SE452949B - MATERIAL FOR CONNECTING ELEMENT FOR SOFT TABLES - Google Patents

Description

452 949 2 A material for connecting elements for soft tissues and internal organs is known (compare, for example, TTDaurova, AP Majsjuk "Eksperimentaljnaja khirurgija", 1959, no. 6, page 37), which material is based on so-called biodegradable synthetic polymers , namely polyvinyl formal.

However, when this bonding material is used, it biogrades slowly, while the dissolution time of the material is longer than the regeneration time of soft tissues. In addition, the use of such connecting elements is accompanied by complications in the form of warp pleuritis or mediastinitis, which lead to the death of 60% of the experimental animals. After the operation, complications arise as a result of the suture disintegrating due to frequent warping and as a result of serous fluid being collected or the dressing material being completely rejected.

All the serious disadvantages have led to the known polyvinyl formal-based material not having any practical use in medicine.

BACKGROUND OF THE INVENTION The main object of the present invention is to provide such a material for connecting elements for soft tissues and internal organs by directed selection of the chemical structure of the macromolecule of the polymer and by combining, in this macromolecule, certain hydrophilic and hydrophobic monomeric structural units , which during the regeneration period of the tissues can retain dissected portions of the soft tissues and the internal organs and which ensures that these portions are physically and biologically tightly closable connected to each other, while the material prevents it from possibly coalescing with the surrounding tissues and organs.

This object is achieved according to the present invention by means of a material for connecting elements for soft tissues and internal organs, which is based on biodegradable synthetic polymers, which material is characterized in that it consists of a copolymer of N-vinylpyrrolidone and acrylic and / or methacrylic acid alkyl esters with 2 -8 carbon atoms in the alkyl group, which copolymer has a viscosity ratio of between 0.3 and 0.8 dl / g, the constituents being included in the following contents in mol%: N-vinylpyrrolidone 41.1 - 90% acrylic and / or methacrylic acid alkyl esters 10 - 60%.

The material of the connecting elements proposed according to the present invention, such as acrylic and / or methacrylic acid alkyl esters, preferably contains ethyl acrylate, butyl methacrylate or a mixture of ethyl acrylate and hexyl methacrylate.

The material of the present invention for the connecting elements is preferably a copolymer of 60-75 mole percent N-vinylpyrrolidone and 25-40 mole percent butyl methacrylate.

The material of the connecting elements proposed according to the present invention combines the ability of the copolymer to biodegradate, which requires the macromolecule to be highly hydrophilic and to be able to be better reacted with the liquid media of the organism, with the necessity of ensuring certain physical and mechanical properties. is hydrophobic in order to maintain the strength properties during the regeneration time (for the tissues).

All the properties of the material according to the invention have been achieved by introducing into the molecule of the copolymer hydrophilic links which contain nitrogen-containing substituents and hydrophobic links which contain alkyl substituents.

Preferred Embodiment of the Invention The copolymer of N-vinylpyrrolidone and acrylic or methacrylic acid alkyl esters is prepared by so-called solution polymerization (polymerization in solution) using radical type initiators (eg superoxides, diazo derivatives, photoradiation etc.), 4: 1 and 2: 3.

The connecting elements made of the material according to the present invention for fixing soft tissues and internal organs consist of films of different dimensions and shapes, which have a surface area of from 20 to 200 cm 2 and a thickness of from 30 to 300 μm. The films are prepared by casting (spreading) a 15-50% solution of the copolymer in a mixture of ethyl and butyl alcohol (in a mutual ratio of 4: 1 respectively) using a Teflon substrate (substrate) or polyethylene.

The film is dried, while the temperature is gradually increased from 20 to 40 ° C. In order for the film to be better stored, it is moistened, before being packaged, by allowing the film to stand in air for a period of 2 hours at a temperature of 20 ° C and a humidity of 100%. The specimens are sterilized by radiation sterilization at a radiation dose of 2.5 mrad or by keeping the specimens in para-formaldehyde vapor for a period of 18 hours, after which the specimens are kept for a period of 20 minutes in a physiological solution.

The connecting elements made of the material according to the present invention are fixed on a damaged surface in the following manner.

The connecting elements, the dimensions of which are larger than the dimensions of the damaged area, may be left for a period of 10-15 minutes in a sterile physiological solution or so-called Henks solution. Then cut out with a pair of scissors a section of the desired shape, which corresponds to the dimensions of the damaged area. The excised section is then dried by means of a gauze tampon, after which a layer of medical adhesive is applied to one side of the section. The section is then applied with the adhesive-coated side on the pre-wound, by means of a gauze tampon or by alcohol-dried surface of a damaged organ or of a pre-formed suture and pressed lightly against this surface. Sutures with intricate shapes can be tightly closed by means of a few films with the obligatory partial laying of one film on the other.

The film is permanently glued to the surface after a period of 60-80 s. 452 949 The edge sections of the film which are not glued to the surface must be removed by cutting with sterile scissors.

The performance of the connecting elements produced by the material of the present invention was preliminarily estimated in in vitro experiments using distilled water (model estimating the physical and mechanical properties of the material) or a buffer phosphate solution having a pH of 7.4 ( when examining the legal obligations of biodegradation). Since the macromolecule of the copolymer contains hydrophilic links, the swelling of the films and consequently their physical and mechanical properties must be considerably dependent on the nitrogen content. An increase in the nitrogen content of the copolymer leads to a decrease in the ultimate strength limit for specimens which have been previously allowed to swell for a period of 1 hour. If the nitrogen content of the copolymer is higher than 8%, the breaking strength limit will be lower than a permissible minimum value, so the copolymers whose nitrogen content is higher than 8% cannot be used.

Taking into account that the connecting elements to be used must not damage soft tissues and internal organs by mechanically irritating the surrounding tissues, and that these connecting elements must be well formed on the surface of the damaged organ when used, An important parameter, which determines the operability of the material, is the elasticity of the material, which is estimated depending on the elongation at break of the material.

On the basis of the test results, it has been found that the elongation at break l 1% is largely dependent on the content of N-vinylpyrrolidone, namely that the elongation at break increases when the content of N-vinylpyrrolidone becomes higher. For all copolymers, however, the elongation at break -ÅLÉ is higher than 100%, ie higher than the value selected as the lower elastic limit of the material.

The study of the dynamic changes in the physical and mechanical properties of the material in a model medium which makes it possible to predict to some extent the fixation of the soft tissues of the organism has shown that an increase in the residence time of the material in the model solution results in a increasing the breaking strength limit of the film and decreasing its elongation at break. Such a change in the physical and mechanical properties of the material is undoubtedly positive, since the increase in breaking strength helps to ensure that the fixing strength during the entire regeneration time is not lower than the initial strength, while the increase in stiffness prevents the internal parts dissected from being disassembled.

The material proposed for the production of connecting elements according to the present invention has been tested in animal and clinical trials in humans.

In clinical examination, the connecting elements for soft tissues and internal organs were used for hemostasis, physically and biologically tight closure of sutures and for eliminating the formation of adhesions during operations on various internal organs and in the treatment of various pathological disorders. Data regarding the number and type of operations, where connecting elements are used in widespread clinical testing of the material according to the present invention, are reported in Table 1. in Table 1 The number of operations and the possibility of using the connecting elements for internal organs produced by the material according to the present invention. the connecting elements and the nature of the organ, Number of operations to be operated on l 2 Tight closure of sutures during dissection of the stomach 37 Tight closure of sutures during operations on the esophagus and intestines 24 Hemostasis and tight closure of sutures during liver operations - 7 452 949 7 Table l (continued) Tight closure and reinforcement of sutures during lung surgery 6 Tight closure of vascular anastomoses 1 Hemostasis and tight closure of the bladder floor 8 Tight closure of pancreatic gland tail 5 Tight closure of urogenital organs 5 Tight closure of defects in the throat 4 Tight closure in the oral cavity at distant Salivation of the salivary glands 17 Closing of holes (perforations) in eardrums 2 Elimination of adhesion processes in osteosynthesis in tubular bones ll Total: 128 operations The test was performed using connecting elements of three dimensional types, as shown in Table 2.

Table 2 Properties of the connecting elements Embodiment of Length Width Thickness of the connecting elements mm mm mm 100 75 100 75 50 100 50 37 100 The use of the material of connecting elements proposed according to the present invention for tight closure of sutures in the treatment of gastric diseases and gastric and intestinal diseases. 452 949 8 Good results have been obtained in the treatment of complicated forms of special disease of varying localization type. The sutures were tightly closed using the material of the present invention in two widespread gastric dissections (3/4) with an anastomosis according to Billroth I, two gastric dissections (2/3) with an anastomosis according to Billroth II, two antrectomies in combination with vagotomy , two sparing dissections (1/3) and 1/2) with anastomosis according to Billroth II and two reconstructive operations (so-called reduodenizations) and in one case when creating an artificial esophagus from the right half of the large intestine. All patients have been discharged as healthy. Postoperative complications have only been found in one case. During gastric dissection due to wound disease in the upper third of the stomach, an infiltrate formed, which completely dissolved after the corresponding treatment.

The connective material material of the present invention has also been used successfully in the treatment of oncological diseases of the distal portion of the stomach.

During the study period of the connective material material of the present invention, the material was used in combination with medical adhesive for physically and biologically tight closure of sutures at 18 gastric dissections and 9 gastroenterostomies with interintestinal anastomosis. The sutures were tightly closed by gradually slicing strips of the material of the present invention until the entire suture line was completely closed. The films were glued on so that they overlapped each other a little. Such a gluing method helped to close the anastomosis line considerably more efficiently and to close the suture very tightly. It should be noted here that the operating time for using the material according to the present invention was only 3-4 minutes longer than the time required to perform the same operation according to the approved reference method.

The comparative examination of the causes of postoperative peritonitis after completion of gastric dissection has shown that the sutures do not disintegrate when the anastomotic zone is reinforced by connecting elements made of the material of the present invention.

When interintestinal anastomoses in gastroenterostomies were enhanced by connecting elements made of the material of the present invention, complications of the above kind (ie disintegration of the suture) were found only in 1 case out of 9, which was considerably lower than in the reference group (in the reference experiments).

During the same time period, 32 patients were operated on due to oncological diseases, 15 of them using the dressing material of the present invention. In only 3 patients out of 15, post-operative complications were found, which resulted from wart formation in the sutures, while the number of complications in the reference group was 6 out of 17.

With the aid of only connecting elements made of the material according to the present invention, it has been possible to securely, without the use of sewing devices, tightly close the wound surface of the parenchyma, which has remained after dissecting a part of a lung measuring 8 x 12 cm.

However, such an effect was not achieved in all cases.

The adhesive is rather difficult and time consuming to apply to a large surface by lubrication by means of a needle belonging to an ampoule of adhesive. This leads to the adhesive polymerizing prematurely on individual sections. In three cases out of six, the film separated from the wound surface of the lung at the end of the operation, when the lung was inflated. In the other three cases, the film was loosened only along the edges, whereby the parenchyma was retained by the film. In these three patients, the postoperative period usually elapsed during insignificant air delivery through the drainage channels. After the operation, no warping was found. These results make it possible to recommend the use of the material proposed according to the present invention when performing operations on the lung parenchyma. However, in order to be able to close the suture more tightly, a 452 949 Ä method must be used, which is relevant in the close closure of intestinal anastomoses, which in other words means that a continuous suture must be formed by gluing tighter films, which must be fixed. , while the films slightly overlap O: each other. ~ When the gallbladder is removed, the film is securely fixed to the liver surface, whereby no bleeding along the edges of the film was detected. In all cases, the postoperative period passed without complications.

By using the material according to the present invention, it has been possible to ensure safe hemostasis in three cases out of four, whereby the film glued to the diaphragm in a single case is detached together with the film-fixing tampon of gauze. In the three cases, the postoperative course was even, with no complications being found.

In order to be able to biologically tightly close the sutures and to increase the strength of the connecting material according to the present invention, this material is used in forming sutures in the oral cavity after removal of salivary gland tumors, due to so-called salivary stone disease, and chronic salivary gland inflammation. The film was placed inwardly soft tissues with subsequent suturing. In all 17 cases, the course of postoperative surgery was smooth, with the wounds healing under primary tension.

In order to prevent any overgrowth from occurring, the connecting material according to the present invention is used in performing operations on fractures of tubular bones (for example femurs, lower legs). The films were placed, without the use of medical adhesive, under the so-called fascia and along the sutures until these were completely closed.

If the surfaces are large, the film was fixed point by point by means of the adhesive. The formation of adhesions was controlled by palpation for a period of from 1 to 4 months and with the guidance of indications from the patients. In all cases, no formation of adhesions was found.

In three cases, it has been possible to check the absence of adhesions visually. In a patient, the absence of Um 452 949 ll of adhesions was found, when after 6 months a repeated operation was performed due to removal of the metal plate, whereby the film was completely fragmented and individual microfragments were detected. In two other patients, no traces of the film have been detected during the same repeated operation after 8 and 8.5 months. Nor was the formation of adhesions observed.

In all cases, the absence of any abnormalities in blood and urine samples as well as the absence of any local tissue reaction to the presence of the material of the present invention were found.

The connecting elements made of the material according to the present invention are convenient to handle, whereby their shape can be changed easily by means of a conventional surgical scissors in order for the connecting element to be able to obtain the desired shape. In addition, the connecting elements are easy to shape to the shape of the surface of the damaged member.

The use of the connecting elements made of the material according to the present invention means partly that reliable adaptation of dissected sections of soft tissues to each other is ensured, partly that postoperative bleeding is eliminated, partly that initiation of adhesion processes is prevented and that the organism's reaction to the connecting element caused as a result of the connecting element completely dissolving.

The invention is further elucidated below by means of the following examples of preparation of the material according to the present invention for connecting elements for soft tissues and internal organs.

Example 1 Copolymer of N-vinylpyrrolidone and ethyl acrylate with a content of vinylpyrrolidone linkers of 50.3 mol%.

The copolymer is prepared by copolymerizing 7.8 g of N-vinylpyrrolidone and 3 g of ethyl acrylate in toluene at a temperature of 80 ° C in the presence of 0.5 mole percent so-called 4A4Z type paraphor (4,4-aza-bis- (4-cyanopentanoic acid) The copolymer yield is 9.7 g, the characteristic viscosity [Q] of the copolymer being 0.43 dl / g. By casting a 26% solution of the copolymer in chloroform, films with a thickness of 250 .mu.m The breaking strength of the film (fbr is 14 kp / cm 2 and its elongation at break after a residence time of 30 minutes in a physiological solution 230 is 90%. The dissolution time of the material in the organism is between 95 and 100 days.

Example gel 2 Copolymer of N-vinylpyrrolidone and octyl acrylate with a vinyl pyrrolidone linkage content of 43 mol%.

The copolymer is prepared by copolymerizing 6.6 g of N-vinylpyrrolidone and 7.3 g of octyl acrylate in toluene at a temperature of 85 ° C in the presence of a so-called 4A4Z-type paraphor. The final product yield is 10.6 g. The product's characteristic viscosity Üz] is 0.34 dl / g. By casting (forming) a 32% solution of the copolymer in chloroform, films with a thickness of 170 μm are produced, whose breaking strength Sir is 16.7 kp / cm 2 and elongation at break Ešo is 210%. The dissolution time of the film in the organism is between 240 and 280 days.

Example Gel 3 Copolymer of N-vinylpyrrolidone and butyl methacrylate with a vinyl pyrrolidone linkage content of 55.2 mol%.

The copolymer is prepared by copolymerizing 7.77 g of N-vinylpyrrolidone and 4.26 g of butyl methacrylate in benzene at a temperature of 75 ° C in the presence of a so-called 4A4Z-type paraphor. The final product yield is 9.8 g, while the characteristic viscosity of the final product [TÜ = 0.78 dl / g.

By casting a 24% solution of the copolymer in alcohol, films with a thickness of 200 μm were produced. The film's breaking strength Ögr is 18 kp / cmz and its elongation at break EGO is 34%, while the dissolution time of the film in the organism varies between 130 and 150 days.

Example 4, Copolymer of N-vinylpyrrolidone and butyl methacrylate with a content of vinylpyrrolidone linkages of 79.8 mol%.

The copolymer is prepared by copolymerizing 8.8 g of N-vinylpyrrolidone and 2.8 g of butyl methacrylate in benzene at a temperature of 85 ° C in the presence of 4A4Z-type paraphor. The final product yield is 10.2 g, while the characteristic viscosity [fi] of the final product is 0.62 dl / g. Films with a thickness of 40-60 μm are prepared in the same manner as in Example 3. The fracture toughness of the film is, is 6.4 kg / cm 2 and its elongation at break E30 is 880%, while the dissolution time of the film in the organism is 35- 40 days.

Example 5 Copolymer of N-vinylpyrrolidone and butyl methacrylate with a content of vinylpyrrolidone linkages of 41.1 mol%.

The copolymer is prepared by copolymerizing 4.4 g of N-vinylpyrrolidone and 8.25 g of butyl methacrylate in the manner described in Example 3. The final product yield is 11.3 g, while the characteristic viscosity [Q] of the final product is 0.13 ai / g.

Films with a thickness of 240 μm were prepared in the same manner as in Example 3, the breaking strength of the films there being 18.8 kp / cm 2 and their elongation at break E30 being 110%.

The dissolution time of the films in the organism varied between 315 and 330 days.

Example 6 Copolymer of N-vinylpyrrolidone, ethyl acrylate and hexyl acrylate with a content of vinylpyrrolidone links of 57.3 mol%.

The copolymer is prepared from 7.77 g of N-vinylpyrrolidone, 1.0 g of ethyl acrylate and 3.12 g of hexyl acrylate in the same manner as described in Example 3. The copolymer yield is 10.6 g, while the [q fl of the copolymer is 0.41 dl / g.

By compression at a temperature of 140 ° C and a pressure of 80 kp / cm2, sheets with a thickness of 1.5 mm are produced, the breaking strength of which and the elongation at break of E¿30 are 13.3 kp / cm2 and 105%, respectively, while The dissolution time for the sheet in the organism is between 164 and 170 days.

Example 7 Copolymer of N-vinylpyrrolidone and pentyl methacrylate with a content of vinylpyrrolidone linkages of 89.6 mol%.

The copolymer is prepared by copolymerizing .5 g of N-vinylpyrrolidone and 0.78 g of pentyl methacrylate in xylene at a temperature of 84 ° C in the presence of 0.6% by weight of 4A4Z-type paraphor. The copolymer yield is 10.2 g, while the characteristic viscosity of the copolymer is 0.32 dl / g. By casting a 37% solution of the copolymer in a mixture of ethyl and butyl alcohol (in a mutual volume ratio of 9: 1, respectively), films with a thickness of 80-90 μm are produced, which have a breaking strength there of 3, 2 kp / cmz and an elongation at break of 910%. The dissolution time of the film in the organism is between 15 and 25 days.

Industrial Applicability The material proposed according to the present invention for the production of connective elements for soft tissues and internal organs can be used in the medical technology for hemostasis, physically and biologically tight closure of sutures and for eliminating the formation of adhesions in operations on various internal organs and in the treatment of various types of pathological disorders. in! m

Claims (3)

10 15 20 452 949 15 PATENT CLAIMS Materials for soft tissues and internal organs, based on biodegradable synthetic polymers, characterized in that it consists of a copolymer of N-vinylpyrrolidone and acrylic and / or methacrylic acid alkyl esters having 2 to 8 carbon atoms in the alkyl group, which copolymer has a viscosity ratio of between 0.3 and 0.8 dl / g, the constituents being included in the following contents in mole percent: N-vinylpyrrolidone 41.1 - 90% acrylic and / or methacrylic acid alkyl esters 60% Material according to claim 1, characterized in that it contains as acrylic and / or methacrylic acid alkyl esters ethyl acrylate, butyl methacrylate, a mixture of ethyl acrylate with hexyl methacrylate. Material according to claim 1 or 2, characterized in that it consists of a copolymer of N-vinylpyrrolidone and butyl methacrylate, the constituents being included in the following contents in mole percent: 60 - 75 25 - 40. N-vinylpyrrolidone butyl methacrylate