Surgery – Instruments – Corneal cutter or guide for corneal cutter
Reexamination Certificate
2001-10-24
2004-11-16
Reip, David O. (Department: 3731)
Surgery
Instruments
Corneal cutter or guide for corneal cutter
Reexamination Certificate
active
06818004
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to surgical apparatus and methods for performing lamellar keratotomies. More particularly, the invention relates to a positioning ring for temporarily immobilizing the eyeball, or ocular globe, such that the globe's cornea protrudes therethrough.
BACKGROUND OF THE RELATED ART
In a normal eye, parallel rays of light entering the eye become focused on the retina to create a sharp visual image. Anomalies in the overall shape of the eye, however, may result in image distortion by causing parallel rays of light entering the eye to become focused at a location other than the retina. Hyperopia, or farsightedness, occurs when the front-to-back measurement of the eyeball is too short, causing parallel rays of light entering the eye to focus behind the retina. In contrast, myopia, or nearsightedness, occurs when the front-to-back measurement of the eyeball is too long, causing parallel rays of light entering the eye to focus in front of the retina. Astigmatism occurs when the parallel rays of light entering the eye do not focus at a single point in the eye, but rather have a variable focus due to an aspherical cornea refracting light in a different meridian at different distances.
Glasses or contact lenses usually correct hyperopia, myopia and astigmatism but surgical corrective methods have become quite popular due to the inconvenience and discomfort of wearing glasses or contact lenses. One of these surgical corrective methods is laser-assisted in-situ keratomileusis (LASIK). During the LASIK procedure, a microkeratome is used to perform an incomplete lamellar keratotomy, which leaves a peripheral residue of corneal tissue uncut to act as a hinge. The hinge permits the corneal disk to be lifted for exposing and resecting the stromal layer with a laser. The tissue removed by the laser reshapes the stromal layer so that the stromal layer will sufficiently refract the light rays entering the eye to cause them to focus on the retina, producing a sharp visual image without the aid of glasses or contact lenses. After the laser completes the reshaping of the stromal layer, the corneal disk is folded back into its original position, using the hinge as a guide. Within minutes, the corneal disk adheres itself to the rest of the cornea and the LASIK procedure is complete.
There are many different designs for microkeratomes but certain aspects of their operation are similar. A suction ring is first affixed to the sclera and centered about the cornea so that the cornea extends through an aperture and above the suction ring. The diameter of the aperture in the suction ring through which the cornea extends is selected on the basis of the size of the cornea and the diameter of the corneal disk to be cut. The suction ring is held to the sclera by a vacuum induced in the area between the cylindrical ring and the eyeball. A float head having a flat, arcuate or oblique surface is then moved over the guide ring so as to compress the cornea into a shape that complements the surface. A cutting head carrying a blade is then moved across the suction ring so as to resect a corneal disk. The float head may be held stationary once it has compressed the cornea prior to the movement of the blade, or the float head may be moved with the blade head while maintaining contact with the cornea. The cutting blade is moved a predetermined distance substantially, but not completely, across the portion of the cutting plane that intersects the cornea. The movement of the cutting blade is restricted by an adjustable stop means, whereby the extent of hinge width formed on the corneal disk is adjustable. The cutting blade is then moved back across the suction ring to its original position, so that the suction ring can be removed and the resulting corneal disk can be folded back and secured over its hinge, exposing the corneal stroma to be reshaped by the laser.
While the use of the hinge has made corrective surgery easier and safer by helping to ensure that the corneal disk is replaced in its original position, the hinge has the disadvantage that it can potentially block a section of the ablation zone covered by the corneal disk hinge.
FIG. 1
shows a plan view of an ocular globe (eyeball) with the corneal disk
11
folded back over the hinge
14
, exposing the stromal layer
12
and the laser ablation zone
13
after an incomplete lamellar keratotomy. For a corneal disk cut with the existing microkeratomes, only about 60% to 70% of the circle diameter of the corneal disk may be safely used because of the interference caused by the hinge. In the example shown in
FIG. 1
, a 10 mm diameter corneal disk
11
is cut and folded back over the hinge
14
. The resulting laser ablation zone
13
has a diameter of only 6 mm because the hinge area plus a safety zone required to protect against laser damage to the hinge, is 2 mm wide and, because both the corneal disk
11
and the laser ablation zone
13
are circles, the same 2 mm of the diameter in the counter-lateral quadrant, or the opposing quadrant furthest from the center of the eye, cannot be used for a circular laser ablation. Therefore, in this example, of the original 10 mm diameter, only 6 mm can be used for laser ablation.
Using a smaller suction ring aperture diameter to reduce the diameter of the corneal disk may be especially harmful if the stromal zone exposed by the microkeratome is smaller than the laser ablation zone, as then ablation may occur over the hinge. This type of ablation damage, referred to as negative hinge syndrome, creates or produces an irregularity of the ablation with an inevitable astigmatic induction, loss of visual acuity, and a decrease in contrast sensibility.
To prevent negative hinge syndrome, surgeons performing LASIK will either obtain unnecessarily large corneal disks or move the suction ring toward the position where the hinge will be located to gain more stromal tissue exposure for the ablation. Obtaining unnecessarily large corneal disks increases the risk of complications from the higher vacuum required under the suction ring to hold the larger suction ring in place on the sclera during the incomplete lamellar keratotomy procedure. Using the higher vacuum increases the intraocular pressure, thereby placing eye structures, such as the retina, at risk. Moving the suction ring toward the position where the hinge will be located to gain more stromal tissue exposure creates a change in the anatomical coupling of the eye with the ring, therefore increasing the risks of suction loss and serious corneal damage during the incomplete lamellar keratotomy procedure.
The suction ring must be securely affixed to the sclera and the corneal region by the suction induced by a vacuum pump. On some eyes, the eyeball is aspherical to a larger degree than normal making it difficult to achieve a good suction seal between the sclera and the suction ring. A cornea with a higher degree of astigmatism will also make it more difficult to seal the corneal region against the aperture on the top end of the suction ring. The suction ring is a cylinder with a circular aperture on the top end through which the cornea is exposed for cutting. The bottom end of the suction ring is also circular and attaches to the sclera by suction induced by a vacuum, normally pulled through ports around the inside wall of the suction ring. A small vacuum pump is used to create the vacuum. To acquire the necessary suction to hold the suction ring in place on the eye, a seal must be maintained both around the bottom end of the suction ring with the sclera as well as the top aperture of the suction ring with the corneal region. This is illustrated in
FIGS. 2
,
3
and
4
.
FIG. 2
shows a properly fitted suction ring on an eye. A good suction seal is formed between the corneal region and the top aperture
25
and the sclera and the bottom end of the suction ring
24
. The suction chamber
21
is the volume inside the cylinder formed by the suction ring and sealed by the eye. The vacuum is induced through port
22
to the vacuum pump.
FIGS
Christian Steven L.
Davis D. Jacob
Reip David O.
Streets Jeffrey L.
Streets & Steele
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