RU2491899C1 - Implanted endoprosthesis for mandibular bulk bone defect replacement - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to restorative and reconstructive maxillofacial surgery. An implanted endoprosthesis for mandibular bulk bone replacement is made in accordance with computer tomography by means of symmetric computer transformation. The above implanted endoprosthesis is presented in the form of a one-piece hollow block made of titanium nickelide and comprises a mandibular body with two perforated titanium screw locks, a mandibular angle, ramus bones with spherical condyloid process, coronoid process with a temporal muscle ligament lock with a slot 3 mm long on an outer surface of the mandibular body and ramus bones for the inferior alveolar neurovascular bundle to be placed.

EFFECT: invention provides the stable connection with the preserved mandibular bone fragment on one side, and with the glenoid cavity on the other side, as well as provides the inferior alveolar neurovascular bundle to be placed.

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Description

The invention relates to reconstructive and reconstructive maxillofacial surgery.

As you know, the lower jaw consists of bone tissue covered with an interacting periosteum, contains two articular heads that interact with the articular fossa of the temporal bones.

During surgical removal of the lower part due to the treatment of volume tumors, traumatic injuries or inflammatory processes, a volume bone defect arises, leading to functional and aesthetic disorders.

The success of restoration of a volume bone defect in the lower jaw after surgical treatment as a whole depends on the design features of the implant that replaces the defect, the immune inertness of the materials the implant is made of, and the features of their interaction with the surrounding tissues.

Today, endoprosthesis implants are widely used as replacement implants for the removal of volume bone defects in the lower jaw, which only partially restore functional and aesthetic disorders.

In particular, an implant-endoprosthesis is known - a fixative for reconstruction of bone defects in the lower jaw, having end parts in the form of rods placed intraosseously and an arch connecting these rods placed in a previously prepared bed (patent RU 2285500, IPC A61F 2/28).

However, this implant-endoprosthesis is designed to provide a fixed connection with a bone fragment and is designed to integrate only with bone structures.

An implant endoprosthesis is also known for replacing bone fragments of complex shape from an alloy based on titanium nickelide, containing a formable support base made in the form of a wire spiral covered with a mesh material along the entire length and fastened with it an element of communication with the surrounding tissue (patent RU 2265417, IPC A61F 2/28).

However, with extensive defects of the lower jaw, the use of this implant-endoprosthesis does not provide satisfactory replacement of the bone defect, since the modeling of its contours using a single cylindrical spiral is not effective enough to restore the entire anatomical shape of the defect to be repaired.

In addition, the use of this implant-endoprosthesis does not provide functional interaction with tendon-muscle tissues. This causes a change in the spatial ratio of the axles of muscle traction, changes in the moments of forces, and a violation of the biomechanics of the lower jaw. Such defects lead to irreversible severe functional impairment and significantly reduce the quality of life and functional rehabilitation of patients.

In addition, all of the listed implants-endoprostheses for replacing bone defects of the lower jaw are made in one standard size without clear individualization according to the anatomical and topographic parameters.

From the existing level of technology there is known “A method for the preventive manufacture of an individualized implant for the simultaneous replenishment of a planned defect in the surgical removal of a tumor of the lower jaw” (RU 2164391 C1, IPC ⁷ A61F 2/28).

The method includes measuring the volumetric mathematical parameters of the tumor of the lower jaw tissue using computed tomography. When planning a resection of the lower jaw with violation of bone continuity without exarticulation, computer mathematical ones are performed to determine the parameters of the implant - resection of the tissues of the lower jaw, including the tumor, formation of the receptive bed defect at the ends, application of the parameters of a symmetric healthy tissue obtained by a symmetric computer transformation to obtain a differential evaluation of the parameters of the resected and healthy part of the lower jaw, which will be the parameters of the imp antata.

When planning a resection of the lower jaw with disruption of bone continuity with exarticulation, computer mathematical ones are performed to determine the parameters of the implant - resection of the tissues of the lower jaw, including the tumor, formation of the receptive bed at the end of the defect, the application of the mathematical parameters of the symmetric healthy tissue obtained by the symmetric computer transformation, adaptation to the resulting defect the articular head of the implant to the articular fossa of the skull and the contact surface of the implant to the receptor box stored fragment jaw, by the difference parameter estimation resected and healthy part of the mandible is prepared volume parameters. An implant is made by transferring parameters to an automatic prototyping device. The implant is sterilized and placed in a package [4].

This method is adopted as a prototype. Advantages of this method: the invention allows the manufacture of an individualized implant to make up for the planned volumetric defect of the lower jaw in one operation.

The disadvantages of the prototype are an unstable connection with a preserved bone fragment of the lower jaw, the difficulty of adapting the articular head of the implant to the articular fossa of the skull and the contact surface of the implant to the receptive bed of the saved fragment of the jaw without additional devices, the difficulty of placing the lower alveolar neurovascular bundle.

The task was to develop an implant-endoprosthesis to replace a volumetric bone defect in the lower jaw, capable of providing a stable connection on the one hand with a preserved bone fragment of the lower jaw, on the other hand, with the articular fossa of the skull, and also ensure the placement of the lower alveolar neurovascular bundle.

The problem is solved by using an implant-endoprosthesis to replace a volumetric defect of the lower jaw, obtained according to computed tomography using a symmetric computer transformation made by transferring parameters to an automatic prototyping device. The implant-endoprosthesis is presented in the form of a monolithic hollow block, made of titanium nickelide (Fig. 1), has a lower jaw body (1) with two perforated retainers for titanium screws (2), jaw angle (3), jaw branches (4) with the condylar process of a spherical shape (5), the coronoid process (6) with a fixator for the tendon of the temporal muscle (7). The outer surface of the body (1) and jaw branch (4) has a groove (8) with a depth of 3 mm to accommodate the lower alveolar neurovascular bundle.

The perforated retainer for titanium screws (2) is made of two titanium plates with perforations for fixing the implant to bone tissue.

The condylar process of spherical shape (5) allows it to be installed in the articular fossa of the temporal bone and to provide the maximum amplitude of the movements of the lower jaw.

On the one hand, the branch of the implant of the lower jaw has a condylar process of spherical shape, the coronoid process has a tendon fixator of the temporal muscle.

The implant-endoprosthesis has a volumetric configuration and corresponds to the size of the eliminated defect of the lower jaw from the chin symphysis to the articular fossa of the temporal bone (figure 2). The volumetric, hollow design of the implant allows you to anatomically correctly distribute muscle fibers that are detached during surgery and adapt them taking into account the functional orientation, which allows you to restore muscle activity as accurately as possible during the patient's rehabilitation period. In addition, this design allows subsequent restoration of the dentition using dental implants.

A groove (8) with a depth of 3 mm on the outer surface of the body and the branch of the implant-endoprosthesis is designed to accommodate the lower alveolar neurovascular bundle, it minimizes trauma to blood vessels and nerves, and ensures rapid restoration of innervation, blood supply and sensitivity in the postoperative period.

The proposed design makes it possible to optimally adapt tendon-muscle structures around the elements of the titanium implant, which creates favorable conditions for reparative regeneration, which in general allows restoration of their early functional activity.

In addition, experimental experimental studies on animals have shown that the use of other materials (for example, silicone or plastic) for the manufacture of an implant-endoprosthesis is impractical due to a decrease in the strength of the entire structure during chewing.

The clinical efficacy of using a titanium implant-endoprosthesis in the reconstruction of lower jaw defects has been confirmed by clinical trials.

Clinical example.

Patient F., 18 years old, was admitted to the maxillofacial department of the city hospital No. 4, the city of Stavropol, 02/25/2008, medical history 1477/4.

Diagnosis: ameloblastoma of the lower jaw on the left with a spread of 32 teeth, with damage to the body, branch, condyle, coronoid process. 2 cm mouth opening.

After performing computed tomography using a symmetric computer transformation, by transferring parameters to an automatic prototyping device, the design, simulation and manufacture of the inventive titanium implant-endoprosthesis were performed.

Under endotracheal anesthesia, a tumor-affected fragment was removed from the submandibular access to the left with exarticulation of the temporomandibular joint. During the operation, the sections of muscles cut off from the corresponding surfaces of the removed jaw fragment are taken on ligatures:

a) the submental-hyoid, the bottom of the oral cavity, the anterior abdomen of the biceps muscle;

b) medial pterygoid, lateral pterygoid;

c) chewing, temporal muscles.

On a healthy bone fragment in the projection of the chin symphysis, a receptive bed is formed under the perforated retainer plates. A spherical head of the condyle was introduced into the distal portion of the surgical wound, with an accurate topographic orientation, implanted into the articular fossa.

After complete installation of the titanium implant-endoprosthesis, the distal sections of all the above muscle groups were fixed around the surface of the titanium implant in the places of their physiological attachment, installation of active drains, suturing of the skin.

The postoperative period proceeded against the background of drug therapy without inflammatory complications. The configuration of the lower jaw was restored, the state of the bite was adequate, the volume of the main functional movements of the jaw was restored after 2 months.

The long-term observation period is more than 3 years. Functional and clinical examination data reliably confirm the presence of muscle mass, functional tone and the interaction of synergistic and antagonistic muscle groups attached to the surface of the implant-endoprosthesis.

Thus, the invention provides the reconstruction of formative and supporting defects of the volumetric bone fragment of the lower jaw, a stable connection of the titanium implant-endoprosthesis with healthy bone tissues, which allows to achieve anatomical and functional compliance with volumetric reconstructive surgical interventions in the maxillofacial region.

INFORMATION SOURCES

1. Roginsky V.V., Evseev A.V., Kotsyuba E.V. et al. Laser stereolithography, a new biomodeling method in craniofacial surgery // Pediatric Dentistry. - 2000. - No. 1-2 (3.4). - S. 92-95.

2. Stuchilov V.A., Nikitin N.N., Evseev A.V. et al. Clinical aspects of using the method of laser stereolithography in the surgical treatment of injuries of the middle zone of the face // Clinical Dentistry. 2001. - No. 3. - S. 54-57.

3. Shalumov A.-S.Z. A method of manufacturing an individualized predisional implant to make up for a complex subtotal polyossal orbital defect. RU 2164392, bull. No. 9, 2001.

4. Shalumov A.-S.Z. A method for the preventive manufacture of an individualized implant for the simultaneous completion of a planned defect during surgical removal of a lower jaw tumor. RU 2164391 C1, IPC ⁷ A61F 2/28.

5. Rapid prototyping & manufacturing: fundamentals of stereolithography, ed. P.F. Jacobs, SME, Dearborn MI, 1992, 434 p.

6. Proceedings of the 5th European Conference on Rapid Prototyping and Manufacturing (4-6 June, 1996, Helsinki, Finland): Ed. P.M. Dickens.

Claims (1)

An implant-endoprosthesis for replacing a volume bone defect in the lower jaw, obtained by computed tomography using a symmetric computer transformation, made by transferring parameters to an automatic prototyping device, characterized in that it is made in the form of a monolithic hollow block of titanium nickelide, includes a lower jaw body with two perforated retainers for titanium screws, jaw angle, jaw branches with a condylar process of spherical shape, coronoid process with ph xator for the tendon of the temporal muscle, with a groove depth of 3 mm on the outer surface of the body and branches of the jaw to accommodate the lower alveolar neurovascular bundle.

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