RU2613417C1 - Method of reinforcing cornea albugo in experiment - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, namely to ophthalmology, and can be applied in experimental medicine in order to reinforce albugo tissues at different stages of keratoprosthetics. Cornea cut is carried out in experimental animals concentrically to limb. Corneal intrastromal recess is formed, in which implant is introduced in form of disk with diameter 9-12 mm and thickness 0.2-0.5 mm, consisting of 4-5 mg of type I collagen and 100-300 mcg of growth factor rhBMP-2.

EFFECT: method of improving cornea biomechanical properties in experiment, creation of favourable ground for further keratoprosthetics, which leads to reduction of operative and postoperative complications in treatment of burn cornea albugos.

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Description

The invention relates to medicine, namely to ophthalmology, and can be used in experimental medicine in order to strengthen the throat tissue at various stages of keratoprosthetics.

There is a method of strengthening corneal throat with auto-cartilage of the auricle [Krasnov MM and others. Ophthalmological journal. 1978, No. 7, p. 392-394].

There is a method of strengthening corneal throat autoperiosteum of the tibia [Volkov VV, Ushakov N.A. in the book. "Questions of reconstructive ophthalmology." L., 1972, p. 37].

The disadvantages of these methods are the need for preliminary sampling of autologous tissues and the difficulties encountered in modeling the implant, as well as poor adaptive capabilities of the material and its lysis in the postoperative period.

The closest analogue is a method for preparing burn cornea of a cornea for keratoprosthetics using the equivalent of cartilage [Prospects for the use of tissue-engineering design based on cultured autologous chondrocytes at the stages of preparation of a cataract for keratoprosthetics. / R.A. Gundorova, E.V. Kiseleva, P.V. Makarov, Yu.A. Kapitonov, T.A. Kanukova. // Russian Ophthalmological Journal. - 2014. - T. 7. - No. 3. - S. 65-70].

The disadvantage of this method is the need for the collection of autologous cells and their subsequent cultivation, which requires additional surgery and does not allow to begin treatment in the shortest possible time. Also, the problem of lysis of the implant used and its large thickness, which complicates the operation, has not been solved.

The objective of the invention is to increase the biomechanical properties of the cornea in the experiment and stabilize the resulting functional effect for a long time.

The technical result achieved by using the invention is to create a favorable soil for further keratoprosthetics, which leads to a decrease in surgical and postoperative complications in the treatment of burn corneal sore throats.

The technical result is achieved by the fact that in a method for strengthening corneal throat in an experiment involving the use of an implant made from collagen according to the invention, the cornea is cut in concentric limb in experimental animals, then a corneal intrastromal pocket is formed into which an implant is inserted in the form of a disk with a diameter of 9 -12 mm and a thickness of 0.2-0.5 mm, consisting of 4-5 mg of type I collagen and 100-300 μg of rhBMP-2 growth factor. Collagen biodegradation activates the growth factor located in it, under the influence of which there is a restructuring of the surrounding tissues. BMP (bone morphogenetic protein) are pleiotropic growth factors that belong to the superfamily of β-transforming growth factor (TGF-β).

BMP regulate three key phases of osteogenesis: chemotaxis, mitosis, and differentiation. BMP also regulate hematopoiesis, stimulate the synthesis of extracellular matrix, and influence the maintenance of cell viability. Strengthening the cataract with the help of the growth factor rhBMP-2 allows for a long time to increase the biomechanical characteristics of the cornea, to make up for the tissue deficiency in the case of thinned sores, and to increase the resistance of tissues to ischemia.

Thus, the proposed method for strengthening the cataract in comparison with existing analogues makes it possible to abandon the use of transplants from autologous tissues and successfully inhibit the development of complications, such as protrusion of the keratoprosthesis, by increasing the strength properties of the initial tissues of the cataract, the formation of new connective tissue and improving metabolic processes, flowing in a thorn.

The method is simple to implement, does not require expensive equipment and drugs, can be used in experimental medicine in the development of surgical methods for treating burn problems.

The method is as follows

In 4-5 mg / ml of an aqueous solution of type I collagen (manufactured by IMTEK, Moscow), 100 μg to 300 μg rhBMP-2 growth factor was added. Then, the resulting hydrogel was poured into 1.0 ml wells of a 24-well plate. To form a gel, the resulting mixture was incubated at + 37 ° C for 30 minutes. The formed collagen hydrogels extracted from the plate were washed in 500 ml of Ringer-Krebs phosphate buffer solution at room temperature for 24 hours, with the solution replaced every 8 hours. Then the gels were laid on the surface and dried until completely dried by a stream of air at + 37 ° C. The resulting films were rehydrated, dried, thus obtaining an implant in the form of, for example, a disk with a diameter of 9-12 mm and a thickness of 0.2-0.5 mm.

The test was conducted on chinchilla rabbits weighing 2.0-2.5 kg. Under general and drip anesthesia, a cornea was cut 5 mm long by 3/5 of its depth concentrically to the limb. A corneal intralamellar pocket was formed in this plane, into which the claimed implant was inserted. Stitches were applied to the incision. One eye was operated on in animals to maintain orientation in the surrounding space.

The proposed method was carried out reinforcing the cornea of the cornea on 18 male rabbits of the breed "chinchilla" with an initial body weight of 2.0-2.5 kg. The simulation of burn sore throat was performed 6 months before the operation, on the left eye of animals by applying a cotton disc with a diameter of 10 mm on the cornea of the rabbit soaked in 10% NaOH for 7 seconds, the right eye was the control.

A clinical assessment of the state of the eyes of animals was carried out according to the degree of inflammatory reaction, vascularization of the cornea (Chentsova E.V., 1996), intensity of clouding of the cornea (Voino-Yasenetsky V.V., 1953). The observed changes were recorded by photographing on a photo-slit lamp from Opton (Germany).

The experimental results were evaluated for morphology and biomechanics.

Example 1

A male chinchilla rabbit weighing 3.5 kg was operated on with the right eye. Retrobulbar blockade of 0.5% novocaine was performed. A 5 mm long cornea was cut into 2/3 of its depth concentrically to the limb. In this plane, with the help of a delaminator, a corneal intrastromal pocket was formed “from limb to limb”. An implant was introduced using a pair of tweezers and a spatula, in the form of a disk with a diameter of 9 mm and a thickness of 0.5 mm, consisting of 4 mg of type I collagen and 100 μg of rhBMP-2 growth factor into the cavity of the formed pocket. Stitches were applied to the incision. At the end of the operation, a subconjunctival injection of 1.0% gentamicin sulfate was made in a volume of 0.5 ml. Then for one week instilled okomistin 1 drop 2 times a day.

A clinical assessment of the state of the eyes of animals was carried out according to the degree of inflammatory reaction, vascularization of the cornea (Chentsova E.V., 1996), intensity of clouding of the cornea (Voino-Yasenetsky V.V., 1953). The observed changes were recorded by photographing on a photo-slit lamp from Opton (Germany).

The experimental results were evaluated morphologically. The cornea was excised around the circumference of the limb, and then fixed in formalin for 24 hours. The resulting corneal disk was cut in half, perpendicular to the vessels. Both fragments were dehydrated in ascending alcohols and embedded in paraffin. Sections 8-10 μm thick were made on a microtome and stained with hematoxylin and eosin. A study of corneal sections was performed under a light microscope at 16- and 40-fold magnification.

To study the biomechanical characteristics, the cornea was excised around the circumference, capturing a portion of the sclera while retreating 3 mm from the limbus. For the purity of the experiment, freshly cut animal tissues obtained immediately before the study were used. The resulting corneal disk was clamped between two metal plates with a hole in the center corresponding to the diameter of the cornea, so that fixation occurred beyond the scleral tissue, and the cornea was intact. The finished structure was dipped in saline to prevent tissue from drying out during the study. Evaluation of biomechanical properties was carried out by examining tissues for puncture on tensile testing machines of the Instron company.

In the early postoperative period, there was a slight corneal edema. The edema was mild and was caused, apparently, by the presence of an operating injury. Clinical signs of acute infectious lesions of the surrounding tissues during examination were not found. On the 9th day, the appearance of newly formed vessels was observed in an eccentric limb, with a subsequent increase in their number and an increase in the caliber of the vessels. On the 34th day, stable stabilization of the clinical picture was noted. After 2 months, no clinically significant changes were noted. By the end of the observation period (90 days), the rabbit showed vascularization and thickening of the corneal tissue to 0.6 mm. A histological examination of the transplant area showed partial fragmentation and replacement of the newly formed connective tissue, in some places vessels grow in it. The cornea is significantly thickened. The study of biomechanical properties showed an increase in the strength characteristics of tissues by 4.5 times.

Example 2

A male chinchilla rabbit weighing 3.5 kg was operated on with the right eye. Retrobulbar blockade of 0.5% novocaine was performed. A 5 mm long cornea was cut into 2/3 of its depth concentrically to the limb. In this plane, with the help of a delaminator, a corneal intrastromal pocket was formed “from limb to limb”. An implant was introduced using a pair of tweezers and a spatula, in the form of a disk with a diameter of 12 mm and a thickness of 0.2 mm, consisting of 5 mg of type I collagen and 300 μg of rhBMP-2 growth factor into the cavity of the formed pocket. Stitches were applied to the incision. At the end of the operation, a subconjunctival injection of 1.0% gentamicin sulfate was made in a volume of 0.5 ml. Then for one week instilled okomistin 1 drop 2 times a day.

A clinical assessment of the condition of the eyes of animals, morphological studies and the assessment of biomechanical characteristics was carried out according to example 1.

In the early postoperative period, there was a slight corneal edema. The edema was mild and was caused, apparently, by the presence of an operating injury. Clinical signs of acute infectious lesions of the surrounding tissues during examination were not found. On the 7th day, the appearance of newly formed vessels was observed in an eccentric limb, with a subsequent increase in their number and an increase in the caliber of the vessels. By the end of the first month, stable stabilization of the clinical picture was observed. After 2 months, no clinically significant changes were noted. By the end of the observation period (90 days), the rabbit showed vascularization and thickening of corneal tissue up to 0.7 mm. A histological examination of the transplant area showed partial fragmentation and replacement of the newly formed connective tissue, in some places vessels grow in it. The cornea is significantly thickened. The study of biomechanical properties showed an increase in the strength characteristics of tissues by 4.5 times.

Claims (1)

A method of strengthening corneal throat in an experiment, including the use of an implant made of collagen, characterized in that the experimental animals make a corneal incision concentrically to the limbus, then form a corneal intrastromal pocket into which an implant is inserted in the form of a disk, with a diameter of 9-12 mm and a thickness of 0 2-0.5 mm, consisting of 4-5 mg of type I collagen and 100-300 μg of rhBMP-2 growth factor.