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This invention relates to a method and apparatus for controlled corneal
ablation of the human cornea to achieve refractive correction of either
myopia, hyperopia, regular or irregular astigmatism, and to minimize the
effects of presbyopia. More particularly, the present invention utilizes
electromagnetic radiation such as an ultraviolet laser at a wavelength of
193 nm whose radiation is intercepted and subdivided by a bundle of
optical fibers having their radiation emitting ends arranged to
simultaneously expose the optically used corneal surface to radiation
modulated by a contact lens constraining an inert UV absorbing liquid to
produce the desired optical reshaping and at the same time minimizing
exposure of other eye tissues to the radiation.
BACKGROUND OF THE INVENTION
Recent investigations have demonstrated that UV far (ultraviolet) radiation
produced by an excimer laser at a wavelength of 193 nm can ablate (remove)
corneal tissue with minimal trauma, loss of transparency or scarring. The
ablative process that occurs using this far UV wavelength region primarily
results from the breakup of intramolecular bonds as reported by Trokel,
et. al., in the American Journal of Ophthalmology, Volume 96, No. 6,
December, 1983, Entitled: "EXCIMER LASER SURGERY OF THE CORNEA". This
action is in contrast with that produced by higher wavelength laser
radiation in the infrared region where tissue destruction results from
thermal heating and the precision of tissue removal is much degraded.
The lens of the eye will absorb all 193 nm UV radiation by the application
of Beer's law of light transmission given by T=10.sup.-ad, where T is the
transmission (100%=1.0), a is the absorbance and d is the thickness of the
material. For bovine lenses a=1360/cm at 193 nm, a value close to that of
human eye lenses. Thus 90% absorbance product of a and d equal to 1.0
i.e., d=1/1360=7.35 um (microns). For thicknesses 10 times this value, the
transmission through the lens would be 1 part in 10 billion. Thus, it
appears that the lens will totally protect the retina of the eye from 193
nm UV. However, very low levels of 193 nm UV, such as might be able to
penetrate the cornea and aqueous humor could possibly damage the lens in a
manner similar to longer wavelength UV radiation causing cataracts.
Therefore, precaution to avoid exposing the lens to any amount of 193 nm
UV is either necessary or desirable.
Some experimentation with in-vivo eyes using total corneal surface ablation
with 193 nm UV has shown a tendency towards some hazing/cloudiness of
vision. The clouding effect suggests that the angle of impingement of UV
may be critical.
There presently exist a number of techniques to modify corneal shape using
lasers for purposes of refractive correction. These include radial
keratotomy, lamellar keratectomy correction (keratomileusis), and direct
corneal shaping via ablation. Baron, is U.S. Pat. No. 4,461,294,
implements the first of these (radial keratotomy) by imbedding laser light
absorbing particles in a radial pattern, then vaporizing these particles
by laser radiation to produce the radial scar tissue characteristic of the
technique. Trokel, et. al., discussed above, and European Patent No. 0 151
869 discuss full surface corneal ablation using the excimer laser. In the
Trokel paper and the European patent, no means for protecting of critical
eye tissue is given. Belgorod, in U.S. Pat. No. 4,724,522, describes an
apparatus and method allowing full protection of eye tissue.
The present invention is uniquely distinguished from the present known
prior art in regard to both apparatus and method: In Baron, the method is
limited to performing radial keratotomy which mandates the formation of
scar tissue (eschewed in the present invention); also, the opaque contact
lens therein plays no role in corneal shaping, serving only to shield the
eye from laser radiation; and the reference to fiber optics is solely for
delivering radiation along the radial slits. In Belgorod's apparatus, the
system of mechanical rotational and linearly transrotational mirror
elements is inherently complex--requiring high precision in construction
and application to achieve the desired ablative sculpting by the excimer
laser. This contrasts with the present invention, which rather than
sculpting the cornea one area at a time, operates simultaneously over the
total cornea, doing so with minimal precision requirements.
SUMMARY OF THE INVENTION
The object of the present invention is to provide a system for corneal
reshaping to achieve refractive correction of refractive errors of the
human eye.
According to the present invention, there is provided a method and
apparatus wherein an electromagnetic wave generator, preferably a far UV
laser (wavelengths less than 200 nm) whose collimated output beam of
radiation is captured by one end of the bundle of small diameter far UV
transparent optical fibers, the other end of said bundle placed in close
proximity with the cornea where individual fibers are selectively angled
by means of a decollimating matrix to conduct the UV radiation to the
cornea while at the same time minimizing exposure to far UV radiation of
all other tissues. Selective attenuation of UV radiation intensity to
ablate a desired corneal surface is accomplished by passing the
decollimated radiation through a UV transparent lens, which lens
constrains an inert UV absorbing liquid between it and the cornea.
A device for full surface ablation of the in vivo/in situ or in vitro
cornea consisting of an arrangement of ultra violet transmitting fibers,
limited in number and size only by the principles of multi-mode or single
mode fiber optic physics and limited in length only by the UV absorption
properties of the material used. The optical fibers intercepting a beam of
UV radiation of desired cross sectional area at one end and at the other
end, in proximity with the cornea, each fiber being directed by means of a
decollimating matrix interface wherein the angle of incidence upon the
cornea of UV radiation from each fiber, the angle of cleavage of each
fiber, the geometrical pattern arrangements of fibers and the variation of
refractive indices and UV arrangements of fibers and the variation of
refractive indices and UV absorptive properties of fibers, intervening
intensity modulating filters and liquids is unrestricted.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view which shows the excimer laser fiber optic
matrix system for ablating the cornea of the eye to achieve refractive
correction according to the present invention;
FIG. 2 is an enlarged partial view of FIG. 1;
FIG. 3 is an enlarged view in section illustrating a decollimating matrix.
DETAILED DESCRIPTION OF THE INVENTION
Referring to FIG. 2 which shows a human eye, numeral 1 denotes the vitreous
humor at the rear of which appears the retina 2 and forwardly the lens 3,
iris 4 and cornea 5.
FIG. 1 shows the components of the system and their interrelation to one
another. Beginning with the excimer laser 10, its collimated beam 11 is
aligned with a cylindrical bundle 12 of quartz fibers, each on the order
of 20-100 um diameter. The fibers then terminate in a decollimating matrix
14 consisting of a flexible plastic disk. Here, the term matrix is used to
emphasize the fact that each fiber element is inserted into the flexible
plastic at a specified angle of incidence. Then, this matrix is placed
over a custom ground quartz contact lens 6 (of zero power)--the curvature
of the inside surface being the predetermined optimum corneal curvature
determined for the particular patient. Lastly, a liquid 7 is placed
between the contact lens and corneal surface 5 and sufficient pressure is
applied to prevent any air voids. The characteristics of the liquid are
(1) chemical inertness, and (2) an ultraviolet absorbance factor
proportional to depth.
The basic principle of operation is as follows: Each fiber receives an
equal amount of ultraviolet flux which is then transmitted to the matrix.
The incident flux from each fiber is injected at a prescribed angle by the
matrix into the contact lens/inert liquid 7 interface where it is
attenuated proportional to the depth of the liquid.
FIG. 2 given an illustration of how corneal ablation can be controlled to
correct for myopia. As shown, the contact lens 6 surface is shallower than
the surface of the cornea. Then, because the ultraviolet absorbing liquid
7 is shallower at the center of the cornea than the periphery, the
greatest rate of ablation occurs at the center, gradually diminishing
towards the periphery. The overall effect is that the shape of the cornea
is ablated to approach that of the inner surface of the contact lens.
The cross sectional illustration in FIG. 2 also shows one possible scheme
for orientation of the fibers. Here, the angling is chosen to minimize
refracting remanent light flux (shown by the dotted lines) to the central
axis of the eye while still maintaining the desired uniformity of flux on
the cornea itself.
Ideally, the liquid 7 should be inert, to avoid any chemical reaction with
corneal tissue, should attenuate (but not block) UV radiation, and should
have high (inter/intra) molecular bonding so as to minimize
ablation/vaporization of the liquid 7 itself. Glycerin (glycerol) is an
example of a liquid approaching these desired properties because it begins
to attenuate UV radiation below 220 nm, is relatively inert and nox-toxic.
Further, glycerin's high boiling point (290.degree. C.) and high energy of
formation (-668 kJ/mol) indicate a considerably higher molecular bonding
than is associated with corneal tissue. Consequently, what radiation is
absorbed by the glycerin liquid will be converted into heat thereby
raising its temperature, but the glycerin liquid will experience little
ablation/vaporization. Because it is anticipated that the cornea will be
ablated for a number of periods each lasting only several seconds, the
problem of heat buildup in the liquid (e.g. glycerin) can be limited.
Also, after each treatment period, the fiber optic bundle, decollimating
matrix, and/or contact lens would be removed, liquid (glycerin) be flushed
from the cornea along with ablation products contained therein. For longer
periods of treatment time it may be desirable to provide for a continuous
laminar flow of the liquid between contact lens 6 and cornea 5 by means of
capillary tubes providing for a continual removal of ablation products
while avoiding heat buildup in the liquid 7.
The advantages and novelty of the system are:
1. Simultaneous ablative processing of the full corneal surface, obviating
such problems as laser output variations versus time, criticality of
corneal positioning, and excessive time requirements otherwise required in
corneal shaping.
2. Inherent iterative convergence of the technique--the corneal shaping
always proceed in the direction of matching the corneal surface with that
of the contact lens. This characteristic enables a degree of optical
precision and predictability unattainable with other methods of corneal
refraction adjustment.
3. Safety both in regard to the minimization of ultraviolet flux into the
eye and the fact that the technique is entirely non-invasive.
4. FIG. 3 shows a modification similar to the system shown in FIGS. 1 and 2
except for the insertion, in the system, of an ultraviolet filter 13 of
desired non-uniform transparency to ultraviolet across its surface.
FIG. 3 shows an embodiment of the invention offering minimal complexity
both in regard to design and application. Beginning with the exciter laser
10, its collimated output beam is aligned with a cylindrical bundle of
fibers 12, all parallel with one another and each on the order of 20 to
100 um in diameter. The fibers 12 decollimate the collimated output beam
by terminating in a plastic decollimating matrix 14 which supports and
directs the fibers to deliver the UV radiation, simultaneously and at
angles to all portions of the cornea, angling of each subdivided beam
emerging from the optical fiber is always away from the optical axis of
the eye, so that no radiation can reach the retina 2 shown in FIG. 2.
Further, the small amount of radiation entering the cornea 5, of the eye
is directed to the peripheral regions of the eye, thereby avoiding
exposure to the lens 3 and the iris. Next, the matrix 14 may be contoured
to fit over a quartz contact lens, the corneal-side curvature of which is
predetermined for the particular patient. Such a lens may be used to
accommodate particular requirements or preferences. A liquid interface
will be constrained between the contact lens and the corneal surface 5.
When a lens is not used, the liquid will be constrained between the cornea
and the confronting surface of the decollimating matrix. The properties of
the liquid interface are inertness with respect to corneal tissue;
resistance to ablation from the UV radiation; and a UV absorbance (thermal
conversion) proportional to the depth of the fluid.
Because of the existing limitation of attenuation of far UV radiation in
quartz fibers (namely, some 30% per mm in the 200 nm region), the length
of the fiber optic assembly 12 is preferably restricted to about 1 to 2
mm. As such, the combination of fiber-optic bundle, decollimating matrix,
and contact lens resembles a single thick contact lens, as shown in FIG.
3. Here the laser output is moved closer to the eye, and to avoid
inadvertent exposure of non-targeted eye/skin areas, baffling 15 is
provided.
When corneal ablation to correct myopia is undertaken, the matrix 14 and
contact lens when used in proximity with the cornea, is shallower than the
surface of the cornea. The film thickness of the UV absorbing fluid is
shallower at the center of the cornea than at its periphery, the greatest
rate of ablation occurs at the center, gradually diminishing towards the
periphery. The overall effect is to ablate the cornea so the its shape
automatically approaches that of the contact lens surface, thereby
correcting the illustrated myopic (nearsighted) condition.
The angled array of fibers in the decollimating matrix region is shown as
one possible orientation of the fiber strands near the optical axis of the
eye, this central region of the cornea can be uniformly irradiated while
directing the beams of radiation from each of the fibers away from the
central axis (on which the retina of the eye lies).
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