SYSTEM AND METHOD FOR THE DELIVERY OF MEDICATIONS OR FLUIDS TO THE EYE
A method for delivering fluids, drugs, or medications to a patient's eye, and a system or apparatus for implementing the method, is disclosed. The system and method comprises the use of a corneal sponge to be deposited onto the cornea of the patient's eye while the patient's eyelids are maintained in open positions, and a scleral contact lens is disposed onto the sponge. The scleral lens has an irrigation fluid supply tube fluidically connected thereto for supplying a fluid, drug, or medication to the sponge which is saturated with the fluid, drug, or medication. Once the sponge and lens are inserted onto the corneal region of the eye, the patient's eyelids are closed thereby trapping and maintaining the sponge and lens upon the corneal region of the eye so as to permit the fluid, drug, or medication to be continuously supplied and applied to the corneal region of the eye.
This patent application is a divisional patent application of U.S. patent application Ser. No. 14/989,072 which was filed on Jan. 6, 2016.
FIELD OF THE INVENTIONThe present invention relates generally to a system and a method for the delivery of medications or fluids to the eye, and more particularly to a system or method for the delivery of medications or fluids to the eye in connection with corneal collagen crosslinking procedures.
BACKGROUND OF THE INVENTIONMany medical treatment procedures or techniques for treating various different eye conditions comprise processes, techniques, or methods for delivering medications or fluids to the eye in order to, for example, provide drug delivery to the eye or to remove materials or various substances from the eye. In connection with corneal collagen crosslinking procedures or techniques, for example, it is desired to frequently administer riboflavin to the eye. In accordance with such procedures, the riboflavin is typically dropped onto the eye every 1-5 minutes for a period of time extending between 20-30 minutes. Other medications or fluids, which may be utilized for treating other various different ocular conditions, such as, for example, infectious keratitis, which is an inflammation of the cornea caused by bacteria, viruses, fungi, and/or parasites, may comprise various antibiotics or anti-fungal agents. These fluids also often need to be applied to the eye several times within a 30 minute period. Current procedural techniques involve the frequent application of drops to the eye, or the use of high volumes of such fluids to the eye employing various irrigation systems comprising a feeding bottle fluidically connected to a contact lens-like device with open flow irrigation.
In view of the fact that many of the medications or fluids, that are particularly preferred for use in connection with the treatment of the aforenoted ocular conditions, may be in relatively short supply, and/or may be relatively expensive, it is desirable to retain a predetermined amount of the medication or fluid upon the cornea during the treatment procedure. In addition, because of the labor-intensive nature characteristic of the frequent drop administration procedures, which are necessarily performed by trained medical personnel, such procedures tend to be relatively costly. Accordingly, it would be desirable if procedures, techniques, or methods could be developed, and apparatus or a system for implementing such procedures, techniques, or methods, which would require less frequent human intervention. Furthermore, many of the medication or fluid application procedures require the patient to maintain his or her head in a predetermined position, or to maintain the eyes in a fixed mode, such as, for example, looking straight ahead, or still further, to have their eyelids held open for relatively long periods of time. All of these procedures may result in some level of discomfort to the patient, which is obviously not ideal.
A need therefore exists in the art for a new and improved method, and a system or apparatus for implementing such method, for delivering medications or fluids to the eye that will resolve the aforenoted problems or drawbacks characteristic of the current state of the art and that will achieve the following overall objectives. More particularly, a need exists in the art for a new and improved method, and a system or apparatus for implementing such method, for delivering medications or fluids to the eye which will be cost effective, which will be significantly more comfortable for the patient, and which will enable a sufficient amount of medication or fluid to effectively be constantly or continuously delivered or applied to the eye.
OVERALL OBJECTIVES OF THE INVENTIONThe overall objectives of the present invention are to overcome the drawbacks characteristic of, and encountered during, current procedures, techniques, or methods for applying various medications or fluids to a patient's eye, to render a method, technique or procedure for applying medications or fluids to a patient's eye that is significantly more comfortable for the patient being treated, and to enhance the efficiency and effectiveness of the medication or fluid delivery to the patient's eye as well as to constantly retain a predetermined amount of the medication or fluid upon the eye throughout the entire treatment procedure.
SUMMARY OF THE INVENTIONThe foregoing and other objectives are achieved in accordance with the teachings and principles of the present invention through the provision of a new and improved method, and a system or apparatus for implementing such method, for delivering medications or fluids to a patient's eye wherein, in accordance with a first embodiment of the method, a scleral contact lens, having an irrigation fluid supply tube attached thereto so as to effectively comprise a contact lens similar to the well-known Morgan lens, as disclosed within U.S. Pat. No. 3,664,340 which issued to Morgan on May 23, 1972, is one of the primary components used in accordance with the techniques or procedures utilized to carry out the method of the present invention. In addition to the scleral contact lens, with the irrigation fluid supply tube attached thereto, a porous corneal sponge, fabricated from a suitable cellulose or similar material, is operatively associated with the scleral contact lens. More particularly, in accordance with the method of the present invention, the eyelids of the eye to be treated are initially held open by means of the fingertips of the doctor or technician performing the treatment method or procedure of the present invention, and a topical anesthesia is applied to the cornea of the eye. The topical anesthesia may comprise any well known anesthesia commonly employed under such conditions such as, for example, tetracaine, proparacaine, lidocaine, or the like. The sponge, containing a small amount of the material or drug to be administered or delivered to the cornea of the eye, is then applied to the surface of the eye and centered over the cornea. The scleral contact lens, with the irrigation fluid supply tube attached thereto, is then effectively placed over the sponge, care being taken to ensure that the sponge and the scleral contact lens are effectively centered upon or mounted or seated directly over the cornea of the eye. In addition, it is important to gently push or depress the scleral contact lens, with its irrigation fluid supply tube attached thereto, onto the sponge such that the sponge is effectively disposed upon the cornea in a trapped state beneath the scleral contact lens. At this point in time, the patient's eyelids can then be closed so as to effectively entrap both the sponge and the lens upon the surface of the eye.
In addition to the foregoing, a syringe, containing the fluid, drug, or medication to be administered to the eye, is operatively connected to the free end of the irrigation fluid supply tube. One of the objectives of the method of the present invention is to provide a relatively low and constant volume of a high concentration of the particular fluid, drug, or medication to be administered or delivered to the eye. Accordingly, a suitable control device is interposed between the syringe and the scleral contact lens so as to in fact control the volume flow and line pressure within the irrigation fluid supply tube. The control device may be, for example, a stopcock type valve, a clamp, or any other suitable means which will limit or control the volume of the fluid flow of the particular fluid, drug, or medication to the corneal sponge and eye to a predetermined degree or volume amount. In accordance with the usage of these components, the plunger of the syringe will then be moved inwardly a predetermined amount so as to cause a relatively small amount of the fluid, drug, or medication to flow through the irrigation fluid supply tube and to effectively saturate the sponge which is disposed over the cornea of the eye. The stopcock or control device is then closed or adjusted, effectively trapping or con-trolling the flow of the fluid within the system between the stopcock and the sponge. Over time, tears within the patient's eye may tend to dilute the fluid, drug, or medication being delivered to the eye, and accordingly, the stopcock will then be opened or expanded, the plunger of the syringe will be pushed a predetermined amount further inwardly within the syringe whereby an additional amount of the high concentration fluid, drug, or medication will again be delivered to the sponge so as to maintain the same saturated with the fluid, drug, or medication to be delivered to the eye in order to treat the eye, and the stopcock again adjusted. It will be noted that all during this process, the patient is disposed in a reclined position, with his or her eyelids closed, so as to enhance the comfort level of the patient as much as possible.
In accordance with additional or, alternative embodiments of the pre-sent inventive method, it is to be noted that in lieu of a single irrigation fluid supply tube, a plurality of irrigation fluid supply tubes may be fluidically connected to the scleral lens in an equiangular circumferentially spaced manner so as to ensure the uniform distribution of the fluid, drug, or medication being supplied to the lens and sponge and ultimately to the eye. Furthermore, the scleral lens may effectively be eliminated whereby the irrigation fluid supply tube, or the plurality of irrigation fluid supply tubes, can be fluidically connected directly to the sponge. Still further, in lieu of the scleral lens and the sponge being separate components, they may be integrally affixed together whereby the combined assembly can be disposed over the cornea of the eye.
Various other features and attendant advantages of the present invention will be more fully appreciated from the following detailed description when considered in connection with the accompanying drawings in which like reference characters designate like or corresponding parts throughout the several views, and wherein:
Referring now to the drawings, and more particularly to
With reference therefore being made to
With reference initially being made to
In addition to the foregoing, and with reference being made to
In accordance with additional or alternative embodiments of the pre-sent inventive method and the structural components of the system of the present invention for implementing the noted method or procedure, it is to be noted that the scleral lens 102 may effectively be eliminated from the system illustrated, for ex-ample, within
Still further, it is also to be noted, as can readily be appreciated from
Still yet further, as can be readily seen or appreciated from
Obviously, many variations and modifications of the present invention are possible in light of the above teachings, and it is to be construed that such variations and modifications are effectively to be included within the claimed method and apparatus. For example, it is to be noted that the corneal sponges may comprise sponges having different thickness dimensions, different sizes, and may be fabricated from different materials comprising different porosity characteristics so as to predetermine saturation volumes and retention times with respect to the fluids, drugs, or medications being delivered to the cornea. The differently-sized corneal sponges can of course be used, for example, depending upon the size of the corneal region being treated. Still further, the corneal sponge can have a diametrical extent which is larger than that of the cornea per se whereby the outer peripheral edge portions of the corneal sponge will effectively be disposed in contact with the sclera, and in this manner, the eyelids will assuredly retain the corneal sponge is contact with the corneal surface of the eye when the patient's eyelids are moved to their closed positions. In a similar manner, the syringes may be characterized by different sizes so as to accommodate various volumes of the fluid, drug, or medication to be delivered. Still yet further, while the system of the present invention has been implemented for the treatment of one eye, the method, technique, or procedure can obviously be repeated for the patient's other eye, or yet alternatively, a bilateral embodiment of the system of the present invention is envisioned such that both eyes of the patient can be treated simultaneously. Yet still further, it is also to be noted that the state of the eye can be such that the epithelium of the cornea is intact, or the epithelium of the cornea has been removed or somehow otherwise altered. After treatment of the particular eye has been completed, the scleral lens and the corneal sponge, or the corneal sponge alone if the scleral lens was omitted from the system and the irrigation fluid supply tube was connected directly to the sponge, is removed from the patient's eye in accordance with a procedure or technique which is effectively the reverse of that described hereinbefore in connection with initial treatment of the patient. It is to be understood that within the scope of the appended claims, the present invention may be practiced otherwise than as specifically described herein.
KEY TO REFERENCE NUMBERS IN THE DRAWINGS
- 10—EYE
- 12—CORNEA
- 14—IRIS
- 16—LENS
- 18—SCLERA
- 20—UPPER EYELID
- 22—LOWER EYELID
- 24—FINGERTIPS
- 26—SURGICAL FORCEPS
- 100—FIRST EMBODIMENT SYSTEM
- 102—SCLERAL LENS OF FIRST EMBODIMENT
- 104—IRRIGATION FLUID SUPPLY TUBE OF FIRST EMBODIMENT
- 106—CORNEAL SPONGE OF FIRST EMBODIMENT
- 108—SYRINGE OF FIRST EMBODIMENT
- 110—CONTROL DEVICE OF FIRST EMBODIMENT
- 112—PLUNGER OF SYRINGE OF FIRST EMBODIMENT
- 200—SECOND EMBODIMENT SYSTEM
- 204—IRRIGATION FLUID SUPPLY TUBE OF SECOND EMBODIMENT
- 206—CORNEAL SPONGE OF SECOND EMBODIMENT
- 300—THIRD EMBODIMENT SYSTEM
- 302—SCLERAL LENS OF THIRD EMBODIMENT
- 304—MAIN IRRIGATION FLUID SUPPLY TUBE OF THIRD EMBODIMENT
- 304a-304e—MULTIPLICITY OF IRRIGATION FLUID SUPPLY TUBES
- 306—CORNEAL SPONGE OF THIRD EMBODIMENT
- 400—FOURTH EMBODIMENT SYSTEM
- 402—SCLERAL LENS OF FOURTH EMBODIMENT
- 404—IRRIGATION FLUID SUPPLY TUBE OF FOURTH EMBODIMENT
- 406—CORNEAL SPONGE OF FOURTH EMBODIMENT
Claims
1. A system for delivering a fluid, a drug, or a medication to a corneal region of a human eye so as to treat the corneal region of the human eye with the fluid, the drug, or the medication, comprising:
- a corneal sponge able to be disposed over the corneal region of the human eye, wherein said corneal sponge has a surface area which is substantially the same as the surface area of the corneal region of the human eye;
- a scleral lens disposed atop said corneal sponge for maintaining said corneal sponge in contact with the corneal region of the human eye; and
- an irrigation fluid supply tube connected directly to said scleral lens so as to supply the fluid, the drug, or the medication to said scleral lens which, in turn, is fluidically connected to said corneal sponge which is adapted to be disposed over the corneal region of the human eye so as to continuously deliver the fluid, the drug, or the medication to said corneal sponge whereby said corneal sponge will be continuously saturated with the fluid, the drug, or the medication such that the corneal region of the human eye is continuously treated with the fluid, the drug, or the medication.
2. (canceled)
3. (canceled)
4. The system as set forth in claim 1, wherein:
- outer peripheral edge portions of said corneal sponge and outer peripheral edge portions of said scleral lens are able to be disposed beneath the eyelids of the human eye when the eyelids of the human eye are disposed at their closed position whereby the eyelids of the human eye effectively trap said scleral lens and said corneal sponge beneath the eyelids of the human eye such that said corneal sponge is maintained engaged with the corneal region of the human eye.
5. (canceled)
6. The system as set forth in claim 1, further comprising:
- a syringe operatively connected to said irrigation fluid supply tube for forcing a predetermined volume of the fluid, the drug, or the medication through said irrigation fluid supply tube toward said scleral lens and said corneal sponge; and
- a control device operatively associated with said syringe and interposed between said syringe and said irrigation fluid supply tube for controlling the volumetric amount of the fluid, the drug, or the medication passing through said irrigation fluid supply tube toward said scleral lens and said corneal sponge.
7. The system as set forth in claim 2, wherein:
- said corneal sponge and said scleral lens comprise a one-piece integral assembly.
8. (canceled)
9. The system as set forth in claim 1, wherein:
- said irrigation fluid supply tube is fluidically connected to an axially central portion of said scleral lens.
10. (canceled)
11. (canceled)
12. The system as set forth in claim 1, wherein:
- said irrigation fluid supply tube has multiple irrigation fluid supply tubes operatively connected thereto wherein said multiple irrigation fluid supply tubes are operatively connected to multiple locations upon said scleral lens.
13. The system as set forth in claim 12, wherein:
- said multiple irrigation fluid supply tubes are disposed within an equiangular circumferential pattern so as, to uniformly distribute the fluid, the drug, or the medication to equiangularly spaced regions of said scleral lens and to equiangularly spaced regions of said corneal sponge.
14. A method for delivering a fluid, a drug, or a medication to a corneal region of a human eye so as to treat the corneal region of the human eye with the fluid, the drug, or the medication, comprising the steps of:
- disposing a corneal sponge over the corneal region of the human eye, wherein said corneal sponge has a surface area which is substantially the same as the surface area of the corneal region of the human eye;
- disposing a scleral lens over said corneal sponge such that said scleral lens will maintain said corneal sponge in contact with the corneal region of the human eye; and
- conducting the fluid, the drug, or the medication through an irrigation fluid supply tube which is connected directly to said scleral lens which, in turn, is fluidically connected to said corneal sponge disposed over the corneal region of the human eye so as to continuously deliver the fluid, the drug, or the medication to said corneal sponge whereby said corneal sponge will be continuously saturated with the fluid, the drug, or the medication such that the corneal region of the human eye is continuously treated with the fluid, the drug, or the medication.
15. (canceled)
16. (canceled)
17. A method as set forth in claim 14, further comprising the steps of:
- manipulating the upper and lower eyelids of the human eye to be treated such that the upper and lower eyelids are expanded with respect to each other;
- inserting said corneal sponge into the human eye so that said corneal sponge is disposed over the corneal region of the human's eye and inserting said scleral lens, having said irrigation fluid supply tube fluidically connected thereto, atop said corneal sponge; and
- releasing the upper and lower eyelids of the human eye so as to effectively close the upper and lower eyelids of the human eye such that outer peripheral edge portions of said corneal sponge and outer peripheral edge portions of said scleral lens are able to be disposed beneath the eyelids of the human eye when the eyelids of the human eye are disposed at closed positions whereby the closed eyelids of the human eye will effectively trap said corneal sponge and said scleral lens beneath the eyelids of the human eye such that said corneal sponge is maintained in engagement with the corneal region of the human eye.
18. (canceled)
19. The method as set forth in claim 14, further comprising the steps of:
- connecting first end portions of multiple irrigation fluid supply tubes to said irrigation fluid supply tube; and
- connecting second end portions of said multiple irrigation fluid supply tubes to multiple locations upon said scleral lens.
20. (canceled)
21. The method as set forth in claim 19, comprising the step of:
- disposing said multiple irrigation fluid supply tubes within an equiangular circumferential pattern so as to uniformly distribute the fluid, the drug, or the medication to equiangularly spaced regions of said scleral lens.
Type: Application
Filed: Dec 30, 2018
Publication Date: May 9, 2019
Inventors: DAVID R. HARDTEN (EXCELSIOR, MN), RICHARD L. LINDSTROM (WAYZATA, MN)
Application Number: 16/236,580