.
Unfortunately, the eye cannot build up resistance to UV radiation,
like the skin does; exposure has an accumulative effect in a 24-hour period.
So, while a single exposure may not be harmful, if repeated the accumulative
effect may be above threshold and result in epithelial damage.
Following exposure to UV radiation, there is a latent period of
6-12 hours before any symptoms are noticed. This period varies inversely with
the dose of UV radiation exposure. The symptoms experienced are:
- A sensation of sand in the eyes, due to congestion of the conjunctival and episcleral blood vessels;
- Lacrimation (watery eye);
- Photophobia (sensitivity to light);
- Chemosis (swelling of conjunctival tissues);
- Erythema (redness) of the lids;
- Blepharospasm (involuntary, sustained and forceful closure of the eyelids).
The condition is generally self-limiting and almost all the
discomfort disappears within 48 hours due to the repair mechanisms of the
corneal epithelium. Photokeratitis is common amongst welders, when the
condition is referred to as 'arc eye' or 'welder's flash'. The latent period appears to be due to a marked decrease in
corneal sensitivity. It has been observed that after exposure to UV radiation
from electric arc welder the corneal sensitivity decreased. The sensation of
sand and pain in the eyes is experienced as the corneal sensitivity is
restored.
Therapy consists of instillation of lubricating ointment and
decongestant drops. A local/topical anaesthetic can be given and the eye can be
patched if pain is severe and blepharospasm is present. Although the primary
short-term effect of acute exposures of UV radiation of the cornea is
photokeratitis, damage to the corneal endothelium may also occur. It also
appears that chronic UV radiation exposure contributes to increased endothelial
polymegethism (greater than normal variation in the size of cornea endothelial
cells) seen with age.
Pingecula, pterygium and band-shaped keratopathy
Long-term chronic exposure to UV radiation is thought to be partly
responsible for other conditions, namely pingeculae, pterygia and band shaped
keratopathies. A significantly high incidence of pingeculae and pterygia is
found amongst outdoor workers, such as fishermen and welders, who are exposed
to UV radiation.
A nodular band-shaped keratopathy has been noted in people who
live in areas of the world with high levels of UV. White or cream opacities
occur between the epithelium and Bowman's membrane in the palpebral fissure.
Cataracts
As only the shorter wave lengths are filtered out by the cornea,
the lens is constantly exposed to the longer wavelengths throughout life. It
has been shown that these wavelengths are responsible for generating
fluorescent compounds and for the protein cross-linking associated with lens
aging and cataract formation. Chronic cumulative photochemical damage results in increased absorption
of UV radiation and some visible light due to photochemically generated
chromophores.
The chromophores increase in concentration and number with age
and are responsible for the increased yellow color of the lens nucleus and
hence enable the lens to act as an effective filter, protecting the retina from
cumulative photochemical damage by the second to third decade. Report have shown that 'senile' cataract have occurred at an
earlier age (40-50 years) in workers exposed to industrial sources of UV, e.g.
printing works, dentistry and medicine. So is there any evidence to suggest
that exposure to UV radiation is responsible for cataract formation?
Vitreous shrinkage
The vitreous is normally protected from damage by the cornea and
lens, which filter wavelength up to 400nm. However, if the eye is aphakic the
vitreous has no protection against wavelengths greater than 295nm. The vitreous
gel possesses UV-absorbing chromophores and there is experimental evidence that
damage, such as vitreous shrinkage and denaturation of the collagen network,
can occur.
Retina
As stated above, the retina is generally protected from UV
radiation by the cornea and lens but damage can occur to: aphakes (without crystalline lens) who lack the filtering effect
of the lens; fishermen and sailors or employees in industries where UV
polymerization is employed.
The aphakic eye is also at risk from retinal detachments due to
vitreous shrinkage and denaturation of the collagen network. Aging is known to
cause a loss of rod and cone cells and it has been suggested that this is due
to a potential cumulative action of light, i.e. a phototoxic effect, which is
cumulative in the normal aging process.
Indirect effects of UV radiation
There are reports that UV radiation can be indirectly absorbed by
photo-sensitizing drugs and cause damage to the crystalline lens and retina. A
treatment for psoriasis (skin disease that causes scaling and inflammation),
known as PUVA therapy, consists of the ingestion of a psoralen compound
followed by exposure to UV radiation.
Ocular protection must be provided as the
UV radiation causes binding of the psoralen compound to lens and retinal
proteins in aphakic individuals. This protection must be provided for at least
12-24 hours after ingestion, i.e. until there is no psoralen compound remaining
in the lens. The opacities occur in the anterior and posterior cortical layer;
some are punctate and others are wedge-shaped. It is believed that the
opacification is mainly due to binding of tryptophan and lens proteins, which
remain in the lens.
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