Excimer
Lasers
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The excimer
laser has brought more accuracy to corneal surgery
and vision correction than ever before. One pulse
of the excimer laser removes 0.25 microns of tissue.
To put this into perspective, a typical human hair
is 70 microns in thickness. Surgeons have never
had a device as accurate as the excimer laser in
eye surgery. |
Electron
Micrograph of a Human Hair Ablated by the Excimer Laser
Two types of excimer lasers are available for refractive
procedures: broad-beam lasers and scanning lasers. Scanning
lasers can be subdivided into two groups: slit scanning
and spot scanning. Each kind of laser has its pros and
cons. Patients should be aware that while type of beam
used does affect outcomes, "often the difference
is not substantial enough to dispose end users towards
one type of laser or another."1
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The following descriptions
are taken from an article by Stanley B. Teplick,
MD.2 |
- Broad Beam Lasers
A broad beam laser uses a relatively large beam
diameter (from 6.0 to 8.0 millimeters) that can be
manipulated to ablate the cornea. The broad-beam laser
results in the shortest procedure time. This speed
creates less likelihood of overcorrection and decentration
- a complication caused by movement of the pupil.
A disadvantage is an increased possibility of center
islands - a complication related to ablation. However,
ophthalmologists have learned to decrease the incidence
of center islands by using several short laser pulses
to ablate the cornea instead of one longer one.
- Slit Scanning Lasers
A slit scanning laser uses relatively small beams
linked to a rotational device with slit holes that
can enlarge. During surgery, the laser beam scans
across these holes to gradually increase the ablation
zone. A uniform beam and potentially smoother ablations
characterize slit scanning lasers. Disadvantages include
a slightly higher propensity for decentration and
slightly greater risk of overcorrection.
- Spot Scanning Lasers
These systems have the potential to produce the
smoothest ablations and use radar technology to track
the eye's movement. They also have the potential to
treat irregular astigmatism and link to topography.
These lasers must be linked to eye tracking to ensure
proper centration.
U.S.
Current Regulatory Status of Excimer Lasers
For the latest information on the US FDA approvals,
click
here. Patients should be aware that each country
has its own regulatory statutes, so some of the devices
approved in the US may not be available in your country.
At the bottom of this page, we have provided links to
various manufacturers wherever possble and have provided
contact information for those companies currently not
online.
Wavefront
Diagnostics & Custom Ablation
Wavefront sensing is an emerging diagnostic tool for
measuring the refractive error of the eye. Conventional
forms of refraction are limited to measuring the best
spherical and cylindrical refraction (myopia or hyperopia
and regular astigmatism). But wavefront sensing allows
for measurements of other conditions within the cornea
that affect a patient's refraction (how they see). Ophthalmologists
refer to these conditions as higher order aberrations.
Traditionally these higher order aberrations have been
described as irregular astigmatism, and considered a
limitation to best vision with refraction. Now by understanding
and characterizing the components of high order aberrations,
doctors have diagnostic power over irregular astigmatism,
and the ability to quantify levels of naturally occurring
or surgically induced aberration.The diagnostic utility
of wavefront sensing has so far been seen in the objective
verification of spherocylindrical refraction, diagnosis
of complex or subtle conditions of the cornea, such
as keratoconus, dry eyes and cataracts, and in the magnitude
of induced aberrations after laser vision correction
procedures. Therapeutically, wavefront sensing has value
in attempts to correct naturally occurring and surgically
induced aberrations, and results, so far, have been
quite promising.
At its very basic, wavefront sensing uses a simple technique.
The patient stares ahead at a field and focuses on an
object. While doing so, a beam of light is projected
into the eye. This light is reflected off the back of
the eye and back out. The machine maps where the exiting
rays of light land. This map is then used to determine
what is going on in the eye. Earlier diagnostic methods
only looked at few data points. Some of the machines
that are available today look at nearly 2,000 data points,
providing a much more detailed map of the patient's
eye.
This diagnostic information can be used both to assist
in the development of the non-surgical correction of
visual problems through customized contact lens and,
to link to an excimer laser system for the surgical
correction of the problems. These surgical systems are
available outside the US and currently in clinical trials
here in the US.
There is an article
on line that may be of assistance.3
The focus of the article is on the marriage of the diagnostic
with the laser. While it discusses only one of the systems
under development, it does have some good overall information
in the first few paragraphs. Another article that may
be of interest appeared in EyeWorld
which recounts data presented at a meeting in early
2000.4
Limited numbers of the machines are available throughout
the US, and most of the companies listed below have
systems in place throughout the world. International
data presented was presented at the American Academy
of Ophthalmology annual meeting in New Orleans in 2001.
Some of the presentations were on the podium, others
were at the manufacturer's booths, presented by physicians.
In December 2001 one system was granted approval by
the US FDA for therapeutic use in treating decentered
ablations. We will to provide further data regarding
this application as it becomes available.The manufacturers
of excimer lasers systems have been working for several
years to develop customized ablation systems that tie
the wavefront diagnostic image of a patient's eye directly
to the surgical ablation map for the excimer lasers.
These laser systems have demonstrated very promising
results and are increasingly available outside the US.
However, clinical trials in the US are still on-going
for the systems. Again, we will provide more data once
it becomes available.
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