KR102330488B1 - A method for diagnosis information service for teeth orthodontics - Google Patents

Abstract

The method of providing diagnostic information for orthodontic treatment according to the present invention comprises the steps of stacking tomography data collected from imaging equipment to complete a three-dimensional skull shape (S01); A step of selecting each view from the direction of the dog (S02), a step of selecting any one in the case of viewing only the bones of the three-dimensional skull shape, viewing the bones and skin at the same time, and viewing as a translucent image through X-rays ( S03), adjusting the transparency of the three-dimensional skull shape (S04). and a step (S05) of selectively displaying an arbitrary cross-section according to the three-axis directions of X, Y, and Z orthogonal to the three-dimensional skull shape. In the method of providing diagnostic information for orthodontic treatment according to the present invention, a screen is divided into four, and three screens of them are located on the left side and display respective cross-sectional images along the three axis directions of X, Y, and Z, , while the other screen is located on the right side and three-dimensionally displays the cross-sectional images appearing on the three screens along the three axis directions of X, Y, and Z, each axis is displayed on the three split screens located on the left side of the screen. As a means of solving the problem, an image displayed three-dimensionally on the right screen is displayed in conjunction with the image of the corresponding cross-section of the moved axis as it is moved.

Description

A method for providing diagnostic information for orthodontics {A method for diagnosis information service for teeth orthodontics}

The present invention relates to a dental orthodontic program capable of accurately grasping a patient's dental condition prior to orthodontic treatment and simulating the post-orthodontic condition in advance to determine the post-orthodontic condition in advance in orthodontic treatment.

More specifically, in performing orthodontic treatment of a target patient, a detailed and accurate diagnosis of the target patient is preceded, a customized treatment plan is established accordingly, and then a specific treatment plan is established so that accurate orthodontic treatment can be achieved. It relates to a method of providing diagnostic information for orthodontic treatment

A condition in which the dentition is not correct and the upper and lower teeth occlusion is abnormal is called malocclusion, and such malocclusion not only causes functional problems such as mastication and pronunciation problems and aesthetic problems on the face, but also causes health problems such as tooth decay and gum disease. It can also cause problems. The cause of these uneven dental conditions or malocclusion (the state of the teeth not biting together) or facial protrusion is the growth of the teeth itself, the growth of the jawbone, bad habits such as sucking fingers in childhood, bad eating habits, or heredity. This is due to the fact that the teeth and oral and maxillofacial areas cannot grow properly in place due to the back. Such unevenness of teeth, malocclusion, or protruding facial hair not only causes passive responses to interpersonal relationships, but also degrades the uniform grinding function of food, which is the basic function of teeth.

Therefore, in order to solve such a problem, orthodontic treatment in which continuous force is applied to the teeth to forcibly induce the movement of the teeth together with the remodeling of the alveolar bone surrounding the teeth is becoming common.

1 shows an example of a conventional dental brace 200 commonly known as a bracket. However, the bracket that is the brace 200 of FIG. 1 is in the form of a labial bracket exposed to the outside. Conversely, a bracket that is not exposed to the outside is called a lingual bracket. Among these labial or lingual brackets, it is common to use a labial bracket in consideration of efficiency rather than aesthetics in cases of severe asymmetry or children having difficulty in oral care.

On the other hand, in the early days, metal brackets were mainly used, but in recent years, there is a trend to mainly use brackets made of ceramic or resin, which provide an aesthetic effect.

In addition, in the bracket body 210 attached to the teeth in the bracket, which is the conventional dental brace 200 shown in FIG. 1, the orthodontic wire 220 connected between the teeth is intermittently inserted into the slot (slot) 212. This is formed, and a tie wing 240 to which a binder member 230 such as a fastening band for holding the straightening wire 220 to the bracket body 210 is fastened is provided. The slot 212 is formed between the wings 240 or is concavely formed in the bracket body 210 itself, as shown in FIG. 1 , and the tooth attachment surface of the bracket body 210 is curved.

Looking at the operation state using the braces 200 of the conventional brackets, the bracket body 210 is attached to the teeth to be corrected, for example, canines, etc. with an adhesive. Then, after inserting the orthodontic wire 220 into the bracket slot 212, the binder member 230, for example, a band, wire, or the like, is fastened in the form of combining a pair of wings 240 to bracket the orthodontic wire. fixed to the body. At this time, although not shown in a separate drawing, there is another form of covering and fixing the orthodontic wire 220 fitted in the slot on the body by integrally forming the cover member on the slot instead of the wing.

Traditionally, orthodontic treatment uses brackets for fine and precise movement of teeth. A bracket is a device that is attached to the teeth and transmits the orthodontic force of a rubber band or wire to the teeth. The doctor adheres the bracket to a certain position among the clinical crowns of the tooth using an oral mirror, a bracket positioner, etc. According to this direct adhesion technique, the visual environment in the oral cavity is limited, and many errors occur in bracket adhesion depending on the clinician's experience or vision, or the position of the bracket positioner. In order to correct the error of bracket adhesion, orthodontists reattach the bracket at the beginning of orthodontic treatment or bend the orthodontic wire at the end of treatment to solve it.

Before performing such orthodontic treatment, in order to determine a suitable treatment method, it is preferable to perform simulation of the expected tooth shape during orthodontic treatment together with the current patient's tooth condition. As such a simulation method, an orthodontic method (Patent Publication No. 2016-0140326) for automatically moving a tooth object, the inventor of the present applicant, has been disclosed. However, in this case, there was no comprehensive consideration of the location or method of attachment of the bracket, which is a very important factor in orthodontic treatment, and the direction and degree of inclination with respect to the root of the tooth, which is the purpose of orthodontic treatment.

On the other hand, the direct bonding of the bracket as described above is difficult for beginners in orthodontics, and it is not easy for even an expert to consistently adhere the bracket to the teeth. Accordingly, the inventor of the present invention has completed the present invention after a long period of research and effort on a device that can effectively help the orthodontist's direct bonding technique.

The imaging device is a device that generates a 3D image of a patient's teeth and facial bone structure using three-dimensional digital imaging. For example, a 3D oral scanner or CBCT (Cone Beam Computerized Tomography: Cone Beam CT), 3D model scanner, MRI, It may be composed of PET (Poisitron emission tomography; positron tomography) or the like. When the incident light irradiated into the oral cavity is reflected on the teeth or the subject, the 3D intraoral scanner senses the reflected light to create a 3D image of the entire shape of the subject in the oral cavity. CBCT uses an area detector to two-dimensionally detect a cone-shaped transmitted X-ray, and uses it to acquire three-dimensional volume information, thereby generating a 3D image with only one rotational scan of a subject in the oral cavity. The 3D image by the 3D oral scanner has the advantage of accurately expressing the surface shape of the subject (teeth, gums, etc.), and the 3D image by CBCT has the advantage of accurately expressing not only the crown information of the teeth but also the alveolar bone and root information.

A method for providing diagnostic information for orthodontic treatment according to the present invention has a technical task to enable a detailed and accurate diagnosis of a target patient's dental condition prior to performing orthodontic treatment of a patient.

The method of providing diagnostic information for orthodontic treatment according to the present invention is a technical task of enabling accurate orthodontic treatment by establishing a customized treatment plan according to a patient's dental condition in detail.

According to the method of providing diagnostic information for orthodontic treatment according to the present invention, a virtual set-up is performed according to a diagnosis made by a corresponding doctor directly using data, so that it is possible to grasp the appearance of a patient before and after orthodontic treatment in advance It is the technical task to make it happen.

The method of providing diagnostic information for orthodontic treatment according to the present invention has its technical task to enable the provision of a more precise and suitable orthodontic device for a patient by accurately reflecting the diagnosis and opinion of the doctor in the manufacturing process of the orthodontic device. do.

The method of providing diagnostic information for orthodontic treatment according to the present invention has a technical task of enabling more accurate orthodontic treatment by considering even root movement occurring in the orthodontic process.

The method of providing diagnostic information for orthodontic treatment according to the present invention has been devised to solve the above problems,

Completing a three-dimensional skull shape by stacking tomography data collected from imaging equipment (S01), a step of selecting the three-dimensional skull shape viewed from the front, back, left and right, and up and down six directions (S02); A step of selecting any one in the case of viewing only the bones of the 3D skull shape, the case of viewing the bones and the skin at the same time, and the case of viewing as a translucent image through X-rays (S03), and adjusting the transparency of the 3D skull shape (S04) ). A step (S05) of selectively displaying an arbitrary section along the three-axis directions of X, Y, and Z orthogonal to the three-dimensional skull shape, specifying a certain section in the vertical direction in the three-dimensional skull shape, To include the step (S06) of displaying the shape as a horizontal panorama is taken as a means of solving the problem.

In addition, the method of providing diagnostic information for orthodontic treatment according to the present invention,

The screen is divided into four, and three screens of them are located on the left side and display respective cross-sectional images along the three axis directions of X, Y, and Z, and the other screen is located on the right side and is located on the three screens. Each cross-sectional image that appears is displayed three-dimensionally along the three axis directions of X, Y, and Z, while moving each axis in three split screens located on the left side of the screen. As a means of solving the problem, the image displayed three-dimensionally on the right screen is displayed in conjunction with each other.

In addition, the method of providing diagnostic information for orthodontic treatment according to the present invention,

A step of marking several points determined to be anatomically significant on the three-dimensional skull shape (S07), among the marked points, by analyzing the correlation made up of the relative distance and direction between each point, the patient's anatomical skull Further comprising the step (S08) of grasping the shape of the problem is to be solved.

The method of providing diagnostic information for orthodontic treatment according to the present invention enables a detailed and accurate diagnosis of a patient's dental condition prior to performing orthodontic treatment of a target patient, thereby providing customized treatment according to the patient's dental condition By establishing a plan in detail, it has the effect of increasing the accuracy of orthodontic treatment by allowing accurate orthodontic treatment to be made.

In addition, in the method of providing diagnostic information for orthodontic treatment according to the present invention, a virtual set-up is performed according to a diagnosis made by a corresponding doctor directly using data, and movement and rotation of teeth according to the simulated correction are performed. By enabling the prediction of the position change, it is possible to grasp the appearance before and after orthodontic treatment of the target patient in advance, thereby increasing the predictability according to the treatment.

In addition, the method of providing diagnostic information for orthodontic treatment according to the present invention is more precise and suitable for the patient by allowing the diagnosis and opinion of the doctor to be accurately reflected in the manufacturing process of the orthodontic preliminary device and the orthodontic device. By making it possible to provide, it has the effect of reducing the occurrence of defects due to device manufacturing.

The method of providing diagnostic information for orthodontics according to the present invention utilizes not only crown (appearance of teeth) information but also root information obtained from imaging equipment such as CBCT, MRI, and PET (Poisitron emission tomography; positron emission tomography). This has the effect of increasing the accuracy and convenience of orthodontic treatment by reducing errors due to orthodontic treatment in consideration of root movement occurring during the orthodontic process and enabling more accurate orthodontic treatment.

1 shows an example of a bracket (bracket) corresponding to the conventional dental braces in FIG.
2 is an image of a case in which only a bone is viewed in a three-dimensional skull shape and a case in which a bone and skin are viewed at the same time.
Figure 3 shows an image according to the control of the transparency of the three-dimensional skull shape.
In Figure 4, each cross-sectional image along the three axes of X, Y, and Z is located on the left side of the three screens, and the screen displayed three-dimensionally along the three axis directions of X, Y, and Z is located on the right it shows that
Figure 5 is a three-dimensional skull shape by designating a certain section in the vertical direction, the shape of the designated section is displayed in a horizontal panorama.
6 is an image screen of a step of identifying the shape of the anatomical skull of the patient by analyzing the correlation between points in the three-dimensional skull shape.
7 is a screen on which the three-dimensional skull shape before orthodontic and the three-dimensional skull shape after correction are displayed overlapping with respect to the same center.
8 is a screen in which a multi-plane display screen composed of three-axis planes of X, Y, and Z and a screen displayed three-dimensionally along the three-axis directions of X, Y, and Z are simultaneously shown for the shape of the skull before and after the overlapped correction. am.
9 is a screen at a specific point in time with respect to a state in which teeth move from a position before orthodontic treatment to a position after orthodontic treatment.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention belongs It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

Examples of the method of providing diagnostic information for orthodontics for digital orthodontics according to the present invention can be applied in various ways. Hereinafter, the most preferred embodiment will be described with reference to the accompanying drawings.

Hereinafter, in describing the present invention, a popular medical program may include software that analyzes and processes a computed tomography (CT) image to perform simulation treatment, etc., and the design application program is computer aided (CAD) design, or computer aided manufacturing (CAM) software. In addition, the files processed by the medical program and the CAD/CAM program may include files provided in the form of STL (Stereolithography, 3D image).

In addition, the configuration and specific data processing method required for the present invention, including a CT imaging device, MRI, PET (Poisitron emission tomography), and CAD/CAM program execution device, can be variously modified according to the needs of those skilled in the art, so the present invention It goes without saying that this is not specified. In addition, in the present invention, for convenience of explanation, a subject performing data analysis and processing may be described as a program, but the present invention is not limited thereto, and it can be understood that the description is based on a device executing the program as the subject.

2 is an image of a case where only a bone is viewed in a three-dimensional skull shape and a case where a bone and skin are viewed simultaneously. Figure 3 shows an image according to the control of the transparency of the three-dimensional skull shape. In Figure 4, each cross-sectional image along the three axis directions of X, Y, and Z is located on the left side of the three screens, and the screen displayed three-dimensionally along the three axis directions of X, Y, and Z is located on the right side it shows that

Step S01 is a step of stacking tomography data collected from imaging equipment to complete a three-dimensional skull shape. Cranial tomography image data (DICOMseries) can be obtained from imaging equipment such as MRI and Ultrasonic diagnostics in addition to the CBCT scanning method. This is possible in a variety of ways. A three-dimensional tooth shape model is also collected/generated by the same method as above.

The skull tomography image data (DICOMseries) collected in this way is stacked and combined to complete a three-dimensional skull volume. It is used to create 3D Face Models, etc.

Step S02 is a step in which the three-dimensional skull shape can be selected as viewed from the front, back, left, right, and up and down six directions, respectively. The three-dimensional skull shape can be viewed from the front and rear, left and right, and up and down six directions by the user's selection button.

Step S03 is a step in which any one of the three-dimensional skull shape can be selected when only bones are viewed, when bones and skin are viewed at the same time, and when viewed as a translucent image through X-rays. The 3D skull shape provides a variety of screens, such as when only bones are viewed, when bones and skin are viewed at the same time, or when viewed as a translucent image through X-rays, and the doctor can selectively view images according to their needs.

In addition, in step S04, it is possible to adjust the transparency of the three-dimensional skull shape and skin. Therefore, even if the bones and skin are overlapped and displayed at the same time, it is possible to diagnose the positions of the skull and teeth by adjusting the transparency.

In Figure 4, each cross-sectional image along the three axis directions of X, Y, and Z is located on the left side of the three screens, and the screen displayed three-dimensionally along the three axis directions of X, Y, and Z is located on the right side it shows that

Step S05 is a step in which an arbitrary cross-section is selectively displayed along the three-axis directions of X, Y, and Z orthogonal to the three-dimensional skull shape. In the three-dimensional skull shape, an arbitrary cross-section is selectively displayed along the three axis directions of X, Y, and Z orthogonal to each other, and each cross-sectional image along the three axis directions of X, Y, and Z is a coronal plane, respectively. ), sagittal plane, and transverse plane, the coronal plane is an imaginary plane that divides the human body into front and back, the sagittal plane is an imaginary plane that divides the human body into left and right, and the horizontal plane is a horizontal plane that divides the human body up and down It is a divided virtual side.

In this case, the screen is divided into four, and among them, three screens are located on the left side and display respective cross-sectional images along the three axis directions of X, Y, and Z, and the other screen is located on the right while the three screens are located on the right side. Each cross-sectional image appearing on the screen is displayed three-dimensionally by combining it according to the three-axis directions of X, Y, and Z.

In other words, a two-dimensional flat image is shown on the left three-split screen, and a three-dimensional stereoscopic image is shown on the right.

On the other hand, as each axis is moved on the three split screens located on the left side of the screen, the image displayed three-dimensionally on the right screen is displayed in association with the image for the corresponding section of the moved axis.

Specifically, in any one of the split screens on the left, if you move the mouse while placing the mouse on any axis and clicking on it, the axis moves, and the cross-sectional image corresponding to the moved axis is also linked to the three-dimensional skull shape on the right. it will be shown

Figure 5 is a three-dimensional skull shape by designating a certain section in the vertical direction, the shape of the designated section is displayed in a horizontal panorama.

It is also possible to designate a certain section in the vertical direction in the three-dimensional skull shape and display the shape for the designated section as a transverse panorama (step S06).

The three-dimensional skull shape is a three-dimensional image, and it is necessary to view it flat in order to more accurately grasp the positional relationship between the teeth. It allows the doctor to more easily understand the degree of inclination, etc. Furthermore, the transverse panorama is characterized in that it is a three-dimensional shape that can be rotated in the transverse and longitudinal directions.

6 is an image screen of a step of identifying the shape of the anatomical skull of the patient by analyzing the correlation between points in the three-dimensional skull shape.

Steps (S07) and (S08) are steps of analyzing the shape of the skull through careful anatomical examination. Through this, more accurate orthodontic conclusions can be drawn.

The doctor selects several points determined to be anatomically significant in the shape of the skull, and marks the selected points on the three-dimensional skull shape. The doctor understands the anatomical shape of the skull of the patient by analyzing the correlation such as the relative distance and direction between the marked points.

7 is a screen in which the three-dimensional skull shape before and after correction is displayed overlapped with respect to the same center, and FIG. It is a screen in which a multi-flat display screen composed of

Step S09 is a step of calling each image for two three-dimensional skull shapes to be overlapped. By applying the same center of volume to the shape of the skull before and after orthodontic treatment, the two images are superimposed, and the difference is compared with each other, so it is possible to easily check the degree of change in the position of the teeth before and after orthodontic treatment and the change in the length of the temporomandibular joint. do.

It is possible to superimpose two images by applying the same center of volume to the skull shape before and after correction, and to determine the transparency of the three-dimensional skull shape before and after correction. By adjusting the transparency of each, it is possible to more easily and selectively view each image.

In addition, it is possible to separately determine the color of the three-dimensional skull shape before and after correction, so that it is possible to clearly distinguish the two images and to understand the difference more easily.

Furthermore, the two overlapping images are provided as a multi-plane display composed of three-axis planes of X, Y, and Z, and the multi-plane display is changed according to the movement of each plane along the three axes. do.

In the three-dimensional skull shape, an arbitrary cross-section is selectively displayed along the three axis directions of X, Y, and Z orthogonal to each other, and each cross-sectional image along the three axis directions of X, Y, and Z is a coronal plane, respectively. ), sagittal plane, and transverse plane, the coronal plane is an imaginary plane that divides the human body into front and back, the sagittal plane is an imaginary plane that divides the human body into left and right, and the horizontal plane is a horizontal plane that divides the human body up and down It is a divided virtual side.

In this case, the screen is divided into four, and among them, three screens are located on the left side and display respective cross-sectional images along the three axis directions of X, Y, and Z, and the other screen is located on the right while the three screens are located on the right side. Each cross-sectional image appearing on the screen is displayed three-dimensionally by combining it according to the three-axis directions of X, Y, and Z.

In other words, a two-dimensional flat image is shown on the left three-split screen, and a three-dimensional stereoscopic image is shown on the right. On the other hand, as each axis is moved on the three split screens located on the left side of the screen, the image displayed three-dimensionally on the right screen is displayed in association with the image for the corresponding section of the moved axis.

Specifically, in any one of the split screens on the left, if you move the mouse while placing the mouse on any axis and clicking on it, the axis moves, and the cross-sectional image corresponding to the moved axis is also linked to the three-dimensional skull shape on the right. it will be shown

9 is a screen at a specific point in time with respect to a state in which teeth move from a position before orthodontic to a position after orthodontic treatment. Step S10 is a step of storing all the teeth when the orthodontic positions are designated, and dynamically showing how all teeth move from the pre-orthodontic position to the post-orthodontic position. Step (S10) is a step in which the crown images for all teeth are arranged according to the dentition with respect to the crown image of the teeth and the changed appearance is shown. It is also possible to simultaneously display the pre-correction and post-correction images of the patient's face selectively or through a split screen. The method of dynamically showing the movement from the pre-correction position to the post-correction position is: First, there is a method of continuously showing the image from the first image before correction to the final image after correction with one click. There is a method of showing changes according to the set time by step (for example, '2 weeks' is set).

Bracket: 200

Claims (11)

Calling each image for two three-dimensional skull shapes to be superimposed (S09);
Determining the transparency of the three-dimensional skull shape before correction;
Determining the transparency of the three-dimensional skull shape after correction;
Determining the color of the three-dimensional skull shape before correction;
Determining the color of the three-dimensional skull shape after correction; and
A method of providing diagnostic information for orthodontic treatment, comprising the step of displaying a three-dimensional skull shape before orthodontic and a three-dimensional skull shape after orthodontic overlap with respect to the same center.
The method of claim 1 .
The method of providing diagnostic information for orthodontic treatment, characterized in that each of the skulls overlapped and displayed in the above is a three-dimensional three-dimensional shape.
3. The method of claim 2,
Orthodontic treatment, characterized in that each skull is provided as a multi-plane display composed of three-axis planes of X, Y, and Z, and the multi-plane display is changed according to the movement of each plane along the three axes. method of providing diagnostic information for
The method of claim 1,
When the orthodontic position of all teeth is designated, it is stored, and all teeth are dynamically shown to move from the position before orthodontics to the position after correction (S10) Providing diagnostic information for orthodontic treatment, characterized in that it further comprises Way.
5. The method of claim 4,
The method of dynamically showing the movement from the pre-correction position to the post-correction position is to continuously show the final image in which correction is completed from the initial image before correction, or to show the state that has been changed according to the set time for each predetermined time interval (Step). ) A method of providing diagnostic information for orthodontic treatment, characterized in that it is any one of the items shown by each.

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