RU2679557C1 - Dental treatment planning system and method - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: group of inventions relates to the field of medicine, namely to dentistry, and can be used for the dental treatment 3D planning and its subsequent implementation using digital 3D technologies. Proposed system comprises: patient individual data at least one storing device containing at least one of the dental rows scanning results, patient face and/or smile images, computer tomography (CT) or MRI, including the temporomandibular joints (TMJ), mandibular canals, upper and lower jaws bones, roots and the teeth coronal parts; at least one reference data storing device associated with age, sex, and/or anthropometric features, one or more computer programs loaded into at least one commands processing device, at that, one or more computer programs contain instructions for the data combination, obtained from the said patient data storage device and the reference data storage device for dental pathologies identification and for the patient data bringing to the norm, taking into account simulation movements, one-time mutually determined treatment stages virtual 3D planning, providing at least one treatment scenario for the corresponding dental pathology each treatment stage taking into account of the said simulated movements, at that, one of the treatment stages scenario change may, if necessary, lead to the corresponding change in the other treatment stages scenario, treatment stages simultaneous planning result three-dimensional modeling, recording information about the received scenarios of each stage of treatment for virtual modeling of at least one complex treatment plan based on the obtained planning result three-dimensional modeling and the corresponding dental pathology each of treatment stage all of the scenarios simultaneous analysis. Method includes: obtaining of the dentitions, face images and/or patient smiles scanning results, computer tomography (CT) or MRI, including temporomandibular joints (TMJ), mandibular canals, the upper jaw and the lower jaw bones, teeth roots and coronal parts, combined in the single coordinate space; obtained results correlation with the taken as a reference data, which are determined by the age, sex, and/or anthropometric features, and their coincidence simulation by the shape movement or changing, taking into account of the imitative functional movements, of treatment stages one-time mutually determined virtual 3D planning implementation, enabling at least one treatment scenario for the corresponding dental pathology each treatment stage, taking into account of the said imitation movements, at that, one of the treatment stages scenario change may, if necessary, lead to the corresponding change in the other treatment stages scenario, dental treatment stages simultaneous virtual planning result three-dimensional modeling, formation of at least one plan for complex treatment of the patient based on the obtained three-dimensional complex modeling and each treatment stage scenarios, and the formation, on the basis of computer three-dimensional modeling, of the patient's face and/or the smile three-dimensional image. Machine-readable data medium contains executed by one or more processors computer-readable instructions, which, during their execution, enable the method implementation.EFFECT: group of inventions provides for the acceleration of planning and, accordingly, the therapeutic measures implementation, under condition of increase in the treatment planning accuracy.26 cl, 2 ex, 19 dwg

Description

The group of inventions relates to medicine, namely to dentistry, and can be used for 3D planning of dental treatment and its subsequent implementation using digital 3D technology.

The use of digital planning and 3D technologies increases the effectiveness and quality of treatment, reduces the likelihood of errors.

The traditional complex dental treatment and its planning is phased - each subsequent stage is planned after the implementation of the previous stage of treatment. Thus, it is impossible to accurately predict the final results of treatment, and the treatment itself is quite long, since it is impossible to simultaneously perform several types of treatment.

Well-known analogues of digital planning provide, as a rule, effective planning of only one of the stages. At the end of each of the stages of treatment, it is necessary to repeat the collection of initial data corresponding to the current stage of treatment, rebuild the 3D scene, plan and carry out the next stage.

For example, if a patient has a dysfunction of the temporomandibular joints as a result of lowering the height of the occlusion and deformation of the dentition, then it is necessary to plan and conduct tire therapy of the temporomandibular joint (TMJ), then plan and correct the deformations of the dentition, and then to plan and eliminate defects of hard tissues of teeth (their attrition) in a reconstructive bite.

In the case of simultaneous (simultaneous) virtual 3D planning of several stages of treatment, the correction of one of the stages requires a complete alteration of the plans of all dependent stages of treatment.

The closest analogue of the technology we developed is the method of diagnosis and treatment planning (Unified Workstation for Virtual Craniofacial Diagnosis, Treatment Planning and Therapeutics, US 2007/0207437 A1), consisting of the following steps:

- obtaining different sets of patient data from various devices (2D and 3D light and X-ray scanning), reflecting craniofacial anatomical structures, including a visual representation of the face surface,

- combining these data in virtual space to obtain a virtual 3D model of the patient’s face and its visualization;

- visualization of a smile and its changes associated with a change in the position and shape of craniofacial structures and the position of the teeth.

Moreover, the well-known technical solution is aimed at creating an external image of the patient, his aesthetic appearance, in particular, the main criterion for evaluating all changes in the position of the teeth is a smile. While the quality of treatment provides not only an aesthetic result, but primarily a functional result. A well-known technical solution has the ability to plan a comprehensive treatment of a patient based on the created virtual model of a patient, however, a comprehensive treatment does not provide for the verification of each of the stages of treatment for suitability for the correct function. Moreover, the scenarios of smile formation do not automatically correlate with each other. To form a particular type of smile, one of the treatment scenarios is modified, after which a new end result is formed. The planning of different stages of treatment is independent of each other and not interdependent, which does not allow simulating a single treatment plan at the same time based on many interdependent treatment scenarios, as a result of which the probability of obtaining the result expected by the patient is reduced.

The technical problem that we are solving consists in one-stage (one-stage) planning of the final result and all intermediate stages of treatment in the amount of all necessary stages for its achievement.

The technical result achieved is to accelerate the planning and, accordingly, the implementation of therapeutic measures, provided that the accuracy of treatment planning is improved.

The difference between this group of inventions is the simultaneous planning of the final result and all intermediate stages of treatment. The ability to perform the correction of any of the intermediate stages allows either the correction of the final result or the correction of the plan of at least one of the dependent stages of treatment while maintaining the final result. In this case, the criterion for evaluating the treatment plan is both an aesthetic and functional result, which is ensured by the creation of a treatment plan (movement of LF, teeth, artificial teeth, etc.) taking into account the functional movements (articulation) of the lower jaw. For this, it is necessary to plan a reconstructive bite at a time, which would be given by a new spatial ratio of the jaw bones or their fragments, a new shape and position of the teeth. Moreover, the correction of any of the planned stages of planning leads to automatic correction of other stages dependent on it, and to recheck each of the stages of treatment for their suitability for the correct function by integration with a virtual articulator.

The achievement of these aspects of the technical result is due to the following:

- in creating at least one scenario of a treatment plan, which may include setting the position of the lower jaw, setting a new position of the tooth-alveolar fragments of the jaw, setting a new position of the teeth and the position of the implants, setting a new tooth shape;

- correction of one of the planning stages allows you to see the effect of this correction on other stages and the final result itself and decide on the admissibility of these changes or the need for automatic (or manual) correction of all dependent stages to keep the planned final result unchanged;

- correction of one of the stages does not lead to the need to re-plan all dependent stages, which reduces the planning time;

- “simultaneity” of planning will allow for simultaneous, and not just sequentially different types (stages) of dental treatment;

- the patient, even before the start of treatment, sees a possible end result, which should correspond to the physiological position of the lower jaw and occlusion, ensuring maximum chewing efficiency and optimal aesthetic result.

For an accurate understanding of the essence of the technology developed by us, a schematic comparative analysis of existing methods and the technology developed by us is presented below.

Currently, there are a variety of software products aimed at planning and implementing certain types of treatment, for example, for aligning teeth, navigation during implantation, and smile design. The advantage of their application is the high probability of achieving the planned result, the disadvantage is the impossibility of complex application. The use of 3D technologies in this case is the key to achieving the planned result, but planning itself is not much different from the traditional approach. The traditional planning scheme is based on the concept of sequential phased planning (Fig. 1a). However, this concept has a significant drawback - it is impossible to immediately simulate the end result of a multi-stage treatment and show it to the patient. Planning is carried out sequentially before each new stage of treatment, and the initial data for it are the achieved results of the previous stage. Moreover, each new stage is planned not by one, but by different specialists, and their idea of the final result may differ. Such planning is based on the assumption that these specialists have a general idea of the desired result and how to achieve it. With this approach, teamwork is very important. Lack of professionalism and competent planning at any stage can critically affect the overall result, there is a high probability of a gradual deviation at the stages from the ideal result. Theoretically, with such an approach, it would be possible to plan the final result, subject to an open data format and data transfer from one program to another. But in real practice, this is not feasible due to the closed data format of different programs, banal inconvenience and additional time losses. Equally important is the fact that the user must first learn all the features of different programs.

There are single software products that combine the necessary functionality on a single platform and in a convenient form allow you to implement the concept of sequential final planning (Fig. 1b). This concept is based on the sequential planning of the stages of treatment until the end result. This became possible due to the high probability of achieving the planned result using 3D technologies: the 3D-planned shape of artificial teeth is repeated with high accuracy in real products using CAD / CAM technologies, the planned position of the implants is set with high accuracy by guiding patterns, the planned alignment of teeth is also with high probability is achieved using 3D technology. The advantage of this concept is that not the result of treatment at the previous stage can be the basis for planning the next stage, but the result of planning the previous stage can be the basis for further planning. Thus, this concept contains elements of 4D modeling - virtual modeling sets not only the spatial position and shape of the objects of the oral cavity (3D), but also organizes these changes in time (4D). The main disadvantage of this approach is that if a mistake is made at the previous stage or a slight correction is required, then it is necessary to redo it and all subsequent stages (Fig. 1c). For example, the position of the central jaw ratio is virtually set, and then a script is created to align the teeth. It turns out that the occlusal relationship could become more optimal if you slightly adjust the position of the lower jaw. Or, for example, a script was created to align the teeth, then a new tooth shape was designed by importing artificial teeth from the data bank, and suddenly it turns out that a correction of the tooth movement is necessary, since the position of the artificial tooth and the final position of the abutment do not coincide, which will require excessive grinding teeth. And if the result expected by the patient differs from that created by us? Similar situations are very common when planning the outcome of a comprehensive dental treatment. Since virtual 3D planning requires a significant investment of time, this drawback becomes very significant and in real practice insurmountable.

In this regard, the full potential of such programs that have full functionality on a single platform is not fully utilized, and users perform traditional sequential phased planning. The only difference is that for this, it is not used several different ones, but only one program that has richer features, which, as noted above, is more convenient for the user.

We are proposing a new concept for 4D modeling. It is based not on phased, but on one-stage (simultaneous) final planning. Its peculiarity lies in the fact that all the functionality of clinical 3D modeling (positioning of the lower jaw / correction of the position of fragments of the jaw bones, alignment of teeth, placement of artificial teeth / modeling of their new shape, planning the position of implants) should be combined in a single unit and work in this way, that the planning of different stages of treatment is interdependent, carried out before the start of treatment itself at a time and in the amount of all necessary stages, with the possibility of changing individual stages, which automatically leads to the corresponding correction of all the others (Fig. 1d). It must be possible to create several alternative treatment plans. Moreover, for each given position of the central ratio, it should be possible to create several scenarios of tooth alignment, and for each alignment scenario, the creation of several smile design projects (artificial dentition).

The group of inventions includes a dental treatment planning system, a planning method, and a computer-readable storage medium comprising computer code implementing the method.

The object “Dental treatment planning system” includes:

at least one device for storing individual patient data containing at least one of the results of scanning the dentition, images of the patient’s face and / or smile, computed tomography (CT) or MRI, including temporomandibular joints (TMJ), mandibular canals, bones upper jaw and lower jaw, roots and coronal parts of teeth;

at least one device for storing reference data due to age, gender and / or anthropometric characteristics, one or more computer programs loaded into at least one command processing device, wherein one or more computer programs contain instructions for combining data, obtained from the said device for storing individual patient data and the device for storing reference data for identifying dental pathologies and for bringing patient data to normal, taking into account imitations ionic movements

one-time mutually stipulated virtual 3D planning of the treatment stages, providing at least one treatment scenario for each treatment stage of the corresponding dental pathology taking into account the mentioned imitative movements, while changing the scenario of one of the treatment stages can lead, if necessary, to a corresponding change in the scenario of the other stages of treatment,

three-dimensional modeling of the result of the simultaneous planning of the stages of treatment,

recording information about the received scenarios of each stage of treatment for virtual modeling of at least one comprehensive treatment plan based on the obtained three-dimensional modeling of the planning result and the simultaneous analysis of all scenarios of each stage of treatment of the corresponding dental pathology.

In particular cases, the "system" is implemented as follows:

- images of the face and / or smile of the patient can be selected from a 2D and / or 3D image;

- virtual 3D planning of the stages of treatment can be chosen from: modeling of gnatological treatment, modeling of orthognathic treatment, modeling of orthodontic treatment, modeling of orthopedic treatment, modeling of implantological treatment;

- a scenario for modeling gnatological treatment is determined by setting the position of the lower jaw relative to the reference position of the lower jaw;

- a scenario for modeling orthognathic treatment is determined by setting the position of the dentoalveolar fragments of the jaw relative to the reference position;

- a scenario for modeling orthodontic treatment is determined by setting the position of the teeth relative to the reference position;

- a scenario for modeling orthopedic treatment is determined by setting the shape of artificial teeth relative to the reference shape;

- the scenario for modeling implantological treatment is determined by setting the position of the implants.

The object "Dental treatment planning method" includes:

obtaining results of scanning dentitions, images of the patient's face and / or smile, computed tomography (CT) or MRI, including temporomandibular joints (TMJ), mandibular canals, bones of the upper jaw and lower jaw, roots and coronal parts of the teeth combined in a single coordinate space;

correlation of the obtained results with the data taken as reference, which are due to age, gender and / or anthropometric characteristics, and the simulation of their coincidence by moving or changing the shape, taking into account imitative functional movements,

the implementation of a one-time mutually stipulated virtual 3D planning of the stages of treatment, providing at least one treatment scenario for each stage of treatment of the corresponding dental pathology, taking into account the mentioned imitative movements, while changing the scenario of one of the stages of treatment can lead, if necessary, to a corresponding change in the scenario of other stages of treatment ,

three-dimensional modeling of the result of simultaneous virtual planning of the stages of dental treatment,

the formation of at least one comprehensive treatment plan for the patient based on the obtained three-dimensional integrated modeling and scenarios of each stage of treatment, and

the formation, on the basis of computer three-dimensional modeling, three-dimensional image of the face and / or smile of the patient.

In particular cases, the "method" is implemented as follows:

- design based on the compiled comprehensive dental treatment plan designs used at the stages of treatment;

model the stages of treatment selected from: gnatological treatment, orthognathic treatment, orthodontic treatment, orthopedic (prosthetic) treatment, implantological treatment;

- modeling of gnatological treatment includes the task of at least one position of the lower jaw;

- the position of the lower jaw is set based on the analysis of the ratio of the TMJ elements and the height of the bite;

- modeling of orthognathic treatment includes the selection and assignment of at least one new variant of the position of the fragments of the jaw bones or the tooth-alveolar complex;

- modeling of orthognathic treatment involves setting the position of the lower jaw (for example, habitual occlusion, a central ratio), and for each given position of the lower jaw, at least one scenario of the movement of fragments of the jaw bones or tooth-alveolar complex is formed;

- modeling of orthodontic treatment includes modeling of a reconstructive bite and the creation of at least one scenario of tooth alignment;

- modeling of alignment of teeth includes setting the position of the lower jaw, setting the position of the tooth-alveolar complex, and for each given position at least one scenario of alignment of the teeth is formed;

- modeling of orthopedic (prosthetic) treatment includes at least one project of the position and shape of artificial teeth;

- modeling the position and shape of artificial teeth includes setting the position of the lower jaw, setting the position of the tooth-alveolar complex, setting the final position of the alignment of the teeth, with at least one project of the position and shape of the artificial teeth being formed for each position;

- modeling the shape and position of artificial teeth includes importing from the storage device the reference data of a three-dimensional tooth model, installing it in the jaw model in relation to the necks of natural teeth or in the calculated position in the case of an adentia and modifying its shape;

- modeling of implantological treatment includes setting at least one new variant of the position of the implant or implants;

- modeling the position of the implants includes setting the position of the lower jaw, setting the position of the tooth-alveolar complex, setting the final position of the alignment of the teeth, setting the position of the artificial teeth, and at least one project of the position of the implants is formed for each given position;

- modeling the position of the implant includes importing the implant reference data from the storage device, installing it in a virtual model of the jaw, while modeling the position and size of the implants includes an analysis of the position of artificial teeth, bone volume, the position of the roots of adjacent natural teeth and the mandibular canal;

- at least one comprehensive treatment plan contains data about at least one predetermined position of the lower jaw, the coordinates of the transfer of fragments of the jaw bone, the script alignment of teeth, the shape and position of artificial teeth and implants;

- the stages of treatment are planned taking into account the possible functional movements of the lower jaw.

Another object of patenting is a computer-readable storage medium containing machine-readable instructions executed by one or more processors, which, when executed, implement the dental planning method described above.

The materials of this invention use "terms and definitions", which have the following interpretation:

- reference data - anatomical or physiological parameters corresponding to the tender, age norm and / or anthropometric characteristics of the patient;

- simulation movements - virtual movements of 3D objects corresponding to possible movements of their real prototypes during a function or at the treatment stages;

- treatment scenario - a treatment plan that includes a complete list of types (stages) of treatment associated with a change in the position or shape of the elements of the dentofacial system, their parts and / or their artificial prototypes. The actual exclusion of one or more types (stages) of treatment (gnatological, orthognathic, orthodontic, orthopedic (prosthetic), implantological) from the general complex of planned therapeutic measures is considered as one of the virtual treatment options with a zero result;

- modeling of gnatological treatment - setting the medical position of the lower jaw, the central ratio or another position of the reconstructive bite;

- modeling of orthognathic treatment - planning the separation of jaw fragments and their movement in order to set a reconstructive bite and change the contour of the soft tissues of the face;

- modeling of orthodontic treatment - planning a scenario for aligning teeth (setting a new final position of the teeth, the sequence and speed of their movement);

- modeling of orthopedic treatment - planning the position and shape of artificial teeth, the level and shape of the gingival margin;

- modeling of implantological treatment - planning of the position and size of implants, augmentation (building) of bone tissue;

- dependent stage of treatment planning - if the content of another stage directly or indirectly affects the content of the planned stage of treatment, then this stage is considered dependent. For example, a change in the position of the lower jaw affects the start and end points of the alignment path of the teeth, the position, size and shape of the artificial teeth, and the position of the implants in the virtual space. Changes in the position of implants during planning do not affect any of the other planned stages of treatment.

Example 1

Patient M., complaints of abrasion, crowded teeth, decreased bite height, pain in the temporomandibular joint (Fig. 2). When analyzing a three-dimensional scene, it was found that as a result of tooth abrasion, the LF heads displaced distally in the articular fossae (TMJ cross sections are shown in the upper part of Fig. 2), which led to compression of the bilaminar zone and pain. At the bottom of FIG. 2 shows the ratio of incisors on the left, the cutting edge of the lower incisor is worn. 2 on the right shows a general 3D scene.

A treatment plan was created, which consisted in virtual setting the position of the central ratio (displacement of the LF forward and down, hinged opening of the LF with an increase in the interalveolar distance) (Fig. 3). A virtual alignment of the teeth was carried out, which consisted in moving the tooth with the help of the manipulator to a new position (Fig. 4). The lateral sections of the upper and lower dentitions were expanded, the lateral teeth of the LF were distalized, and the tortoanomalies of the anterior teeth of the HF and LF were corrected (Fig. 5).

Further, in the corrected position of the teeth, their new shape was planned, which compensated for the lost height (Fig. 6). A new shape of the teeth sets the bite, which ensures a comfortable position of the heads of the lower jaw in the space of the articular fossae of the TMJ (Fig. 7).

At the end of the complex modeling of the new occlusion (Fig. 8), it was decided to slightly change the position of the LF, giving it an even more mesial position. This led to a change in the nature of the closure of virtual artificial teeth (Fig. 9).

To optimize the occlusion of artificial teeth in the new position of the lower jaw, it was enough to carry out a correction of the alignment of teeth scenario, which again led to the restoration of occlusal contacts (Fig. 10).

Thus, 2 different scenarios of the treatment plan were created (indicated by an arrow in Fig. 11), which differ in different positions of the LF, different scenarios of tooth alignment, but maintaining the same correct interocclusal ratio and the shape of artificial virtual teeth.

When implementing the proposed method of correction of the treatment plan scenario, it was not necessary to redo the teeth alignment scenario and re-arrange the artificial teeth. When changing the position of the bass, it was enough to just slightly adjust the final position of the teeth. In the traditional approach, it would be necessary to re-create the scenario of tooth movement, since the initial position of the teeth has changed, which means that the final position of the artificial teeth will be corrected again. In our method, all corrections are mutually connected and are carried out automatically by a computer program.

The total time for creating a virtual treatment plan was 2 hours. With the virtual correction of this plan in the traditional way, 1.5 hours of time is required. Using our approach, the time spent was 15 minutes. The ability to create several alternative treatment plans enables a more accurate and comprehensive analysis and selection of the best. Reducing time and simplifying computer simulation greatly facilitates this work and ensures the achievement of an optimal result with less effort.

Example 2

Patient L., has a dentition defect in the area of the 46 tooth, deformation of the dentition in the form of tooth extension 16 and the tooth tilts 47 to the side of the defect, the defect of the crown part of the 47 tooth and needs implantation in the region of 46, replacing the dentition defect with the artificial 46 tooth, restoration of the crown part 47 of the tooth (Fig. 12).

Created a treatment plan (Fig. 13), which consists in correcting the position of the teeth - intrusion of the 16 tooth, eliminating the inclination (uprating) of 47 and 48 teeth; staging of artificial teeth 47 and 46 and planning the position of the implant in the projection of the 46 tooth.

After the virtual correction of the position of the 47th, 48th and 16th teeth, a space appeared to be placed in proportion to the full 46th tooth. Virtual placement of the implant provides the output of the fixing screw to the middle of the crown part of the artificial 46 tooth (Fig. 14).

In FIG. 15, in translucent mode, artificial 47 and 46 teeth are shown, set in accordance with the final position of the patient's aligned natural teeth. In FIG. 16 in translucent mode shows artificial 47 and 46 teeth, set in accordance with the initial position of the patient’s natural teeth.

Such planning allows simultaneous implantation and orthodontic treatment, during which the implant will fully take root and will be able to withstand full chewing load, that is, it will be possible to make permanent dentures. Moreover, the implant installed at the very beginning of treatment after the end of orthodontic treatment will be in the correct position for the prosthetics.

This approach has reduced the total dental treatment time for this patient by half.

Claims (38)

1. Dental treatment planning system, including: at least one device for storing individual patient data containing at least one of the results of scanning the dentition, images of the patient’s face and / or smile, computed tomography (CT) or MRI, including temporomandibular joints (TMJ), mandibular canals, bones upper jaw and lower jaw, roots and coronal parts of teeth; at least one reference data storage device due to age, gender and / or anthropometric characteristics, one or more computer programs loaded into at least one command processing device, wherein one or more computer programs contain instructions for combining data obtained from said patient individual data storage device and reference data storage device for detecting dental pathologies and for bringing data the patient to normal, taking into account imitative movements, one-time mutually stipulated virtual 3D planning of the treatment stages, providing at least one treatment scenario for each treatment stage of the corresponding dental pathology taking into account the mentioned imitative movements, while changing the scenario of one of the treatment stages can lead, if necessary, to a corresponding change in the scenario of the other stages of treatment, three-dimensional modeling of the result of the simultaneous planning of the stages of treatment, recording information about the received scenarios of each stage of treatment for virtual modeling of at least one comprehensive treatment plan based on the obtained three-dimensional modeling of the planning result and the simultaneous analysis of all scenarios of each stage of treatment of the corresponding dental pathology. 2. The system according to claim 1, in which the image of the face and / or smile of the patient can be selected from a 2D and / or 3D image. 3. The system of claim 1, wherein the virtual 3D planning of the treatment steps can be selected from: modeling of gnatological treatment, modeling of orthognathic treatment, modeling of orthodontic treatment, modeling of orthopedic treatment, modeling of implant treatment. 4. The system of claim 3, wherein the scenario for modeling gnatological treatment is determined by setting the position of the lower jaw relative to the reference position of the lower jaw. 5. The system according to claim 3, in which the scenario for modeling orthognathic treatment is determined by setting the position of the dentoalveolar fragments of the jaw relative to the reference position. 6. The system according to claim 3, in which the scenario for modeling orthodontic treatment is determined by setting the position of the teeth relative to the reference position. 7. The system according to claim 3, in which the scenario for modeling orthopedic treatment is determined by setting the shape of artificial teeth relative to the reference form. 8. The system according to claim 3, in which the scenario for modeling implantological treatment is determined by setting the position of the implants. 9. A method for planning dental treatment, including: obtaining results of scanning dentitions, images of the patient's face and / or smile, computed tomography (CT) or MRI, including temporomandibular joints (TMJ), mandibular canals, bones of the upper jaw and lower jaw, roots and coronal parts of the teeth combined in a single coordinate space; correlation of the obtained results with the data taken as reference, which are due to age, gender and / or anthropometric characteristics, and the simulation of their coincidence by moving or changing the shape, taking into account imitative functional movements, the implementation of a one-time mutually stipulated virtual 3D planning of the stages of treatment, providing at least one treatment scenario for each stage of treatment of the corresponding dental pathology, taking into account the mentioned imitative movements, while changing the scenario of one of the stages of treatment can lead, if necessary, to a corresponding change in the scenario of other stages of treatment , three-dimensional modeling of the result of simultaneous virtual planning of the stages of dental treatment, the formation of at least one comprehensive treatment plan for the patient based on the obtained three-dimensional integrated modeling and scenarios of each stage of treatment, and the formation, on the basis of computer three-dimensional modeling, three-dimensional image of the face and / or smile of the patient. 10. The method according to p. 9, in which the designs used at the treatment stages are designed on the basis of a comprehensive dental treatment plan. 11. The method according to p. 9, in which the stages of treatment are selected, selected from: gnatological treatment, orthognathic treatment, orthodontic treatment, orthopedic (prosthetic) treatment, implantological treatment. 12. The method according to p. 11, in which the modeling of the gnatological treatment includes setting at least one position of the lower jaw. 13. The method according to p. 12, in which the position of the lower jaw is set based on the analysis of the ratio of TMJ elements and the height of the bite. 14. The method according to p. 11, in which the modeling of orthognathic treatment includes the selection and assignment of at least one new version of the position of the fragments of the jaw bones or dentoalveolar complex. 15. The method according to p. 14, in which the modeling of orthognathic treatment involves setting the position of the lower jaw (for example, the usual occlusion, central ratio), and for each given position of the lower jaw, at least one scenario of the movement of fragments of the jaw bones or dentoalveolar complex is formed. 16. The method according to p. 11, in which the modeling of orthodontic treatment includes modeling a reconstructive bite and creating at least one scenario of alignment of the teeth. 17. The method according to p. 16, in which modeling the alignment of the teeth includes setting the position of the lower jaw, setting the position of the dentoalveolar complex, and for each given position at least one scenario of alignment of the teeth is formed. 18. The method according to p. 11, in which the modeling of orthopedic treatment includes at least one project of the position and shape of artificial teeth. 19. The method according to p. 18, in which the modeling of the position and shape of the artificial teeth includes setting the position of the lower jaw, setting the position of the dentoalveolar complex, setting the final position of the alignment of the teeth, at least one project of the position and shape of the artificial teeth is formed for each position teeth. 20. The method according to p. 18, in which modeling the shape and position of artificial teeth includes importing from the storage device the reference data of a three-dimensional tooth model, installing it in the jaw model in relation to the necks of natural teeth or in the calculated position in case of adentia and modifying it forms. 21. The method according to p. 11, in which the modeling of implantological treatment includes setting at least one new variant of the position of the implant or implants. 22. The method according to p. 21, in which the simulation of the position of the implants includes setting the position of the lower jaw, setting the position of the dentoalveolar complex, setting the final position of the alignment of the teeth, setting the position of the artificial teeth, at least one project of the position of the implants is formed for each position . 23. The method according to p. 21, in which the simulation of the position of the implant includes importing from the storage device the reference data of the implant, installing it in a virtual model of the jaw, while modeling the position and size of the implants includes an analysis of the position of artificial teeth, bone volume, position the roots of adjacent natural teeth and the mandibular canal. 24. The method according to p. 9, in which at least one comprehensive treatment plan contains data about at least one predetermined position of the lower jaw, coordinates of the transfer of fragments of the jaw bone, scenarios of tooth alignment, shape and position of artificial teeth and implants. 25. The method according to p. 11, in which the stages of treatment are planned taking into account the possible functional movements of the lower jaw. 26. A computer-readable storage medium containing machine-readable instructions executed by one or more processors, which, when executed, implement a method for planning a dental treatment according to any one of paragraphs. 9-25.

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