RU213082U1 - An individual surgical template for osteosynthesis in case of a fracture of the condylar process of the mandible - Google Patents

Abstract

The utility model relates to medicine, namely to maxillofacial surgery and surgical dentistry. The method consists in accurate repositioning of bone fragments of the lower jaw during osteosynthesis of a fracture of the condylar process and precise positioning of titanium extramedullary mini-plates using an individual surgical template.

The technical result of the proposed utility model is to improve the positioning accuracy of titanium extramedullary mini-plates and screws for fixing bone fragments in case of a fracture of the condylar process of the lower jaw.

An individual surgical template for osteosynthesis for fractures of the mandibular condylar process includes a body made of biocompatible plastic, the body is made in the form of a plate 1.5 mm thick, with recesses at the location of titanium extramedullary mini-plates and holes for drilling and installation of screws. The difference is that it has three clasps, in the region of the lower jaw cut above the fracture line there is an upper clasp, on the posterior edge of the lower jaw branch below the fracture line there is a rear clasp, the upper and rear clasps have a bend of 5 mm, and the front clasp is made without a bend.

Description

The utility model relates to medicine, namely to maxillofacial surgery and surgical dentistry. The method consists in accurate repositioning of bone fragments of the lower jaw during osteosynthesis of a fracture of the condylar process and precise positioning of titanium extramedullary mini-plates using an individual surgical template.

The main surgical method for the treatment of mandibular fractures is osteosynthesis using titanium extramedullary mini-plates. The final position of the titanium extramedullary mini-plates and the assessment of the position of the bone fragments is determined by the surgeon during the osteosynthesis operation.

The earlier X-ray examination, as well as the ideal lines of osteosynthesis in the area of the condyle process, described by Meyer (Meyer C., Kahn J.L., Boutemi P., Wilk A. Photoelastic analysis of bone deformation in the region of the mandibular condyle during mastication. J) are helpful. Craniomaxillofac Surg., 2002).

But due to limited surgical access and the lack of visualization of intraosseous structures, this technique has a number of serious drawbacks:

1. The application of two straight titanium mini-plates, necessary to meet the requirements of stable functional osteosynthesis, is difficult due to insufficient visualization of bone structures during surgery, and therefore there is a risk of incorrect reposition and fixation of bone fragments.

2. Damage to the neurovascular bundle of the lower jaw with a drill or a fixing screw can lead to anesthesia or hypoesthesia in the region of innervation of the lower alveolar nerve; bleeding during surgery or hematoma formation in the postoperative period.

3. The area of bone tissue in the region of the neck of the condylar process of the mandible has a narrowing, which makes it difficult to select and adapt titanium extramedullary mini-plates for fixing bone fragments.

4. Increasing the time of surgical intervention due to the choice and adaptation of titanium extramedullary mini-plates.

An individual surgical template is known for performing osteosynthesis for fractures of the angle and body of the lower jaw (patent RU 208411 application No. 2021118026, class IPC A61B 17/17, publication date 12/16/2021).

A well-known individual surgical template for osteosynthesis for fractures of the angle and body of the lower jaw, including a body made of biocompatible plastic with recesses, is distinguished by the fact that the body is made in the form of a plate 1.5 mm thick, repeating the relief of the jaw, with recesses for titanium bone mini- plate, the lower curved edge of the template is 0.25 of the total length of the body and is made in such a way that it goes around the edge of the lower jaw and goes beyond the inner surface of the lower jaw by 5-7 mm.

The disadvantage of the known template is that it is not suitable for fracture of the condylar process of the lower jaw.

The technical result of the proposed utility model is to improve the positioning accuracy of titanium extramedullary mini-plates and screws for fixing bone fragments in case of a fracture of the condylar process of the lower jaw.

An individual surgical template for osteosynthesis in fractures of the condylar process of the lower jaw includes a body made of biocompatible plastic, the body is made in the form of a plate 1.5 mm thick, with recesses at the location of titanium extramedullary mini-plates and holes for drilling and installing screws.

The difference is that there are three clasps: in the area of the lower jaw cut above the fracture line there is an upper clasp, on the posterior edge of the lower jaw branch below the fracture line there is a rear clasp, the upper and posterior clasps have a bend of 5 mm, and the front clasp is made without a bend.

The proposed individual template is planned on the basis of multislice computed tomography of the bones of the facial skeleton (scanning slice thickness 0.6 mm). In the 3D modeling program, a virtual comparison of bone fragments in the area of the fracture and positioning of the model of titanium bone mini-plates is carried out. The template is modeled on the basis of the obtained relief of the lower jaw with models of titanium extramedullary mini-plates.

The essence of the utility model is shown in Fig. 1-4, which shows the proposed template.

The design of an individual surgical template has a number of distinctive features: the body thickness is 1.5 mm, which is optimal for the rigidity of the entire structure and sufficient to temporarily hold the bone fragments in the correct position; for drilling and installing screws; in the region of the lower jaw cut above the fracture line there is an upper clasp (3), on the posterior edge of the lower jaw branch below the fracture line there is a posterior clasp (4), the upper and posterior clasps pass to the inner surface of the lower jaw up to 5 mm, the anterior clasp (5) reaches the anterior edge of the lower jaw branch without passing to the inner surface.

The presence of such features in the formula of the utility model as a thickness of 1.5 mm, repeating the relief of the jaw, recesses for titanium mini-plates, the presence of clasps in the front, back and upper parts of the body for stable fixation to the lower jaw - allow you to firmly hold the fragments in correct positioning and precise positioning of the mini-titanium bone plates. The bend of the upper and rear clasps by 5 mm allows you to securely fix the template on bone fragments and thus increase the positioning accuracy.

The template is made on a 3D printer from biocompatible plastic and subsequently sterilized by autoclaving in a gentle mode (temperature +120°C, pressure 1.1 atmospheres, time 45 min).

All features of the formula of the utility model are essential and their use will improve the positioning accuracy of bone fragments and titanium extramedullary mini-plates, reduce the risk of intra- and postoperative complications, and reduce the time of surgical intervention in case of fracture of the condylar process of the mandible.

Clinical example.

Patient R. (b. 1992) was treated at the Department of Maxillofacial Surgery with a diagnosis of a displaced mandibular fracture along the condylar process on the right. At the preoperative stage, multispiral computed tomography of the bones of the facial skeleton was performed, tooth splinting was performed using the Tigerstedt method. After immobilization, the displacement of the fragments was preserved. The patient was prescribed antibacterial, analgesic, desensitizing therapy. An emergency operation was scheduled. The obtained results of multislice computed tomography were processed in a graphical editor, in which the virtual reposition of bone fragments, positioning of titanium mini-plates and fixing elements were performed. An individual surgical template is modeled, which is subsequently made using a 3D printer. Before surgery, the template was sterilized by autoclaving.

Surgical treatment was carried out according to the standard protocol of bone osteosynthesis using an individual surgical template: under endotracheal anesthesia, an incision was made in the mucous membrane of the anterior edge of the lower jaw branch, passing to the anterior edge of the masticatory muscle proper. The anterior edge of the mandibular ramus was sharply and bluntly identified, and the outer surface of the mandibular ramus was skeletonized with visualization of the fracture line. Titanium bone mini-plates were placed in the template and adapted according to the surface topography. The template was placed in the surgical wound, then sequentially using clasps in the upper and posterior edges of the body, the template was fixed on small and large bone fragments, then the front clasp was fixed on the front edge of the lower jaw branch. With the help of a physiodespenser, burr holes were formed for fixing elements, and then, using screws and an angled screwdriver, titanium mini-plates were fixed. Screw channels were formed on the contra-angle tip, then titanium bone mini-plates were fixed with screws using an angled screwdriver. The template was then removed. The stability of osteosynthesis and the state of the bite were assessed, the tissues were sutured, the wound in the oral cavity was drained with a glove graduate. The drainage was removed on the 2nd day, the sutures were removed on the 7th day. The wound healed by first intention. On the tenth day, the dental splints were removed. On the control X-ray examination, the position of the fragments is correct. The postoperative period passed without complications. In the late postoperative period after three months, the mouth was opened in full, the bite was orthognathic.

Claims (1)

An individual surgical template for osteosynthesis for fractures of the condylar process of the lower jaw, including a body made of biocompatible plastic, the body is made in the form of a plate 1.5 mm thick, with recesses at the location of titanium extramedullary mini-plates and holes for drilling and installing screws, characterized in that that the template was made on the basis of planning according to multislice computed tomography of the bones of the facial skeleton, a 3D modeling program with virtual comparison of bone fragments in the area of the fracture and positioning of the model of titanium bone mini-plates and was made using a 3D printer, while it has three clasps in the area The lower jaw notch above the fracture line has an upper clasp, on the posterior edge of the lower jaw branch below the fracture line there is a posterior clasp, the upper and posterior clasps have a bend of 5 mm, and the anterior clasp is made without a bend.

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