RU2115413C1 - Irrigation solution "intrasol" - Google Patents

Abstract

FIELD: medicine, ophthalmology. SUBSTANCE: irrigation solution has the following components, g/l: sodium dehydrogen phosphate, 0.018-0.072; sodium hydrogen phosphate, 0.079-0.141; sodium chloride, 8.50-9.50; L-carnosine, 0.5-20.0; and purified water, the balance; pH = 6.8-7.6. Solution can be used for replacement of moisture of eye anterior chamber and its washing out and other eye tissues at surgery operations. EFFECT: decreased trauma and edema of eye cornea, decreased loss of cornea endothelial cells. 3 cl, 5 ex

Description

 The invention relates to medicine, namely to ophthalmology, and can be used to replace moisture in the anterior chamber of the eye, as well as rinse the anterior chamber of the eye and other tissues of the eye during surgical interventions.

 A physiological saline solution is known, including 0.9% sodium chloride, which is widely used as an irrigation solution in the practice of domestic ophthalmic surgery (Bulletin of Ophthalmology, 1970, N 5, 80-82).

 The disadvantage of this solution is that it is not a buffer, and its pH depends on the quality of the water used for its preparation, and varies from 5.0 to 7.0. This has a detrimental effect on the vital activity of endothelial cells, corneal epithelium and other eye tissues.

 Known solution BSSplus (balanced salt solution), which includes sodium, potassium, calcium and magnesium chlorides, as well as monosubstituted sodium phosphate, sodium bicarbonate, dextrose and glutathione. The solution has a pH of 7.4. (Arch. Ophtalmol. V. 93, 1978, p. 516).

The disadvantage of this solution is that its buffering properties are ensured by the presence of sodium bicarbonate. Such a system is unstable and its pH can increase due to the release of CO ₂ .

 The objective of the invention is to create a stable buffer solution, similar in salt composition to the moisture of the anterior chamber, having a certain pH value and containing a substance that stabilizes cell membranes.

 The technical result is to reduce the morbidity of surgical intervention, reduce corneal edema, reduce the loss of endothelial cells of the cornea.

The technical result is achieved by the fact that an irrigation solution comprising sodium chloride, monosubstituted sodium phosphate and water, according to the invention additionally contains disubstituted sodium phosphate and L-carnosine in the following ratio of components in g / l:
Monosubstituted sodium phosphate - 0.018 - 0.072
Disubstituted sodium phosphate - 0.079 - 0.141
Sodium Chloride - 8.50 - 9.50
L-Carnosine - 0.5 - 20.0
Purified Water - Else
and has a pH of from 6.8 to 7.6 inclusive.

One embodiment of the invention is that in which the above irrigation solution further comprises a dextran or a water-soluble cellulose derivative (an alkyl derivative, or a carboxyalkyl derivative, or a hydroxyalkyl derivative of cellulose) in an amount of:
Dextran or water soluble - 1.0 - 50.0 g / l
The cellulose derivative is 0.1 to 20.0 g / l.

 In this composition, sodium chloride provides isotonicity of the irrigation solution to tissues and cells. Isotonicity is characterized by osmolarity (mOsm) and depends on the concentration of electrolytes in the solution. With less sodium chloride less than 8.5 g / l, the osmolarity of the solution will be below 288 mOsm; and with a larger amount of sodium chloride, more than 9.5 g / l, the osmolarity will be above 322 mOsm, which is a non-physiological value for human cells and tissues.

 Mono- and disubstituted phosphates are the natural ingredients of a buffering mechanism that maintains a constant pH in tissue fluids. The indicated concentration of phosphate ions in solution correlates with the phosphate content in the moisture of the anterior chamber of the eye (A. Peary. Eye Biochemistry. - M .: Medicine, 1968).

 The pH of the solution varies from 6.8 to 7.6, which corresponds to the physiological value in various conditions of the eye.

 L-Carnosine is a natural antioxidant and protector of the aqueous membrane and lipid phase of biological membranes (Biochem J., 1994, Dec 1; 304 (pf2): 509-16). The amount of L-carnosine is based on experimental data. For this purpose, chinchilla rabbits were replaced with moisture in the anterior chamber by a solution of carnosine or a 0.9% sodium chloride solution (as a control). At a carnosine concentration of 0.5 g / L to 20 g / L, a decrease in the corneal stack was observed biomicroscopically as compared to the control. At a lower concentration of carnosine than 0.5 g / l, the effect was not achieved. At a concentration of carnosine greater than 20.0 g / l, narrowing of the pupil was observed, that is, an undesirable side reaction.

 Dextran or water-soluble cellulose derivatives are colloidal osmotic agents that prevent corneal swelling and also maintain an aqueous buffer membrane on the surface of cells. This is especially true for longer operations with a large volume of irrigation solution, for example, with phacoemulsification, vitrectomy.

 The amount of dextran and a water-soluble cellulose derivative was determined experimentally. For this, freshly removed rabbit corneas were placed in the test irrigation solution and the swelling was measured after 2 hours. The experiment showed that at a dextran concentration of less than 1.0 g / l, the corneal swelling was comparable to the control. As a control, a 0.9% sodium chloride solution was used. At a concentration of 1.0 - 50.0 g / l, the cornea practically did not swell. At a dextran concentration of more than 50.0 g / l, no increased effect on corneal swelling was observed.

 A similar experiment with a water-soluble cellulose derivative (with each of these separately) showed that at a concentration of 0.1 - 20.0 g / l, corneal swelling was not observed. At a concentration below 0.1 g / l, there was no effect of a decrease in corneal thickness compared to the control. At concentrations above 20.0 g / l, there was no effect of enhancing the effect on the thickness of the cornea.

 All components of the irrigation solution are stable and can withstand autoclaving sterilization without changing the properties of the solution.

 An irrigation solution is prepared as follows.

Accurate weights of sodium chloride, monosubstituted sodium phosphate, disubstituted sodium phosphate and carnosine in an amount corresponding to the limits according to the formula are weighed on an analytical balance. Samples of salts are transferred to the flask and the solution volume is adjusted to 1 liter with purified water. Mix the solution until the samples are completely dissolved. A portion of L-carnosine is added to the resulting solution and mixed again until the latter is dissolved. Measure the pH of the solution using a pH meter. The solution is filtered through a 0.22 - 0.45 micron filter and poured into vials. The bottles are corked and sterilized in an autoclave for 40 minutes at 120 ^o C.

In the case of using claim 2 of the formula dextran or one of the listed water-soluble cellulose derivatives (an alkyl derivative, or a carboxyalkyl derivative, or a hydroxyalkyl derivative of cellulose) in an amount according to the formula, dilute in 0.5 l of a cooled salt solution (sodium chloride, mono- and disubstituted sodium phosphates ), prepared according to claim 1 of the formula and incubated at a temperature of 4 - 12 ^o C for a day. Next, the mixture is stirred until complete dissolution and filtered through a 0.45 μm filter. The amount of L-Carnosine according to the formula of claim I is dissolved in 0.5 L of a salt solution and added to 0.5 L of a saline solution of dextran or one of the water-soluble cellulose derivatives. The solution is filtered through a 0.22 - 0.45 μm filter, poured into vials, sealed and sterilized in an autoclave for 40 minutes at 120 ^o C.

 The method is illustrated by examples.

 Example 1

8.5 g of sodium chloride, 0.072 g of monosubstituted sodium phosphate, 0.079 g of disubstituted sodium phosphate are weighed. Weighed portions are placed in a flask and the solution volume is adjusted to 1 liter with purified water. Stir until the precipitate is dissolved. 0.5 g of L-carnosine was added to the solution and stirred until dissolved. Measure the pH of the solution on a pH meter. The pH value is 6.81. The solution is filtered through a 0.45 μm filter, placed in 0.25 L vials, sealed and sterilized in an autoclave for 40 minutes at 120 ^o C.

 Irrigation solution was used for extracapsular cataract extraction (EEC) in patient K. The scope of surgery is standard. The volume of irrigation solution was 25 ml. A day after the operation, the cornea is transparent. Corneal edema was absent. Endothelial cell loss was 5%.

 Example 2

 An irrigation solution was prepared analogously to example 1, using weighed components: sodium chloride 8.9 g, monosubstituted sodium phosphate 0.039 g, disubstituted sodium phosphate 0.117 g, carnosine 1.0 g. PH of the solution 7.23. Patient S. underwent EEC with IOL implantation. The volume of irrigation solution was 50 ml. In the early postoperative period, corneal edema was absent. Endothelial cell loss was 7%.

 Example 3

 An irrigation solution was prepared according to the described procedure. Weighed components were used: sodium chloride 9.5 g, monosubstituted sodium phosphate 0.026 g, disubstituted sodium phosphate 0.131 g, carnosine 20.0 g. PH solution 7.43. Patient S. underwent phacoemulsification of the lens. The volume of irrigation solution was 180 ml. There were no complications in the postoperative period. Endothelial cell loss was 4%.

 Example 4

9.0 g of sodium chloride, 0.018 g of monosubstituted sodium phosphate, 0.141 g of disubstituted sodium phosphate were weighed and dissolved in 1 l of purified water. A portion of 1.0 g of dextran was poured into 0.5 l of saline and placed in a refrigerator at 8 ^o C for a day. Next, the solution was stirred until the dextran was completely dissolved and filtered through a 0.45 μm filter. To 0.5 L of the remaining saline was added 10.0 g of carnosine, mixed until dissolved. To 0.5 L of dextran saline was added 0.5 L of carnosine saline and filtered through a 0.22 μm filter. the pH of the solution is 7.64. The solution was poured into vials, sealed and sterilized.

 Patient G. conducted EEC with implantation of IOL. The volume of irrigation solution was 85 ml. In the postoperative period, the cornea is transparent, no complications were detected. Endothelial cell loss was 6%.

 Example 5

 An irrigation solution was prepared according to the method described in example 4. The following weighed components were used: sodium chloride 9.2 g, monosubstituted sodium phosphate 0.026 g, disubstituted sodium phosphate 0.131 g, carnosine 1.0 g, dextran 50.0 g. PH of solution 7 , 41.

 Patient V. underwent phacoemulsification of the lens with IOL implantation. The volume of irrigation solution was 200 ml. The course of the postoperative period without complications. Endothelial cell loss of 4%.

 Example 6

 An irrigation solution was prepared according to the procedure described in example 4. Weighed portions of the components (salts and carnosine) indicated in example 5. As a water-soluble cellulose derivative, methyl hydroxyethyl cellulose was used in an amount of 20.0 g. PH of the solution was 7.42.

 Patient H. underwent EEC with IOL implantation. The volume of irrigation solution was 100 ml. A day after the operation, the cornea is transparent, there is no glass. Endothelial cell loss 5%.

 Thus, the use of the proposed irrigation solution made it possible to avoid corneal edema during surgical interventions of varying complexity and duration and to reduce the loss of endothelial cells.

Claims (3)

1. An irrigation solution containing sodium chloride, monosubstituted sodium phosphate and water, characterized in that it additionally contains disubstituted sodium phosphate and L-carnosine in the following ratio of components, g / l:
Monosubstituted sodium phosphate - 0.018 - 0.072
Disubstituted sodium phosphate - 0.079 - 0.141
Sodium Chloride - 8.5 - 9.5
L-carnosine - 0.5 - 20.0
Purified Water - Else
and has a pH of from 6.8 to 7.6 inclusive.  2. The solution according to claim 1, characterized in that it further comprises dextran in an amount of 1.0 to 50.0 g / L.  3. The solution according to claim 1, characterized in that it further comprises a water-soluble cellulose derivative representing an alkyl derivative, or a carboxyalkyl derivative, or a hydroxyalkyl derivative of cellulose, in an amount of 0.1 to 20.0 g / l.