RU2344799C1 - Method of medicine transport to eye cornea - Google Patents

Abstract

FIELD: medicine; ophthalmology.

SUBSTANCE: soft contact lens with through drainage orifices distributed regularly over its surface is set on cornea. Second lens with central through orifice is installed over the first contact lens symmetrically and coaxially to it with a gap. Tube from a vial with medicine enters central through orifice of upper lens and is split into several parts distributed regularly over the internal surface of upper contact. Medicine is delivered by instillation over regular time intervals to the centre of upper contact lens and distributed regularly over the whole surface of lower soft contact lens passing to cornea surface through drainage orifices.

EFFECT: improved treatment efficiency due to constant and regular medicine transport, distribution and effect on damaged cornea.

2 ex, 1 dwg

Description

The invention relates to the field of medicine - ophthalmology.

In infectious diseases of the cornea, continuous irrigation of the cornea with an antibiotic is necessary. For local prolonged treatment of inflammatory diseases of the cornea, ophthalmic medicinal films and therapeutic soft contact lenses soaked in antibiotic are used.

Ophthalmic medicinal films have certain advantages compared with other dosage forms of drug delivery to the cornea and their accurate dosage, see Krasnov MM “Ophthalmic medicinal films for the provision of first medical and specialized care for eye damage, damage to the organ of vision.” Kirov. - L., 1984, T. 214, p. 42-49. This drug film is placed in the conjunctival sac, in which it is wetted with tear fluid and after 10-15 seconds becomes elastic due to the formation of a monolayer of the polymer solution. Within 40-50 seconds, the eye adapts to the injected ophthalmic drug film. After 10-15 minutes, deformation of the film is observed, after 20-30 minutes it turns into a viscous clot of the polymer and after 75-90 minutes the polymer completely dissolves. The resulting solution containing the drug substance is distributed in the conjunctival cavity and creates a thin transparent film on the surface of the eyeball, because the coefficients of refraction of the solution and tear fluid are the same. Since the dissolution of the ophthalmic drug film occurs gradually, the drug enters the ophthalmic medium for a predetermined period, which allows for a constantly maintained concentration of the drug. The basis of the ophthalmic drug film consists of polymers of acrylamide or its copolymers with some acrylic and vinyl monomers. Therefore, a method of delivering a drug to the cornea is to dissolve the ophthalmic polymer drug film, which includes the drug, due to the tear fluid of the eye.

The disadvantages of this solution are: when a medicinal film is placed in the lower conjunctival arch, a small amount of the drug enters the cornea, the drug does not flow uniformly, there is no direct and continuous irrigation of the cornea and a change in the rate of administration, impossibility of prolonged irrigation with the drug, there is no possibility of additional administration of the drug and other medicines, then for each medicine you need to have your own film, you need to have a special device for If this film is dissolved, when the film is dissolved, the polymer that is not needed by the eye gets into the eyes; the release of such films is carried out only abroad. Therefore, this method of drug delivery to the cornea is inefficient, uneconomical and low-tech.

The closest way to deliver a drug to the cornea is to use a therapeutic soft contact lens, impregnated with a drug installed on the cornea of the eye, see A.A. Kibaev, E.I. Shapiro. “Contact correction of vision”, M .: publishing house “LDM” Service, 2000, p. 64-66. The properties of the hydrophilic polymers made it possible to use contact lenses pre-saturated with the drug for introducing drugs into the cornea of the eye, i.e. isolation of a drug from such a polymer lens — use as a method of delivering a drug to the cornea of the eye. In the treatment of a number of diseases of the cornea of the eye, this method of drug delivery has some success and is not inferior to conventional therapeutic effects. There are publications of their use in ophthalmic surgery. It was found that saturation of the contact lens, for example, with hydrocortinsone, is carried out for 6 hours. The material of such a lens makes it possible to achieve high adsorption ability with respect to various substances in solutions, to precisely set and continuously maintain the most effective concentration of the preparation, for example, polycarpin, hydrochloride. The use of such a lens is effective as protection against damaged cornea in case of injuries after surgery, if necessary, the introduction of drugs with pronounced side effects, or with the introduction of toxic drugs.

The disadvantages of this method of drug delivery to the cornea of the eye through the release of a drug from a soft contact eye lens are: uneven (jerky) drug intake, with the drug being initially delivered at a high concentration, decreasing over time due to dissolution of the lacrimal fluid, and therefore repeated applications are required, i.e. there is no possibility of long-term maintenance - irrigation of a high concentration of drugs. After conducting experimental studies on the sorption and desorption of antibiotics from a polymer soft contact lens, it was revealed that the release of the antibiotic occurs within an hour. In addition, there are no: uniform distribution of drugs, the possibility of adding another drug, changes in the rate of entry and generally irrigation of the cornea with the drug, the possibility of a wider choice and speed of drug change. This method of drug delivery to the cornea is ineffective both in observing the constancy of its concentration and in the time of its administration, irregularity of irrigation, there is no constant drug delivery for a long period of its administration. For each infectious disease of the cornea, it is necessary to have a contact polymer eye lens soaked with antibiotic, and with the ongoing development of new drug developments, this requires a lot of time and money. The application of this method is possible only in highly professional medical institutions and hospitals (hospitals), this method does not have widespread use in medical practice.

The technical result of the proposed solution is: increasing the effectiveness and efficiency of treatment due to the constant and uniform flow, distribution and effect of the drug on the damaged cornea of the eye, the possibility of changing the speed of drug delivery, increasing the efficiency and adaptability of the method of drug delivery to the cornea, increasing the efficiency of using the proposed method , availability and simplicity of the solution, the possibility of use during irrigation and other preparations.

This result is achieved in that in the method for delivering the drug to the cornea of the eye, which consists in delivering the drug to the cornea by wetting the drug with a soft contact lens mounted on the cornea of the eye, the drug is instilled uniformly at regular intervals to deliver the drug to the lens surface dropwise and centered, evenly distributing it over its surface, they pass the medicine through the drainage holes of the lens onto the surface of the cornea, irrigating it.

The invention consists in the combination of essential features sufficient to achieve the invention a technical result.

An essential sign of the method of administering the drug, which coincides with the sign of the prototype, is: A - drug delivery to the cornea of the eye by wetting the drug with a soft contact lens mounted on the cornea of the eye.

An essential distinguishing feature of this method are: B - instillationally uniformly at regular intervals delivering the drug on the lens surface dropwise and centered, distributing it evenly on its surface; In - pass the medicine through the drainage holes of the lens on the surface of the cornea, irrigating it.

The method of drug delivery to the cornea of the eye is carried out by installing a soft contact ophthalmic lens 1 (see drawing) on the cornea 2 of the eye and wetting it with liquid drug coming from the vial 3 with the medicine through a tube 4 connected to the vial 3. The second end 5 of the tube 4 enters the through central hole 6 of the second contact lens 7 mounted symmetrically and coaxially on the first contact eye lens 1 with a gap 8. The second end 5 of the tube 4, located in the gap 8 of the lenses 1, 7, is split into separate parts - 9 and evenly distributed over the inner concave surface of the second lens 7. Throughout the entire area of the first lens 1, through drainage holes 10 are made. The drug 11 from the bottle 3 uniformly instillation flows continuously through the opening of the tube 4 into the gap - a gap 8 between the lenses 1, 7, also spreads over the mustache 9 of the tube 4, along the inner surface of the second lens 7 and comes in drip through the drainage holes 10 of the lens 1 to the cornea 2, irrigating it. The drug enters the evenly distributed drainage holes 10 over the entire area of the first contact ophthalmic lens 1 through the central hole 6 of the lens 7 and the mustache 9 evenly distributed on the inner surface of the lens 2, thereby obtaining a uniform flow of the drug to the cornea 2.

Using the proposed method of drug delivery - an antibiotic such as levofloxacin to the cornea, they treat infectious eye diseases, such as bacterial keratitis. Polymeric materials, for example hydroxyethyl methacrylate, are used as contact lens materials. The radius of curvature of the inner surface of the second lens 7 is made smaller than the radius of curvature of the outer surface of the first contact eye lens 1, which determines the gap "S" between the lenses, equal to from 0.5 to 2 mm.

Consequently, the drug is drip evenly at regular intervals, without changing its concentration, uniformly enters the entire surface of the cornea for several hours (maybe 3 or more) through the drainage holes of the contact eye lens mounted on the cornea of the eye.

Example No. 1. In the treatment of patient A. diagnosed with ulcerative streptococcal keratitis of the right eye, the proposed method of delivering the drug to the cornea using uniform drip irrigation of the cornea of the eye with levofloxacin through the drainage holes of the contact eye lens, uniformly wetting the latter with instillation of a constant and uniform flow of the drug. Continuous irrigation of the cornea with levofloxacin was carried out for 2 hours 2 times a day. Significant positive dynamics were noted. On the second day, relief of pain, the disappearance of the subjective sensation of a foreign body was noted. On the third day, there was a cessation of mucopurulent departments from the conjunctival cavity and a significant decrease in corneal infiltrate. By the end of the week there was a complete resorption of the infiltrate. Full restoration of the corneal epithelium occurred after 8 days.

Example No. 2. In the treatment of patient B. diagnosed with multiple erosive keratitis of the left eye, the proposed method for the delivery of the drug levofloxacin to the cornea of the eye was used. That is, uniformly drip irrigating the cornea through the drainage holes of a soft eye contact lens using uniform instillation flow and drug distribution in the gap between two lenses placed on top of each other and on the cornea of the eye. Continuous and uniform irrigation of the cornea of the patient occurred within 3 hours 1 time per day with a solution of levofloxacin for a week. The patient well tolerated the proposed method of drug delivery. Significant positive dynamics were noted. On the second day, there was a decrease in pain, the disappearance of the subjective sensation of a foreign body. On the third day, there was a complete relief of pain, the cessation of mucopurulent departments from the conjunctival cavity and a significant decrease in corneal infiltrate. By the end of the week there was a complete resorption of the infiltrate. Complete restoration of the corneal epithelium occurred ten days later.

Using the method of drug delivery to the cornea of the eye in comparison with the prototype allows to increase the effectiveness and efficiency of treatment by means of constant and uniform supply, distribution and exposure of the drug to the damaged cornea of the eye, the possibility of changing the rate of drug delivery, manufacturability and cost-effectiveness of the proposed method, its availability and ease of use due to the fact that in the method of drug delivery The drug is distributed evenly to the cornea along the surface of the cornea, instillation uniformly at regular intervals to deliver the drug to the cornea dropwise and centered, pass it through the drainage holes of the lens, irrigating the cornea. The proposed method for drug delivery allows you to use several drugs in one bottle, and changing the bottle with the right drug, that is, you can use a wide selection of drugs. In this method, a direct, continuous, long, with a possible time adjustment, irrigation of the cornea is carried out over the entire area of the affected area of the cornea. The method is available for use by paramedical personnel, does not require long preparation before use. The method of administering the drug to the cornea has been tested in the treatment of bacterial keratitis of the eyes in medical practice, has shown good results and can be recommended in the treatment of infectious eye diseases.

Claims (1)

A method for delivering a drug to the cornea of the eye, which consists in delivering the drug to the cornea by wetting the drug with a soft contact lens mounted on the cornea of the eye, characterized in that a soft contact lens is installed on the cornea with through-hole drainage holes evenly distributed over the entire area, over it with a gap, symmetrically and coaxially establish a second lens having a central through hole into which the tube from the drug vial enters, n and the inner surface of the second lens, the tube splits into parts evenly distributed over the inner surface of the second lens, the drug is instillatively delivered at regular intervals centered on the second lens, after which the drug is evenly distributed over the entire surface of the soft contact lens, entering the corneal surface through the drainage holes.