RU2683852C1 - Method for calculating bone-substituting material volume in planning of operation of directed bone tissue regeneration - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention relates to surgical dentistry. Disclosed is a method of calculating the volume of bone-substituting material when planning a guided bone regeneration operation, involving cone-beam computed tomography, taking impressions, making models, characterized by that the manufactured models are scanned, their scans are obtained in .STL format, then the cone-beam computer tomography data in .DICOM format and scans of models in .STL format are loaded into Avantis 3D program and based on obtained data "grid" is constructed, and reference points are used to compare cone-beam tomography and scans with further installation of implants in orthopedic profitable positions, further, a surgical template is made and the anatomical features of the alveolar crest are simulated and the exact volume of bone-substituting material required for targeted bone tissue regeneration is measured.EFFECT: invention provides reduced time of operation, reduced postoperative complications, reduced overexploitation of bone-substituting material.1 cl, 12 dwg

Description

FIELD OF THE INVENTION

The invention relates to medicine, namely to surgical dentistry and is intended for planning and calculating materials during reconstruction of the lower jaw with subsequent dental implantation.

State of the art

Targeted bone tissue regeneration is one of the most common and popular osteoplastic operations. A large number of methods of radiation diagnostics predetermined the need to highlight the most informative and least dangerous technologies for the patient at each stage of dental implantation. Today, the standard in examining patients is cone beam computed tomography [N. Nechaeva K., Modern 3-D diagnostics in implantology practice. Dentistry today No. 9 (149) 2015]. By analyzing cone beam computed tomography, one can not only determine the spatial configuration of the lower jaw, but also identify anatomical structures that can affect the course of surgery. The experience of using cone beam computed tomography indicates a high information content of the technique and the possibility of increasing the efficiency, quality and optimization of the examination, surgical treatment based on the data obtained.

But under difficult anatomical conditions, large defects, implantation should be carried out with 3-D planning and using a surgical template made using rapid prototyping technology, the advantage of which is the high precision of the manufactured template (0.016 mm), as well as the complete absence of manual labor [Yudin P .S., Polyakov MK, Evaluation of the accuracy of surgical templates for the installation of dental implants using computer pre-surgical planning. Dental implantology and surgery No. 4 (17) 2014].

Directional bone tissue regeneration is indicated when bone width in the area of missing teeth is less than 5 mm. It must be remembered that with a residual bone width of 4-5 mm, simultaneous implantation can be performed, and sufficient primary stability of the implant can be achieved. With a residual width of 2-3 mm, it is necessary to carry out the operation without installing an implant, and return to this area after the formation of a sufficient bone mass.

The method consists in the fact that the patient undergoes cone beam computed tomography. After that, the dentist-surgeon plans an operation for the directed regeneration of bone tissue:

1. Determination of the number and specific installation site of dental implants, their diameter and length.

2. Depending on the width of the crest of the alveolar ridge and the volume of the existing bone, the height and width of the directed bone regeneration are planned.

3. Planning the use of regenerative material to fill the "bone defect", the choice of resorbable (collagen) membrane.

Planning for the installation of dental implants.

An orthopedic dentist and a dentist determine the placement of dental implants. Using cone beam computed tomography and the Simplant program, the monitor determines the diameter, length of the implants, as well as their location in the right places and in the right direction, according to a specially made surgical template, with guide bushings.

However, when carrying out this planning method, the dentist-surgeon does not have information about the volume of bone-substituting material necessary for the directed regeneration of bone tissue.

Disclosure of invention

The objective of the present invention is to determine the volume of bone substitute material when planning directional bone tissue regeneration.

The technical result of the invention is to reduce the time of the operation, reduce postoperative complications, reduce overspending of bone replacement material.

The specified technical result is achieved by the fact that the method for calculating the volume of bone-substituting material when planning an operation for the directed regeneration of bone tissue includes cone beam computed tomography, imprinting, production of models, scanning of manufactured models, obtaining their scans in .STL format, then cone beam data computed tomography in .DICOM format and model scans in .STL format are loaded into the Avantis 3D program, and according to the data obtained, a “grid” is constructed, and on the reference one the data are compared with cone beam tomography and scans (scene), with the further installation of implants in orthopedic positions, then a surgical template is made and the anatomical features of the alveolar ridge are used to model bone grafting and measure the exact volume of bone substitute material needed for targeted bone tissue regeneration.

Brief Description of the Drawings

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

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

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. Figure 4 shows the placement of implants in orthopedically advantageous positions, where 1 is a scan of the model of the lower jaw, 4 is a scan of the model of the upper jaw, 10 are implants.

In FIG. 5 shows horizontal bone deficit, where 2 is cone beam computed tomography of the lower jaw, 10 are implants.

In FIG. Figure 6 shows the volume of bone substitute material necessary for targeted regeneration of bone tissue, where 11 is the volume of bone substitute material, 10 are implants.

In FIG. 7 shows the volume of bone substituting material - 11, necessary for targeted regeneration of bone tissue, in a volume of 1 cm ³ .

In FIG. Figures 8-12 show photographs of the patient's lower jaw before, during, and after the operation.

The implementation of the invention

A method for planning targeted bone regeneration is as follows.

The patient undergoes cone beam computed tomography, obtaining data in .DICOM format.

An orthopedic dentist takes impressions, casts models, performs a wax-up Wax-up in the area of missing teeth. Models scan and receive model scans in .STL format. Further, the results of cone beam computed tomography and model scans 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 computed tomography data, a “grid” is constructed, and cone-beam computed tomography and scans are compared using 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.

Then, in this program, the virtual installation of implants is performed in orthopedic favorable positions and a surgical template is prepared. Orthopedic advantageous positions are called positions in which there will be the most long-term, predictable, aesthetic result.

The program visualizes how much the implant is immersed in bone tissue. Before planning the volume of bone substitute material, manipulations with the “mesh” are carried out: its cleaning and enlargement. After that, the volume of bone substitute material is modeled taking into account the anatomical features of the alveolar ridge and the volume of bone substitute material is measured. After such planning, the dentist, surgeon, has a complete picture of the upcoming operation and the volume of bone-substituting material necessary for the directed regeneration of bone tissue.

Implementation example.

Patient H., aged 50, came to us with complaints of loss of masticatory teeth in the lower jaw on the left. Loss of teeth occurred over 10 years of the patient's life due to complicated forms of caries and periodontitis.

On examination: in the lower jaw, the absence of teeth 3.5, 3.6, 3.7, the mucous membrane of the oral cavity is pale pink, moderately moistened, without pathological changes (see photo in Fig. 8).

When examining the alveolar ridge, atrophy of the alveolar ridge was revealed horizontally in the region of 3.5, 3.6 teeth, which corresponds to 3 degrees of atrophy, 1-2 mm wide (see photo in Fig. 9).

Diagnosis: Partial tooth loss, Atrophy of the alveolar ridge of the lower jaw 3 degrees.

The operation was performed under local anesthesia, an incision was made from the tooth zone 3.5 to the tooth zone 3.8. The mucoperiosteal flaps were peeled off, the bone defect was closed with an allocrosh in a volume of 1 cm3 (see photo in Fig. 10), the augmentation area was covered with a collagen membrane (see photo in Fig. 11), the mucoperiosteal flaps were put in place, monofilament seams.

The following were prescribed: antibiotics, non-steroidal anti-inflammatory drugs, oral baths with antiseptic solutions. In the postoperative period, moderate swelling of soft tissues, pain of moderate intensity for 3 days was noted. The patient felt satisfactory. Photo 12 shows a photo of the state of the gums 10 days after surgery.

The application of the method for calculating the volume of bone substitute material when planning directed regeneration of bone tissue allows us to determine, taking into account the anatomical features of the alveolar ridge, the volume of bone substitute material necessary for directed regeneration of bone tissue, reduce the time of surgery and postoperative complications, and get rid of overexpenditure of bone substitute material.

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 using the proposed method for calculating the volume of bone substitute material in surgical dentistry when planning the operation of directed regeneration of bone tissue, and therefore meets the patentability condition "Industrial Applicability".

Claims (1)

A method for calculating the volume of bone-substituting material when planning an operation for the directed regeneration of bone tissue, including conical beam computed tomography, imprinting, production of models, characterized in that the manufactured models are scanned, their scans are received in .STL format, then the cone beam computed tomography data in .DICOM format and model scans in .STL format are loaded into the Avantis 3D program, and according to the data obtained, a “grid” is constructed, and the cone-lu data are compared using reference points Eve tomography scans and with the further installation of orthopedic implants in favorable positions, then made surgical template and the anatomical features of the alveolar ridge model and measured kostnozameschayuschego exact volume of material required for targeting the regeneration of bone tissue.

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