RU175248U1 - Nanostructured titanium mini-plate for lower jaw osteosynthesis - Google Patents

Abstract

Grade-4 nanostructured titanium mini-plate with surface treatment using the ECAP-conform method for open focal osteosynthesis of the lower jaw, having a rectangular shape with rounded contours 46.4 mm long, 0.6 mm thick, with 6 holes with a diameter of 1 , 7 mm at an equal distance from each other, the width of the plate in the area of the holes is 4.4 mm, between the holes is 3.0 mm. On the back (bone-contacting) surface of the plate there is a relief in the form of square recesses measuring 0.1 by 0.1 mm, a depth of 0.1 mm and distances between adjacent recesses of 0.1 mm, oriented parallel to the length and width of the plate. the surface makes it possible to enhance the spatial stability of the mini-plate not only by fixing it with mini-screws, but also by the process of reparative osteogenesis on the surface of the plate and in the relief structures due to osseointegration.

Description

The utility model relates to medicine, namely to maxillofacial surgery, and can be used for open focal osteosynthesis in fractures of the lower jaw. In case of fractures of the lower jaw, the main type of surgical treatment is osteosynthesis of the jaw using titanium mini-plates and mini-screws; a large number of designs have been developed at the moment, depending on the clinical case. The main direction in the development of surgical technologies is to reduce the size of surgical products while maintaining their basic mechanical properties. Nanostructured titans possess these properties, one of which is Grade-4 titanium using equal channel angular pressing technology, the use of which will reduce the size of the plate (Valiev R.Z., Klevtsov G.V.) [1, 2, 4]. The surface properties of this material make it possible to give the plates new integration properties with bone tissue, which are regarded as osseointegration. (Nosov E.V., Matchin A.A., Stadnikov A.A.) [4, 6, 7].

The level of technology. Known mini-plate manufactured by Rusimplant. The product is made of titanium alloy Grade 2 with a thickness of 1.0 mm and a hole diameter of 2.3 mm. The positive qualities of this plate associated with its high strength properties and high biocompatibility are leveled by its greater thickness and the absence of submicrocrystalline structures on its surface [8].

A well-known rectangular mini-plate with rounded contours 46.4 mm long, 0.6 mm thick, it has 6 holes with a diameter of 1.7 mm at equal distance from each other, the width of the plate in the area of the holes is 4.4 mm, between the holes - 3.0 mm. This mini-plate is made of Grade-4 nanostructured titanium with surface treatment using the ECAP-comform method. (Klevtsova N.A., Klevtsov G.V. 2013) [4, 5]. This plate has a close structure and functional capabilities of the model, but differs in the brand of titanium and the absence of a macrorelief of the back surface of the mini-plate.

The prototype is a mini-plate manufactured by Konmet LLC, which has a straight shape with rounded contours with six holes at equal distances from each other for fixing with 0.6 mm thick mini-screws and made of pure titanium (US standard ASTM F 67-00 ) It has good mechanical properties, high biocompatibility, but differs in the grade of titanium and the absence of any nanostructured surface of the product [7].

The prototype has a close structure and functionality of the model, but differs in the brand of titanium and the absence of a macrorelief of the back surface of the mini-plate.

The task of the model is to create a mini-plate with a macro-relief on its surface, which increases the stability of fragments of the lower jaw, enhances the integration properties of the product, reduces the time of formation of a strong bond with bone tissue.

The problem is solved in that a mini-plate of nanostructured titanium, which is made by equal channel angular pressing (ECAP-comform) [3], creates a relief surface in the form of square grooves with a depth of 0.1 mm and a distance of 0.1 mm between them oriented parallel to the length and width of the plate over the entire area in contact with the surface of the bone tissue.

The proposed model allows to obtain the following technical effect. The structure of the plate allows you to enhance mechanical stability during the fixation of fragments of the lower jaw due to the contact of the relief surface with the bone and the formation of a larger contact area of the product surface and the cortical bone plate, which will strengthen the osseointegration properties of the material.

The essence of the utility model. A mini-plate for open focal osteosynthesis of the lower jaw, having a rectangular shape with rounded contours 46.4 mm long, 0.6 mm thick, there are 6 holes with a diameter of 1.7 mm at an equal distance from each other, the width of the plate in the area of the holes is 4.4 mm, between the holes - 3.0 mm. The mini-plate is made of nanostructured titanium grade Grade-4. On the back (bone-contacting) surface of the plate there is a relief in the form of square recesses measuring 0.1 by 0.1 mm, a depth of 0.1 mm and distances between adjacent recesses of 0.1 mm, oriented parallel to the length and width of the plate. This relief makes it possible to enhance the spatial stability of the mini-plate, not only by fixing it with mini-screws, but also by leveling the sliding effect relative to the cortical plate.

The relief surface enhances the ability of osseointegration with bone tissue of Grade-4 nanostructured titanium with surface treatment using the method of ECAP-conform (Pat. 2383654 Valiev R.Z., Semenova I.P., Yakushina E. B., Salimgareeva G. Kh. , 2008) [3].

The plate is presented in the drawings (Fig. 1, Fig. 2). In FIG. 1 shows the general structure of the plate; FIG. 2A is a fragment of a plate in the region of the hole; in FIG. B is a three-dimensional fragment of the plate in the region of the hole

The mini-plate is rectangular in shape with rounded contours 46.4 mm long, 0.6 mm thick, it has 6 holes with a diameter of 1.7 mm at an equal distance from each other, the width of the plate in the area of the holes is 4.4 mm, between the holes - 3.0 mm. On the back (bone-contacting) surface of the plate there is a relief in the form of square grooves measuring 0.1 by 0.1 mm, a depth of 0.1 mm and distances between adjacent protrusions of 0.1 mm, oriented parallel to the length and width of the plate.

Implementation of a utility model. After adequate pain relief, an incision is made in the skin and subcutaneous fatty tissue parallel to the edge of the lower jaw, departing from it by 1.5-2 cm in the projection of the fracture line with a length of 7-8 cm. Stupidly and sharply reach the edge of the lower jaw and expose the fracture line. Using a raspator, it is skeletonized in the fracture area for its full visualization. With the help of rigid clamps, fragments are matched in the correct position. The mini-plate is fixed to one of the fragments. Using a boron machine, an opening is made in the cortical plate of the body of the lower jaw through the opening of the mini-plate. To prevent bone burn during drilling, water cooling is used. A mini-screw is placed in the hole made, which is screwed to the stop with a screwdriver. For reliable fixation on the fragment must be at least two mini-screws. Another fragment is fixed in the correct position and clamped with a hard clip along with the mini-plate. The holes and the fixing of the mini-screws is made similarly to the opposite side. Soft tissues are sutured in layers with active drainage and removal of the latter 2 days after surgery.

Application examples. A series of experiments on rabbits to study the interaction of nanostructured titanium with bone and soft tissues surrounding it have been performed at the Department of Histology, Cytology and Embryology, Federal State Budgetary Educational Establishment of Higher Educational Institution “Orgmu” of the Ministry of Health of the Russian Federation, which makes it possible to assess the possibility of the clinical use of Grade-4 titanium with surface treatment using technology ECAP-conform (equal-channel angular pressing) in dentistry and maxillofacial surgery for use in the clinic of titanium plates for osteosynthesis of mandibular fractures tee.

Studies were performed on chinchilla rabbits. All animals normally underwent surgery. The wounds healed by primary intention. After a month of observation, the animals were withdrawn from the experiment. 2 variants of reactive changes in the zone of contact with the implant were established. Three rabbits showed lamellar bone structures with dilated osteon channels, full-blooded blood vessels, and perivascular osteoblasts. In other cases, fragments of lamellar bone tissue alternated with bundles of dense fibrous connective tissue. Resorption zones where osteoclasts were located were recorded. Between the bone beams of the spongy substance of the bone, a yellow bone marrow without myeloid cells is determined.

When examining the zone of fracture of the lower jaw on the 7th day, fragments of the damaged bone reveal uneven sizes of the vascular and bone channels containing dilated and blood-filled vessels. Sections of the cortical layer adjacent to the lesion zone become homogeneous, osteocytes are not detected in them and bone plates are not distinguished. The fracture area is filled with osteoblastic granulation tissue containing a large number of fibroblasts and osteoblasts. Cellular elements in the center of the regenerate are randomly located. In the fracture zone, an inflammatory reaction develops, which persists after 14 days from the injury. It is manifested by the expansion and blood filling of blood vessels, proliferation of cellular elements of the periosteum, its thickening. In the parts of the jaw adjacent to the fracture zone, pronounced reactive changes occur. They are manifested by the disappearance of osteocytes, a violation of the organization of bone tissue. In bone with a changed structure, the detection of acid mucopolysaccharides is sharply enhanced. This indicates the breakdown of protein-polysaccharide complexes, as a result of which mucopolysaccharides become available for histochemical research methods. Bone tissue with a disturbed structure undergoes resorption by osteoclasts. In parallel, active reparative processes begin in the fracture zone. Bone callus neoplasm begins with the formation of osteoblastic granulation tissue, which on day 7 does not yet have a fibrous structure.

By the 14th day, numerous fibrillar structures appear in the regenerate. Further transformation of the fibrous tissue leads to the appearance of osteoid tissue. However, by 21 days of complete replacement of the fracture zone with osteoid tissue, the fracture zone does not yet occur. It should be noted that histochemical changes precede structural changes. At the beginning of the repair process, acid mucopolysaccharides accumulate in immature connective tissue. As fibers form, the content of these substances decreases. This indicates that acid mucopolysaccharides are used as plastic material for the construction of ossein fibrils. Our observations confirm the opinions of other researchers that the studied substances are part of collagen fibers. The appearance of the reaction of fibers to SEC-positive structures characterizes their further structural rearrangement. An active plastic process in the regenerate is preceded and accompanied by their increase in the content of ribonucleic acid in cellular elements. This indicates an increase in the processes of protein synthesis in the regeneration zone.

When radiovisiography in the field of osteosynthesis revealed a consolidating fracture without pathological changes around the screws and plates and the absence of pathological changes in the area of osteosynthesis. Examination using a Lext OLS 4000 laser scanning confocal microscope established full contact of bone tissue with the inner surface of the mini-plate and the threaded surface of the mini-screw along its entire length. The results obtained indicate that when using mini-plates and mini-screws made of nanostructured titanium, direct contact of bone tissue with their surface was established, which is regarded as osseointegration.

Preliminary results allow us to conclude that in most cases direct contact of bone tissue with a titanium implant was established, which should be regarded as osseointegration. On the other hand, there are sections of the reorganization of the tissues of the lower jaw on the surface of the implantate / bone interface with signs of fibro-bone integration.

Thanks to the obtained experimental data, a model of a mini-plate made of nanostructured titanium with a relief on the back surface of the plate is proposed, which will enhance the osseointegration properties of the material and the spatial stability of the mini-plate due to osseointegration processes on the surface of the product and between the relief structures.

Bibliographic list

1. Nanostructured titanium obtained by intensive plastic deformation for medical implants / Valiev R.Z. [et al.] // Matiriel Saints Forum.-2008.-T. 584-586.-C. 49-54.

2. Valiev R.Z., Semenova I.P., Latysh V.V., Scherbakov A.V., Yakushina E.B. Nanostructured titanium for biomedical applications: new developments and prospects for commercialization // Russian Nanotechnology. 2008.V.3. No. 9-10. S.80-89.

3. Pat. 2383654 Russian Federation IPC C22F 1/18 B82B 3/00 Nanostructured technically pure titanium for biomedicine and a method for producing a bar from it / Valiev R.Z., Semenova I.P., Yakushina E. B., Salimgareeva G. Kh .; Applicant and patent holder of UFGATU. - No. 2008141956/02; declared 10/22/2008, publ. 03/10/2010 Bull. No. 7. - 6 p.

4. Rogova T.F., Klevtsova N.A., Arslanova G.S., Matchin A.A., Nosov E.V. Mechanical properties and biocompatibility of nanostructured titanium products for maxillofacial surgery // University complex as a regional center of education, science and culture. Materials of the All-Russian Scientific and Methodological Conference (with international participation); Orenburg state un-t - Orenburg: LLC IPK "University". February 29–31, 2013 .-- P.1481.

5. Kashapov M.R., Klevtsova N.A., Ishteryakov V.I., Rogova T.F., Klevtsov G.V. Miniaturization of Grade 4 titanium plates due to the formation of a submicrocrystalline structure // University Complex as a Regional Center for Education, Science and Culture Materials of the All-Russian Scientific and Methodological Conference (with international participation); Orenburg state un-t - Orenburg: LLC IPK "University". January 30-February 01, 2013 - S.1076-1079

6. Matchin A.A., Klevtsov G.V., Stadnikov A.A., Merson E.D., Mikhailova I.A., Nosov E.V. Morphological aspects of reparative osteogenesis using a nanostructured titanium implant // Morphology. - 2014.- No. 3. - S. 126.

7. Matchin A.A., Stadnikov A.A., Klevtsov G.V., Nosov E.V., Merson E.D. Features of reparative osteogenesis when fixing fragments of the lower jaw with mini plates and mini screws made of nanostructured titanium // Morphology. - 2016.- No. 3. - S. 134 - 135.

8. The catalog of products of LLC Konmet 2016. C.6 [Electronic resource]

http://www.conmet.ru/r_chere.html#CAT_MINIPL

9. Product catalog of the company "Rusimplant" [Electronic resource]

http://www.rusimplant.ru/catalog/implantaty-dlja-cheljustno-licevoj-hirurgii/miniplastiny-vinty-dlya-chelyustno-licevoj-xirurgii/

Claims (1)

A mini-plate for osteosynthesis of fractures of the lower jaw, having a rounded contour shape and six holes at an equal distance from each other, characterized in that it is made of Grade-4 nanostructured titanium by the method of equal channel angular pressing, the presence of a relief surface in the form of square-shaped recesses with dimensions 0.1 to 0.1 mm, a depth of 0.1 mm and a distance between adjacent recesses of 0.1 mm, oriented parallel to the length and width of the plate on the surface adjacent to the bone.

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