RU2460497C1 - Scleroplant for reconstructive scleroplasty in case of pathologic states of sclera - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to field of medicine, namely to ophthalmology and is intended for reconstructive scleroplasty in case of pathological states of sclera, induced by different diseases, traumas, as well as developed as a result of ablation of eye and orbit tumours. Claimed is scleroplant for reconstructive scleroplasty in case of pathological states of sclera, made from spatially cross-linked polymer by photopolymerisation of oligomers of methacryl series in form of flat or spherically curved according to the shape of eyeball mesh plate of rounded or lobe-like shape, from 0.1 to 0.5 mm wide and with general diameter from 15 to 30 mm, scleroplant contains cuts on periphery for improvement of deformation and holes for fixation.

EFFECT: claimed scleroplant makes it possible to restore normal configuration of external eye surface, protect eye membranes from bulging, and vitreous body from flowing out, ensures connection of synthetic transplant with patient's sclera with formation of strong complex "sclera-transplant" with absence of negative effects, connected with impairment of supply of sclera sections under implant.

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Description

The invention relates to medicine, namely to ophthalmology, and is intended for reconstructive scleroplasty in pathological conditions of the sclera due to various diseases, traumatic injuries, as well as those resulting from the removal of tumors of the eye and orbit. With these types of pathology, staphylomas form or scleral defects occur as a result of thinning of the sclera.

To close defects in sclera, biological materials are usually used (RU 99102289, RU 93006067, RU 2161021, RU 2089200): donor frozen or lyophilized allosclera, dura mater, femoral fascia, etc. [1]

However, the use of biological materials is associated with a number of problems:

1. Allergic and immunological reactions of the patient to biological material.

2. Difficulties in implantation associated with the consistency of biological material, as a rule, without elastic properties.

3. The lack of persistent effect due to biodegradation and resorption of the material used.

4. The complexity of the collection of material, its conservation and storage.

5. The need to study biological material for infections that can be transmitted through transplantation material, which not only increases the cost of the material and increases the production time of the transplant, but also makes it difficult to use in emergency situations.

6. The moral and ethical aspect that arises when using biological transplantation material, as well as the imperfection of legal norms.

Therefore, currently synthetic transplants are the most promising for reconstructive scleroplastic operations (RU 96121727, RU 2160123, RU 2297811, etc.) [2].

A number of disadvantages are characteristic of synthetic silicone implants for scleroplasty:

- increased yield of oligomers and other toxic compounds from the volume of the graft,

- low efficiency of scleroplastic operations due to the lack of a tight fusion of the graft with the patient’s sclera,

- a large number of complications associated with malnutrition and ischemia of the membranes of the eyeball under the graft due to the impossibility of vascular invasion through the graft resulting from this pain syndrome and the formation of pressure sores with perforation of the sclera,

- high probability of infection, etc.

To address these shortcomings, a polyester fiber explant for scleroplastic surgery was proposed (RU 2003103472). However, this explant, which is a fabric of a cellular structure made by knitting, does not have elastic properties. Therefore, it cannot be used for reconstructive scleroplasty, which is performed in order to eliminate staphilus and restore the normal configuration of the eyeball.

Thus, the closest in technical essence is an implant made of a material widely used in medicine - silicone rubber, processed in a low-temperature plasma of a discharge created in a gas medium to form a porous structure in the surface layer of the graft (RU 2160123). Moreover, such disadvantages as the increased exit of oligomers and other toxic compounds from the volume of the implant to the outside, the lack of hydrophilicity and the fusion of the silicone implant with the sclera in the proposed analogue were eliminated. However, such significant shortcomings of silicone implants as the formation of pressure sores with sclera perforation resulting from malnutrition of the membranes of the eye under the implant, the presence of pain and infection of the graft, etc., were not resolved [3, 4].

Based on the foregoing, we were tasked with creating an implant for reconstructive scleroplasty in pathological conditions of the sclera from a biocompatible biostable non-toxic material with a structure that repeats or restores the normal configuration of the outer surface of the eye, protects the shell of the eye from bulging, and the vitreous from leakage, provides a synthetic connection graft with the patient’s sclera with the formation of a durable complex "sclera-graft" in the absence of n Negative effects associated with malnutrition of the sclera under the implant. The developed implant should connect to the sclera solely due to the connective tissue germinating into the implant without a pronounced inflammatory reaction and without disturbing the nutrition of the eye tissues, and should also not impede the growth of blood vessels from the surrounding tissues of the eyes of the own tissues into the sclera layers.

The technical problem is solved by creating a scleroplant for reconstructive scleroplasty in pathological conditions of the sclera, made of a spatially cross-linked polymer by photopolymerization of methacrylic series oligomers in the form of a flat or spherically curved eyeball in the form of a rounded or bean-shaped solid mesh plate with a total diameter of 15 to 30 mm, with this scleroplant contains slots around the periphery to improve deformation and holes for fixation. The mesh structure of the scleroplant is formed by cells of various shapes with a diameter of 0.1 to 1 mm and a distance between them of 0.1 to 1 mm. The holes for fixation have a diameter of from 0.5 to 1.5 mm and can be located on the periphery, in the center of the scleroplant and along the edges of the slots. Scleroplant thickness is from 0.1 to 0.5 mm. Peripheral slots to improve scleroplast deformation are located radially relative to the center of the scleroplant and are spaced from it at a distance of 1 to 10 mm.

The technical result is achieved by the fact that the implant for reconstructive scleroplasty (scleroplant) is made of a spatially cross-linked polymer obtained by photopolymerization of methacrylic series oligomers. A distinctive feature of this production method is that the product formation process eliminates any mechanical impact on the implant. Any mechanical effect on the polymer is known to provoke the formation of free radicals, which subsequently lead to polymer degradation and undesirable toxic reactions.

The design of a scleroplant for reconstructive scleroplasty depends on the location and configuration of the scleral defect. If there is a significant bulging of the membranes of the eye in the area of the scleral defect and the defect is located at some distance from the limbus, then a flat bean-shaped or oval-shaped plate is used. This is due to the fact that in this case it is necessary to pin down the protrusion of the sclera (staphyloma) in order to restore the normal configuration of the eyeball. In the event that the scleral defect is directly adjacent to the limb, that is, located in the anterior parts of the eyeball, it is necessary to use a spherically convex scleroplant, which completely repeats the shape of the eyeball.

For optimal fit to the sclera of the patient, rounded scores are provided in the scleroplant design at the periphery, which are located radially relative to the center of the scleroplant and are spaced from 1 to 10 mm from it. During implantation of a scleroplant, the edges of these slots come together and are fixed to the patient’s sclera so that the scleroplant repeats the normal configuration of the patient’s eyeball.

Subsequently, connective tissue sprouts through the scleroplant cells and “biological fixation” of the product is achieved. The connection of the scleroplant with the sclera occurs without a pronounced inflammatory reaction and without disturbing the nutrition of the eye tissues, the scleroplant does not prevent the growth of blood vessels from the surrounding tissues of the eyes. For the manufacture of a scleroplant, a polymer material is synthesized obtained by photopolymerization of methacrylic oligomers of the patent RU 2234417. The polymer material is biocompatible, biostable, hydrophobic, does not cause inflammatory or rejection reactions.

The claimed invention is illustrated in graphic material.

Depending on the location and configuration of the scleral defect, the scleroplant has the following designs:

Figure 1 - Flat scleroplant oval.

A - from 15 to 30 mm,

B - from 15 to 30 mm.

Scleroplant contains:

(1) - cells of various shapes with a diameter of from 0.1 to 1 mm and a distance between cells from 0.1 to 1 mm.

(2) - holes for suture fixation on the periphery of the scleroplant, where

C is the diameter of the holes for suture fixation from 0.5 to 1.5 mm.

Figure 2 - Flat scleroplant bean-shaped.

A - from 15 to 30 mm,

B - from 15 to 30 mm,

D - from 10 to 30 mm.

Scleroplant contains:

(1) - cells of various shapes with a diameter of from 0.1 to 1 mm and a distance between cells from 0.1 to 1 mm.

(2) - holes for suture fixation on the periphery of the scleroplant, where

C is the diameter of the holes for suture fixation from 0.5 to 1.5 mm.

Figure 3 - Flat scleroplant bean-shaped with slots on the periphery.

A - from 15 to 30 mm,

B - from 15 to 30 mm.

The scleroplant contains slots (3). The slots (3) allow the scleroplant to take a spherical shape without the formation of overlapping edges of the slots on each other and corners.

Scleroplant contains:

(1) - cells of various shapes with a diameter of from 0.1 to 1 mm and a distance between cells from 0.1 to 1 mm.

(2) - holes for suture fixation on the periphery of the scleroplant, where

C is the diameter of the holes for suture fixation from 0.5 to 1.5 mm.

Figure 4 - Spherically curved in the shape of an eyeball scleroplant bean-shaped with cuts on the periphery.

A scleroplant in the form of a solid mesh plate spherically curved in the shape of an eyeball with cells (1) and holes for fixation (2) around the periphery of the product. Since the shape of the eyeball is such that the radii of curvature are different in different departments, the slots (3), to improve deformation, allow the scleroplant to take a spherical shape with a given radius of curvature.

Figure 5 - Spherically curved in the shape of an eyeball scleroplant bean-shaped with angular slots with rounded corners in the scan.

A scleroplant in a scan in the form of a solid mesh plate of a round or bean-like shape with slots (3), which are located radially relative to the center of the scleroplant and are distant from it

E - from 1 to 10 mm

to improve deformation and fixing holes (2) on the periphery of the product.

The claimed scleroplant has been successfully put into practice, which is confirmed by the following clinical examples demonstrating the results of surgical scleroplastic treatment using the claimed scleroplant.

Example 1: Patient Sh., 68 years old, applied to the CF of FSI MNTK “MG” named after Acad. S.N. Fedorova with complaints of severe deformity of the left eyeball, a progressive decrease in vision. From the anamnesis, it is known that the patient suffers from polyarthritis and takes anti-inflammatory hormonal drugs for a long time. The patient was diagnosed with ciliary scleral staphyloma complicated by severe ectasia of the ciliary body with the threat of perforation of the left eye membranes.

In order to strengthen the sclera, a reconstructive sclerotherapy was performed using the declared spherically curved scleroplant with a thickness of 0.15 mm. The operation and the postoperative period were uneventful. Deformation of the eyeball is eliminated, visual functions are stabilized. The observation period is 1.5 years.

Example 2: Patient U., 52 years old, applied to the CF of FSI MNTK "MG" named after Acad. S.N. Fedorova with complaints of pain, severe deformation of the right eyeball, a sharp decrease in vision. From the anamnesis it is known that the patient was repeatedly operated on for chronic recurrent uveitis. The patient was diagnosed with post-traumatic (postoperative) extensive scleral autolysis complicated by severe ectasia of the choroid with perforation of the membranes of the right eye against the background of an autoimmune systemic disease of the connective tissue.

In order to strengthen the sclera, a reconstructive sclerotherapy was performed using the claimed flat scleroplant 0.3 mm thick. The operation and the postoperative period were uneventful. Deformation of the eyeball is eliminated, visual functions are stabilized. The observation period is 8 months.

Information Sources Used

1. EI Kovalevsky “Eye diseases”. Atlas. Moscow, "Medicine", 1985, p. 148.

2. Markosyan G.A., Ivashchenko Zh.N. Results of sclera reinforcement with synthetic grafts with long follow-up. - Materials of the VIII Congress of Ophthalmologists of Russia. Abstracts of reports. Moscow 2005, p. 725.

3. Utkin V.F. Strengthening sclera with silicone rubber with progressive myopia. - In the book: The Fifth All-Union Day of Ophthalmologists. M., 1979, v. 1, p. 157-158.

4. Ilnitsky VV Temporary and permanent episcleral filling in surgery for retinal detachment, its prevention. - Dis. Doct. honey. sciences. M., 1995.

Claims (5)

1. Scleroplant for reconstructive scleroplasty in pathological conditions of the sclera, characterized in that the scleroplant is made of a spatially cross-linked polymer by photopolymerization of methacrylic series oligomers in the form of a flat or spherically curved eyeball of a solid circular mesh or round bean shape with a total diameter of 15 to 30 mm, while the scleroplant contains slots around the periphery to improve deformation and holes for fixation. 2. A scleroplant for reconstructive scleroplasty for pathological conditions of the sclera according to claim 1, in which the mesh structure is formed by cells of various shapes with a diameter of 0.1 to 1 mm and a distance between them of 0.1 to 1 mm. 3. Scleroplant for reconstructive scleroplasty for pathological conditions of the sclera according to claim 1, in which holes for fixation with a diameter of 0.5 to 1.5 mm are located on the periphery, in the center of the scleroplant and along the edges of the slots. 4. A scleroplant for reconstructive scleroplasty for pathological conditions of the sclera according to claim 1, wherein the thickness is from 0.1 to 0.5 mm. 5. Scleroplant for reconstructive scleroplasty for pathological conditions of the sclera according to claim 1, in which the slots are located radially relative to the center of the scleroplant and are spaced from it at a distance of 1 to 10 mm.

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