RU2698984C1 - Method for planning an installation of orthodontic implants - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, namely to orthodontic and surgical dentistry, and is intended for installation of orthodontic implants. Disclosed is a method for planning an installation of orthodontic implants, involving conical-beam computed tomography, taking impressions, making models. Manufactured models are then scanned to obtain scans thereof in .STL format. Then, cone-beam computer tomography data in .DCM format and model scans in .STL format are loaded into "Avantis 3D" program, and according to obtained data "grid" is constructed, and by reference points cone-beam tomography and scans are compared, with further installation of orthodontic implants taking into account sizes of inter-root areas of interest, as well as arrangement of vessels and nerves, making a surgical template.

EFFECT: invention provides improved quality of installation of orthodontic implants, higher accuracy of planning during their installation and, as a result, decreased surgery time and postoperative complications.

1 cl, 12 dwg

Description

FIELD OF THE INVENTION

The invention relates to medicine, namely to orthodontic and surgical dentistry, and is intended for the installation of orthodontic implants.

State of the art

Orthodontic implant - a new tool for eliminating dentoalveolar anomalies and deformations, is gaining more and more popularity. With the help of orthodontic implants, you can change the position of a single tooth, and groups of teeth, and even the intermaxillary ratio [1]. Their installation requires a high level of knowledge of the biomechanics of tooth movement and the anatomy of the maxillofacial region. However, if the principles of biomechanics are spelled out in the scientific literature, then compulsory X-ray examination, namely cone beam computed tomography, is required to obtain knowledge about the individual anatomical features of the patient [2].

Cone-beam computed tomography allows you to learn in detail about the condition of the jaw bone tissue, its quantity, quality, the presence of inflammatory processes, to know the sizes of the interroot areas of interest, as well as the location of blood vessels and nerves [3].

In particular, the use of individual surgical templates is necessary for more accurate navigation of the cutters and the correct positioning of orthodontic implants. Currently, analogues of the proposed solution are templates made using compression molding of plastic.

Closest to the proposed technical solution is a method of installing an orthodontic implant described in the patent of the Russian Federation for invention No. 2427343, class. IPC A61C 8/00, publ. 08/27/2011.

Install the implant in a known manner in compliance with typical rules of hygiene and anesthesia.

Accordingly, with the x-ray image, the installation area is selected. Then, a 3-4 mm incision is made to exfoliate the periosteal tissue from the bone, using a boron in the cortical layer of the bone, a canal is drilled with a diameter of approximately 1.0-1.5 mm and a depth of 1-3 mm, depending on the thickness of the cortical layer. The implant is inserted into the key and, with little effort, manually inserted into the bone tissue. The incision does not need to be sutured.

This technique is used to install orthodontic implants, without more accurate positioning of orthodontic implants, the operation is performed without the use of surgical templates.

Disclosure of invention

The present invention is to carry out more accurate planning when installing orthodontic implants.

The technical result of the invention is to improve the installation quality of orthodontic implants, improve the accuracy of planning during their installation, and as a result, reduce the time of the operation and postoperative complications.

The indicated technical result is achieved in that the method of planning the installation of orthodontic implants involves performing cone beam computed tomography, imprinting, making models, the manufactured models are scanned, their scans are received in .STL format, then cone beam computed tomography data in .DCM format and scans of models in .STL format are loaded into the Avantis 3D program, and according to the data obtained, a “grid” is constructed, and cone-beam tomography and scans are compared using reference points cial installing orthodontic implants based on sizes of interest mezhkornevyh portions, as well as vessels and nerves arrangement, manufacturing surgical template.

The use of the method of planning the installation of orthodontic implants allows you to determine, taking into account the anatomical features of the alveolar ridge, the sizes of the inter-root sections of interest, as well as the location of the vessels and nerves, the exact location of the orthodontic implants, reduce the time of the operation, postoperative complications.

Brief Description of the Drawings

In FIG. 1 shows a comparison of computed tomography data and scans for reference points on the lower jaw, where 1 is a cone beam computed tomography in .DCM format; 2 - scan of the model in .STL format; 3 - view of the associated cone beam computed tomography and scans of the lower jaw; X - reference points.

In FIG. 2 presents a comparison of computed tomography data and scans for reference points on the upper jaw, where 4 is a cone beam computed tomography in .DCM format; 5 - model scan in .STL format; 6 is a view of a matching cone beam computed tomography and scans; X - reference points.

In FIG. 3 presents a computed computed tomography and scans of the upper and lower jaw, where - 7 is a view of the associated computed tomography of the upper and lower jaw; 8 is a view of the associated scans of the upper and lower jaw; 9 is a view of a matching cone beam computed tomography and scans of the upper and lower jaw.

In FIG. 4 presents a computed computed tomography and scans of the upper and lower jaw and an orthodontic implant (view from the vestibular surface), where 9 is a view of the associated cone beam computed tomography and scans of the upper and lower jaw; 10 - orthodontic implant.

In FIG. 5 presents a computed computed tomography and scans of the upper and lower jaw and an orthodontic implant (view from the palatal surface), where 9 is a view of the associated cone beam computed tomography and scans of the upper and lower jaw; 10 - orthodontic implant.

In FIG. 6 shows cone beam computed tomography and an orthodontic implant (view from the vestibular surface), where 7 is a view of the associated computed tomography of the upper and lower jaw; 10 - orthodontic implant.

In FIG. Figure 7 shows cone beam computed tomography and an orthodontic implant (view from the palatine surface), where 7 is a view of the associated computed tomography of the upper and lower jaw; 10 - orthodontic implant.

In FIG. 8-10 are photographs of the patient during the operation.

In FIG. 11-12 are photographs of the patient 7 days after surgery, with orthodontic traction.

The implementation of the invention

The method of planning the installation of orthodontic implants is as follows.

The patient undergoes cone beam computed tomography, receive data in .DCM format.

A dentist orthopedist takes impressions, makes models. The manufactured models are scanned, their scans are received in .STL format. Then, the data of cone beam computed tomography in .DCM format and model scans in .STL format are loaded into the Avantis 3D program. The Avantis 3D program is intended for planning, making templates, calculating the volume of material for bone grafting.

According to the data obtained, a “grid” is constructed, and cone-beam tomography and scans are compared by reference points (scene). Reference points - points at which the combination of model scans and computed tomography is performed; a combined version of model scans and computed tomography is called the scene.

Next, they perform the installation of orthodontic implants taking into account the sizes of the inter-root sections of interest, as well as the location of the vessels and nerves, and the manufacture of a surgical template.

Implementation example.

A patient, a dentist, orthodontist, was sent to our clinic to install orthodontic implants, at the age of 50 years.

On examination: on the upper jaw teeth 2.6, 2.7, the mucous membrane of the oral cavity is pale pink, moderately moist, without pathological changes.

To ensure rational prosthetics, it is necessary to increase the occlusal height in the area of 2.6, 3.6 and 2.7, 3.7 teeth, it is necessary to intrude teeth 2.6, 2.7.

Diagnosis: 26, 27 (Z 96.5) Tooth alveolar extension.

The operation was performed under local anesthesia, using a physiological dispenser and a surgical template (see photo in Fig. 8), installation of 1.4 x 10 orthodontic implants, from the vestibular side (see photo in Fig. 9), from the palatine side (see photo in Fig. 10).

Were prescribed: non-steroidal anti-inflammatory drugs, oral baths with solutions of antiseptics. In the postoperative period, moderate pain was observed for 3 days. The patient felt satisfactory.

On the day of surgery, traction was installed on orthodontic implants. The patient felt well, the appearance of orthodontic implants after 7 days, from the vestibular side (see photo in Fig. 11), from the palatine side (see photo in Fig. 12).

The use of the method of installing orthodontic implants allows you to determine, taking into account the anatomical features of the alveolar ridge, the sizes of the inter-root sections of interest, as well as the location of the vessels and nerves, the exact location of the orthodontic implants, reduce the time of the operation, postoperative complications.

A comparative analysis of the claimed invention showed that the set of essential features of the claimed method is not known from the prior art and therefore corresponds to the patentability condition “Novelty”.

In the prior art there were no signs that coincided with the distinguishing features of the claimed invention and affecting the achievement of the claimed technical result, therefore, the claimed invention meets the patentability condition "Inventive step".

The above information confirms the possibility of applying the proposed method in orthodontic and surgical dentistry for planning the installation of orthodontic implants, and therefore meets the patentability condition "Industrial applicability".

Information sources

1. Persin L. S. Orthodontics. Modern methods for the diagnosis of dentofacial anomalies. - M.: Medicine, 2007.

2. Ryakhovsky A.N. Digital Dentistry. Avantis LLC, Moscow, 2010, p. -282.

3. X-Ray Art No. 2 (01), February 2013.

Claims (1)

A method of planning the installation of orthodontic implants, including conical beam computed tomography, imprinting, manufacturing of models, the manufactured models are scanned, their scans are received in .STL format, then the data of cone beam computed tomography in .DCM format and model scans in .STL format loaded into the Avantis 3D program, and according to the data obtained, a “grid” is constructed, and cone-beam tomography and scans are compared by reference points with the further installation of orthodontic implants taking into account the sizes of inter-root sections of interest, as well as the location of blood vessels and nerves, the manufacture of a surgical template.

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