KR102438919B1 - implanting method for dental restoration - Google Patents

Abstract

In order to improve dental restoration reliability, the present invention generates a three-dimensional planning image in which a CT image is superimposed on a scanning image including three-dimensional external information of the upper and lower jaw of which at least one side is the restoration target gum portion, and a matched three-dimensional planning image is generated in the three-dimensional planning image. A first step of designing and manufacturing an implanting guide device in which a plurality of implant placement information is set along the dental arch, and an instrument for alveolar bone flattening and implant placement is guided; Guided by the implanting guide device, the alveolar bone is flattened and the implant is implanted, the holder device comprising a holder abutment and a fixing bar fixed to the via insertion part of the holder abutment is fixed to the upper side of the implant. Step 2; The temporary dentures are occluded between the upper and lower jaws so that the temporary mounting part into which the holder device is inserted is formed on the inner part of the temporary denture softened during heating to a preset softening temperature range so as to be deformed in response to the patient's vertical height through occlusal pressure. a third step to be corrected; A fourth step in which a corrected scanning image is obtained from the corrected scanning image of the temporary denture so that the 3D external information of the temporary mounting unit is exposed to the outside, the 3D external information of the temporary mounting unit is replaced with a virtual holder device ; and a fifth step of manufacturing a final dental restoration by fixing an artificial tooth part to an artificial gum part in which a mounting part is formed on the inner surface based on the virtual holder device, to which a clip engaged with the fixing bar is fixed. provides a way to

Description

Dental restoration implanting method {implanting method for dental restoration}

The present invention relates to a dental restoration implanting method, and more particularly, to a dental restoration implanting method having improved dental restoration reliability.

BACKGROUND ART In general, a denture or a prosthesis is a dental restoration that artificially restores appearance and function by replacing a missing natural tooth. At this time, the dentures or prostheses can be installed inside the oral cavity to restore the masticatory function and prevent periodontal tissue deformation, and can be divided into partial/complete dentures and partial/complete prostheses according to the number of missing teeth.

On the other hand, the denture is installed by applying a dental adhesive to the inner surface-side mold groove is adhered to the surface of the gum. For this reason, there is a problem of causing a foreign body sensation and pain because direct occlusal pressure is applied to the gums. On the other hand, the prosthesis is fixed to a fixture to be placed in the alveolar bone, thereby reducing the feeling of foreign body and pain in the gums due to occlusal pressure. However, there is a problem in that the prosthesis is substantially permanently fixed and difficult to manage. Accordingly, an overdenture that compensates for the shortcomings of the denture and the prosthesis has been disclosed.

In detail, since the overdenture is detachable from the oral cavity like the denture while being fixed to a fixture to be placed on the alveolar bone like the prosthesis, it is easy to manage such as cleaning. At this time, the overdenture includes a coupling means selectively coupled to the abutment fixed to the fixture.

Here, the conventional coupling means is provided in a ball type that is individually matched to the implanted and fixed implants spaced apart along the dental arch of the alveolar bone, or provided as a bar type passing through the implants. At this time, it is preferable to understand that the implantation includes a fixture and an attachment/abutment.

At this time, the ball-type coupling means has a structure in which the upper end of the attachment fastened to each fixture is individually coupled to the fixing part formed on the inner surface of the overdenture, and thus the positional precision between each attachment and each fixing part is required. That is, if any one of the coupling means is not aligned at the correct position, there is a problem that the overdenture cannot be installed accurately.

And, the bar-type coupling means is fixed via a fixing bar along the abutment fastened to each of the fixtures, the upper end of the abutment and the coupling groove into which the fixing bar is inserted is formed on the inner surface of the denture. Therefore, there is an advantage that the bar-type coupling means is easier to mount the overdenture in the oral cavity than the ball-type coupling means.

At this time, the fixing bar is provided by being bent in response to the implantation information of the implant so as to pass through the plurality of implants previously implanted in the alveolar bone, and after bending, deformation due to external force such as masticatory pressure can be minimized. It is made of metal material. Therefore, in order for the fixing bar to be firmly fixed to each of the implants, the height of each of the implants must be uniformly aligned, and for this purpose, a flattening operation of the alveolar bone is required. Moreover, the vertical diameter is different for each recipient who requires dental restoration, and the amount of cutting of the alveolar bone is determined in response to the vertical diameter.

However, in the prior art, the operator cut / flattened the alveolar bone based on the experience value, and due to this, when the amount of cutting is too large or small, the occlusion between the opposing tooth and the overdenture is undesirable, and there is a problem that the discomfort is increased. In addition, there was a problem in that the flattened outer surface of the alveolar bone could not be precisely formed to correspond to the height at which the fixture was implanted, so that the fixing bar could not be firmly fixed.

Meanwhile, in the prior art, the overall dental restoration plan including the implantation information and the design of the overdenture is designed based on the CT image including information such as the outer surface and density of the alveolar bone of the recipient.

At this time, in the case of a CT image, it is easy to obtain information about the alveolar bone, but it is difficult to obtain information about the gum, which is a soft tissue. In addition, there was a problem in that it was difficult to use the CT image data in the design of each device for guiding the actual overdenture and implantation. That is, it takes an excessive amount of time to convert the CT image into an STL file that is easy to 3D print or mill the overdenture and various guide devices. In addition, as the manufacturing time of various guide devices and a series of implanting processes using the manufactured various guide devices, i.e., alveolar bone cutting and fixture placement, take a long time, the overall period of dental restoration increases, increasing inconvenience There was a problem being

Korean Patent Registration No. 10-1694475

In order to solve the above problems, an object of the present invention is to provide a dental restoration implanting method in which dental restoration reliability is improved.

In order to solve the above problems, the present invention generates a three-dimensional planning image in which a CT image is superimposed on a scanning image including three-dimensional external information of the upper and lower jaw of which at least one side is the restoration target, the three-dimensional planning image is generated. A first step of designing and manufacturing an implanting guide device in which a plurality of implant placement information is set along the dental arch, and an instrument for alveolar bone flattening and implant placement is guided; Guided by the implanting guide device, the alveolar bone is flattened and the implant is implanted, the holder device comprising a holder abutment and a fixing bar fixed to the via insertion part of the holder abutment is fixed to the upper side of the implant. Step 2; The temporary dentures are occluded between the upper and lower jaws so that the temporary mounting part into which the holder device is inserted is formed on the inner part of the temporary denture softened during heating to a preset softening temperature range so as to be deformed in response to the patient's vertical height through occlusal pressure. a third step to be corrected; A fourth step in which a corrected scanning image is obtained from the corrected scanning image of the temporary denture so that the 3D external information of the temporary mounting unit is exposed to the outside, the 3D external information of the temporary mounting unit is replaced with a virtual holder device ; and a fifth step of manufacturing a final dental restoration by fixing an artificial tooth part to an artificial gum part in which a mounting part is formed on the inner surface based on the virtual holder device, to which a clip engaged with the fixing bar is fixed. provides a way to

Through the above solutions, the present invention provides the following effects.

First, a highly precise dental restoration plan is established for the patient based on the scanning image and CT image of the oral cavity and the external information of the implant and sleeve device stored in the digital library. Guide devices and dental restorations can be mounted in the oral cavity with high precision and precision.

Second, the implantation information is accurately set based on the CT image showing the cross-section of the oral cavity, but the image data for the actual design is the 3D implanting guide device based on the scanning image and virtual data, which are surface data. It is easy to convert to a printable STL file, so the overall design and manufacturing process can be significantly shortened.

Third, as the position of the virtual flat surface, which is the standard for flatness and cutting of the alveolar bone, is corrected by considering the clearance gap for interference with the alveolar bone when the surgical guide is installed, the actual surgical guide is precisely fixed in the oral cavity and the implant is placed Because it guides the implantation precision can be significantly improved.

Fourth, the universally provided jig base is individually coupled to each holder abutment, and the alignment direction of the neighboring jig base through the alignment coupling bar guides the fastening of the fastening screws while constrained in parallel with the preset bending path information. Since the bonding tolerance is formed to be substantially close to zero, the accuracy of implantation can be significantly improved.

Fifth, since the final dental restoration is mounted and fixed through a holder device that is fixed in a wide arc area along the dental arch, occlusal stability is remarkably improved.

1 is a flowchart for a dental restoration implanting method according to an embodiment of the present invention.
2 is an exemplary view showing a three-dimensional planning image set according to an embodiment of the present invention.
3 is an exemplary diagram illustrating a process in which a virtual sleeve device is virtually disposed according to an embodiment of the present invention.
4 is an exemplary view showing a process of setting a virtual flat surface according to an embodiment of the present invention.
5 is an exemplary view showing a modified example of a process for setting a virtual flat surface according to an embodiment of the present invention.
6 is an exemplary view showing design information of an implanting guide device applied to an embodiment of the present invention.
7 is an exemplary view showing design information of an implanting guide device applied to another embodiment of the present invention.
8 is an exemplary view showing design information of an implanting guide device applied to another embodiment of the present invention.
9 is an exemplary view showing an implanting guide device manufactured according to another embodiment of the present invention.
10 is an exemplary view showing a process in which the holder device is fixed according to an embodiment of the present invention.
11 is an exemplary view showing a process for confirming the bending angle of the fixed bar according to an embodiment of the present invention.
12 is an exemplary view showing a process of correcting temporary dentures according to an embodiment of the present invention.
13 is an exemplary diagram illustrating a process in which a corrected scanning image is swapped according to an embodiment of the present invention;
14 is an exemplary view showing the design process of the overdenture and cutting guide according to an embodiment of the present invention.
15 is an exemplary view illustrating a process in which an artificial tooth part is corrected and fixed to an artificial gum part according to an embodiment of the present invention.
Figure 16 is an exemplary view showing a process in which the clip is fixed to the artificial gums according to an embodiment of the present invention.

Hereinafter, a dental restoration implanting method according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

On the other hand, the implanting method of the present invention includes not only placing an implant (hereinafter referred to as a fixture) in the alveolar bone, but also manufacturing the final dental restoration and mounting a series of processes for mounting on the upper side of the implanted fixture. It is better to understand the meaning. At this time, it is preferable to understand that the dental restoration finally manufactured according to the present invention is an overdenture that is detachably mounted from the oral cavity through a holder device fixed to the upper side of the fixture, including a holder abutment and a fixing bar.

And, it is preferable to understand that the restoration target gum part to be described below is a jaw that requires dental restoration through the overdenture, and in the present invention, it is described and illustrated as a mandible in which the molars remain. In addition, the opposing arch or the opposing side, which will be described below, is preferably understood as the jaw that occludes the restoration target gum portion, and in the present invention, it is described and illustrated as the upper jaw, which is the deciduous jaw. Of course, in some cases, the present invention may be edentulous or partially edentulous in the maxilla and/or the mandible, and the same may be applied to the manufacturing process of the overdenture when the maxilla and/or mandible become denture jaws, but restoration is required after tooth extraction. .

It is preferable to understand that the implanting guide device to be described below includes a planarization guide and a surgical guide. The flattening guide is a device for cutting and flattening the upper end of the alveolar bone in accordance with the implantation height of the fixture in consideration of the vertical height between the overdenture and the opposing tooth, and the height of the holder device to which the overdenture is mounted. It is desirable to understand In addition, the surgical guide is preferably understood as a device for guiding the fixture to be placed in the correct placement position and direction in the cut and flattened alveolar bone.

In addition, temporary dentures to be described later are dentures manufactured primarily to be deformed by the impression model manufactured after taking an impression of the oral cavity or oral cavity in order to obtain design information for the dental restoration. Of course, the temporary denture can be used temporarily by the patient in the dental restoration process, and the usability and convenience in the dental restoration process can be significantly improved.

1 is a flowchart of a dental restoration implanting method according to an embodiment of the present invention, and FIG. 2 is an exemplary view showing a three-dimensional planning image set according to an embodiment of the present invention.

1, the dental restoration implanting method according to the present invention is a three-dimensional planning image generation and implant placement information setting (s10), implanting guide device design and manufacturing (s20), alveolar bone flattening and implant placement, Includes a series of steps such as holder device fixation (s30), temporary denture correction (s40), correction scanning image swap (s50), artificial teeth and artificial body parts manufacturing, clip fixation (s60), final dental restoration manufacturing (s70) do.

Referring to FIG. 2 , the three-dimensional planning image M includes a scanned image obtained by including three-dimensional external information of the upper and lower jaws of which at least one side is a restoration target. In detail, the scanning image is preferably obtained by scanning the surface of the oral cavity or impression model. The scanning image includes an image (m2) of the restoration target gum part including three-dimensional external information of the restoration target gum part, and an occlusal side image (m3) including three-dimensional external information on the opposing side, and the restoration target gum part The image m2 and the occlusal side image m3 may be acquired, respectively, and virtual occlusal alignment may be performed based on a preset occlusal plane op. Through this, the upper and lower jaw images may be virtually arranged in correspondence with the patient's vertical height. In addition, the CT image m1 is acquired using a CT imaging device that captures a computed tomography (CT) of the patient's head, and includes internal tissue information covered by the gum tissue.

The scanning image and the CT image m1 are overlapped and matched based on a common part, and thus the three-dimensional planning image M can be generated. Here, the common part may be the outer surface of the remaining teeth or the outer surface of the silk tissue in which the flow is minimized without being covered by the gum tissue, such as between the teeth.

Alternatively, if at least one side is edentulous, after attaching a reference marker, the scanning image and the CT image m1 are acquired, and the reference marker image displayed in the same part of each image can be set as a common part and matched. . In this case, it is preferable that the reference marker is attached to the lower side that is spaced apart from the upper end of the alveolar bone as much as possible in consideration of the height of the alveolar bone.

Accordingly, the three-dimensional planning image M includes three-dimensional external information of the restoration target gum portion and the opposing side included in the scanning image, upper and lower alveolar bones, residual teeth, and lower teeth included in the CT image m1. Internal tissue information such as the manic nerve (K) can be displayed at the same time. At this time, the restoration target gum image (m2), the contralateral image (m3), and the CT image (m1) are displayed overlapping based on the common part, each image can be individually modified, and each image is selectively displayed It can be manipulated to flash or blink. That is, it is preferable to understand that the three-dimensional planning image M is not a state in which the scanning image and the CT image m1 are bound, but merely overlaps and is virtually arranged.

In the three-dimensional planning image (M), the implantation information (A) is set in plurality along the dental arch. In detail, the implantation information (A) is preferably set to at least one or more plural, and is preferably set to 4 anterior places or 2 anterior and 2 posterior so that the final dental restoration is stably mounted and supported. . The implantation information (A) is preferably set based on the alveolar bone information included in the CT image (m1).

In addition, the virtual tooth m61 may be virtually disposed on the restoration target gum portion image m2 in response to the vertical height. The virtual tooth m61 is three-dimensional external information of an artificial tooth part (61 of FIG. 15) to be described later, and is pre-stored in a digital library, which is a storage of image data for dental restoration design. This digital library is connected to a planning unit in which the scanning image and the CT image m1 are loaded and displayed, and the three-dimensional planning image M is generated and each design information is set through wired/wireless communication. That is, image data acquired through a scanner or CT imaging device and image data stored in the digital library are loaded into the planning unit to establish an overall plan for dental restoration, and the implanting guide device and the overdenture (FIG. 15) 60) design information can be obtained.

The virtual tooth m61 is preferably set as standardized three-dimensional vector data based on the average value of each tooth calculated in consideration of anatomical deviations by gender and age. In addition, the virtual tooth m61 may be pre-stored as standardized as a single size, or may be pre-stored as divided into large/medium/small. In addition, it is preferable that three-dimensional external information for each artificial tooth corresponding to each tooth is individually set and stored in a set along the dental arch. That is, the virtual tooth m61 may be simultaneously selected in a state in which a plurality of tooth images for any of the upper and lower jaws are arranged along the dental arch, and may be virtually placed on the three-dimensional planning image M. In this case, the virtual tooth m61 may be manipulated to selectively delete unnecessary tooth images from among each tooth image.

3 is an exemplary diagram illustrating a process in which a virtual sleeve device is virtually disposed according to an embodiment of the present invention. At this time, it is preferable to understand that the virtual sleeve device includes a virtual implantation guide sleeve and a virtual fixed guide sleeve, which will be described later.

2 to 3 , a virtual implant mf selected from the digital library based on the alveolar bone information included in the CT image m1 is virtually disposed in response to the implantation information A. In addition, the virtual implantation guide sleeve m51, which is spaced apart from the upper end of the virtual implant mf and virtually arranged concentrically, is superimposed on the scanning image and stored.

The virtual implant mf is preferably understood as 3D external information about a real fixture. In addition, the virtual implantation guide sleeve m51 is three-dimensional external information of a guide sleeve coupled to a surgical guide 50 to be described later to guide the actual placement of the fixture, and the virtual implant mf and It can be pre-stored as a set. The virtual implantation guide sleeve m51 is preferably set to an offset distance (w3 in FIG. 5) according to the standard of the virtual implant. Here, it is preferable that the offset distance (w3 in FIG. 5) be understood as a spaced distance between the upper end of the fixture and the upper end of the guide sleeve. The offset distance (w3 in FIG. 5) is set in consideration of an adjacent residual value or interference with the virtual implantation guide sleeve m51.

At this time, it is preferable that the virtual implantation guide sleeve m51 is set in a set with the virtual coupling part m50a which is three-dimensional external information of the coupling part included in the surgical guide. The virtual coupling part m50a includes a virtual coupling hole m53 to which the virtual implantation guide sleeve m51 is virtually coupled. The virtual coupling hole m53 includes a coupling hole to which a real guide sleeve is coupled and 3D external information about a coupling groove in which a projection of the guide sleeve is rotationally coupled in the coupling hole.

In addition, in response to the anchor pin information (D) set in consideration of the implantation information (A) and the lower alveolar nerve (K), the virtual fixed guide sleeve (m55) is virtually arranged. The virtual fixed guide sleeve m55 is preferably integrated and stored in the scanning image, preferably the restoration target gum image m2, together with the virtual implantation guide sleeve m51. At this time, since the virtual fixed guide sleeve m55 has substantially the same configuration as the virtual implantation guide sleeve m51 except for size and location, a detailed description thereof will be omitted.

The virtual implantation guide sleeve m51 and the virtual fixed guide sleeve m55 are superimposed on the scanning image and integrated and stored, and then can be utilized as design information of the implanting guide device to be described later through a series of processes. At this time, since the virtual implantation guide sleeve (m51) and the virtual fixed guide sleeve (m55) are set and stored in advance with the virtual coupling part (m50a), the design process of the surgical guide 50 is quick and simplified, so manufacturing Convenience can be significantly improved.

Here, the process of erasing and correcting the inner image of the temporary deletion line m2a preset in the restoration target gum portion image m2 may be further included. For example, when a large amount of residual tooth shapes are included in the restoration target image m2 or the virtual sleeve device is excessively obscured by the restoration target gum image m2, such image deletion correction may be performed. . Through this, the virtual implantation guide sleeve m51 and the virtual fixed guide sleeve m55 can be displayed so that the superimposed state on the scanning image can be visually and clearly recognized, so that design convenience can be further improved.

As such, in the present invention, the implantation information (A) is accurately set based on the CT image (m1) in which the cross-sectional image of the oral cavity is displayed as a whole, and the image data required for design is the surface data of each object. It is set based on the scanning image and virtual data. That is, according to this, it is easy to convert the implanting guide device, which will be described later, into an STL file that can be manufactured by rapid 3D printing, and the overall design and manufacturing process can be performed quickly.

4 is an exemplary diagram illustrating a process of setting a virtual flat surface according to an embodiment of the present invention.

Referring to FIG. 4 , a single erasing model m30 matching the restoration target gum portion is extracted from the digital library. The erasure model m30 is standardized into a semi-cylindrical shape corresponding to the anatomical dentition and stored in the digital library. At this time, the rounded portion of the erasing model m30 corresponds to the mesial surface of the oral cavity, and the vertical surface side corresponds to the distal surface of the oral cavity.

In the erasure model m30, a horizontal reference plane m31 matching the occlusal plane op may cross the central portion or may be set on the other surface (upper surface in the drawing). For example, when the upper and lower teeth are restored at the same time, the horizontal reference plane m31 is set along the center of the erasing model m30. It can be set on the other surface of (m30). And, at least one surface (m33) corresponding to the side of the restoration target gum portion is a second reference surface (L2) spaced downward by a preset clearance interval (w1) from the first reference surface (L1) corresponding to the upper end of the virtual implant (L2) and Virtually adjusted to match. The distance h between the horizontal reference plane m31 and the one surface m33 can be virtually adjusted in consideration of the patient's vertical height and the dental restoration plan.

Here, it is preferable that the clearance distance w1 is set in consideration of the position and the angle of arrangement of the lower end of the virtual implantation guide sleeve m51 protruding downward based on the first reference plane L1. That is, the 3D external information of the virtual implantation guide sleeve m51 or the virtual coupling part m50a protruding downward of the first reference plane L1 is taken into consideration, and the clearance gap w1 may be set. Through this, the interference between the inner structure of the surgical guide and the flattened upper surface of the alveolar bone can be prevented in advance when the actual surgical guide is mounted in the oral cavity and the implantation of the fixture is guided. Through this, since the fixture is accurately placed in response to the implantation information (A) set based on the three-dimensional planning image (M), implanting precision can be significantly improved.

Then, an overlapping portion with the erasing model m30 in the restoration target gum image m2 is erased to form the virtual flat surface E, and the upper end of the restoration target gum image m2 is the virtual flat surface. Virtually replaced by face (E). Through this, the overall design information of the implanting guide device based on the three-dimensional external information of the gum part to be restored included in the scanning image, the virtual implantation guide sleeve m51 and the virtual flat surface E, is quickly obtained. and can be precisely set.

Meanwhile, FIG. 5 is an exemplary diagram illustrating a modified example of a process for setting a virtual flat surface according to an embodiment of the present invention. At this time, since the actual configuration of this modified example is the same as that of the embodiment except for the process in which the erasure model is virtually disposed, a detailed description of the same configuration will be omitted.

Referring to FIG. 5 , the erasing model m30 may be virtually disposed based on a matching virtual abutment m14 corresponding to the offset distance w3 of the virtual implantation guide sleeve m51 . The virtual abutment m14 is virtually disposed between the virtual implantation guide sleeve m51 and the virtual implant spaced apart in consideration of the offset distance w3. Preferably, the lower surface of the virtual abutment m14 is formed in a cylindrical shape matching the upper end of the virtual implant, and the height w2 may be set according to the offset distance w3. For example, when the offset distance is 9mm, the length of the virtual abutment may be set to 4.5mm, if the offset distance is 10.5mm, it may be set to 6mm, and when the offset distance is 12mm, it may be set to 7.5.

In addition, it is preferable that one surface m33 of the erasing model m30 is virtually corrected to correspond to the second reference plane L2 set corresponding to the position of the lower surface of the virtual abutment m14. That is, the erasing model m30 is virtually arranged in consideration of the position of the upper end of the holder abutment coupled to the upper end of the actual fixture. Through this, since the cutting and flattening height of the alveolar bone is more preferably set, it is possible to prevent in advance the problem of a decrease in precision due to the interference between the mouth-to-device or device-to-device during the implantation process to be described later.

Furthermore, the cutting and flattening range/position of the alveolar bone is set based on the virtual implant and the virtual implantation guide sleeve m51 that is virtually placed as a set. That is, the cutting and flattening height of the alveolar bone may be set after first considering the holder device and the height of the overdenture mounted through the holder device. Through this, the occlusal precision between the overdenture and the opposing tooth to be finally manufactured and mounted in the oral cavity is improved, and the discomfort during mastication is minimized, so that the satisfaction with dental restoration can be significantly improved.

6 is an exemplary view showing design information of an implanting guide device applied to an embodiment of the present invention. At this time, it is preferable that the three-dimensional external information of the restoration target gum part be understood as the same meaning as the restoration target gum part image m2 below, and are described and illustrated with the same number.

Referring to (a) of Figure 6, the design information (m40) of the flattening guide is the step of forming an inner contour based on the three-dimensional external information (m2) of the restoration target gum portion, and the virtual flat surface (E) ) and the step of forming the design information m41 of the flat guide surface along the rim that is opened at a position corresponding to the setting. And, as the design information m40 of the planarization guide is transmitted to a manufacturing apparatus such as a 3D printer, a real planarization guide is manufactured.

In detail, the virtual body portion is formed by protruding or spaced apart from the inner and outer surface surface information of the gum corresponding to the lower side with respect to the virtual flat surface E in the restoration target gum portion image m2 at a predetermined thickness or interval. At this time, the upper side of the virtual body portion based on the virtual flat surface (E) is set to be opened. Then, the design information m41 of the flat guide surface is set along the upper edge of the virtual body that matches the outer edge of the virtual flat surface E. In addition, design information of a piece fixing part to which an anchor pin can be fixed based on the virtual fixing guide sleeve m55 superimposed on the scanning image and stored may be included in the design information m40 of the flattening guide.

Referring to (b) of Figure 6, the design information (m50) of the surgical guide is the virtual coupling hole (m53) corresponding to the outer periphery of the virtual implantation guide sleeve (m51) at the upper end of the virtual body portion is formed, is designed And, as the design information m50 of the surgical guide is transmitted to the manufacturing device, the actual surgical guide is manufactured.

Here, since the virtual coupling hole m53 is included in the virtual coupling part m50a pre-stored as a set with the virtual implantation guide sleeve m51, the virtual coupling hole m53 has a three-dimensional appearance without a separate complicated design process. Information can be set immediately. In addition, since the design information m41 of the flat guide surface is set in consideration of the clearance w1, a virtual setting based on the design information m41 of the lower surface of the virtual coupling part m50a and the flat guide surface The virtual cutting surfaces m1a to be spaced apart may be set. In addition, design information of the piece fixing unit may be included in the design information m50 of the surgical guide based on the virtual fixing guide sleeve m55.

That is, the planarization guide and the surgical guide are designed based on the substantially identical image data, the restoration target gum image (m2) and the anchor pin information (D), based on the virtual flat surface (E). The design information m41 of the flat guide surface or the position of the virtual fixed guide sleeve m55 is set. Accordingly, the contour of the inner surface of the finally manufactured flattening guide and the surgical guide and the position of the piece fixing part may be set to be substantially the same. Through this, since the mounting positions are substantially identical to each other in the process of mounting the surgical guide 50 after separating the planarization guide, implanting precision can be significantly improved.

Furthermore, in the planarization guide, the design information m41 of the flattening guide surface is based on the second reference surface L2 so that the clearance gap for interference between the cut and flattened upper end of the alveolar bone and the actual surgical guide is considered. is set to Therefore, in a state in which the actual surgical guide is mounted on the alveolar bone, the inner surface portion to which the guide sleeve is coupled may be spaced apart from each other while being molded and fixed along the alveolar bone side portion. Through this, the implantation precision can be remarkably improved because an implantation error that occurs when the surgical guide is not mounted in an accurate position is prevented in advance.

On the other hand, Figure 7 is an exemplary view showing the design information of the implanting guide device applied to another embodiment of the present invention, Figure 8 is the design information of the implanting guide device applied to another embodiment of the present invention. It is an example diagram shown. And, Figure 9 is an exemplary view showing an implanting guide device manufactured according to another embodiment of the present invention. At this time, since the basic configuration other than the process of acquiring design information in FIGS. 7 to 8 is the same as the above-described embodiment, a detailed description of the same configuration will be omitted.

Referring to FIG. 7 , an inner contour of the design information m500A of the surgical guide may be formed based on an outer contour of the design information m40 of the planarization guide. And, it can be designed and manufactured, including the step of forming the virtual coupling hole (m53) corresponding to the virtual implantation guide sleeve (m51) at the upper end of the design information (m500A) of the surgical guide (m500A). At this time, the design information (m500A) of the outer side of the surgical guide may be set with a virtual alignment coupling groove (m54) that matches the outer periphery of the design information (m50b) of the piece fixing part. In addition, the design information m50c of the fixing piece hole may be further included in the design information m500A of the surgical guide separately from the design information m50b of the piece fixing part included in the design information m40 of the flattening guide. have.

That is, the surgical guide designed and manufactured by the above process is supported and fixed to the outer surface of the planarization guide. Accordingly, the surgical guide may be superimposed on the planarization guide fixed through the anchor pin to the restoration target gum portion and fixed thereon. Therefore, since the problem that the mounting position is shifted in the process of mounting the surgical guide after separating the planarization guide is fundamentally solved, precision can be further improved. In addition, due to the repeated implantation and separation of the anchor pin in the alveolar bone, excessive damage is prevented, and the strength of the alveolar bone is prevented from weakening, thereby significantly improving safety.

Referring to FIG. 8 , the virtual guide body in which an inner contour is formed based on the three-dimensional external information m2 of the restoration target gum part, and the virtual coupling hole m53 corresponding to the outer periphery of the virtual implantation guide sleeve is formed. (m9) is set. In addition, a three-dimensional virtual cutout block m41 protruding to a thickness that one surface matches the first reference surface L1 and the other surface matches the second reference surface L2 is formed around the virtual guide body m9. Virtually arranged in plurality. Then, when the overlapping region d1 of the virtual incision block m41 and the virtual guide body is erased, design information m500B of the surgical guide including design information of the incision slot hole is generated.

Referring to FIG. 9 , the actual surgical guide 500B manufactured based on the design information m500B of the surgical guide has a cutout slot hole 57 formed based on the virtual cutout block m41 as a boundary. It is divided into a lower first body portion 501 and an upper second body portion 502 . At this time, a coupling hole 53 to which a guide sleeve 52 including a guide hole 51 is coupled is formed in the second body portion 502 , and the guide sleeve 52 is formed on an inner periphery of the coupling hole 53 . ) may be formed with a binding groove (53a) in which the protrusion is caught. In addition, when the molars remain, the alignment-type portion 59 that is aligned with this may be further formed.

And, after manufacturing the two surgical guides 500B, one surgical guide 500B may be transformed into a planarization guide by separating the upper side along the incision slot hole 57 . As such, since substantially only one design is required to manufacture the surgical guide and the planarization guide, the simplification and speed of the design process can be significantly improved. In addition, since the lower surface 57c of the cut-out slot hole 57 is substantially formed to correspond to the second reference plane L2, when the second body part 502 is separated, the cut-out slot hole 57 is formed. The lower surface 57c may function as the flat guide surface.

10 is an exemplary view illustrating a process in which the holder device is fixed according to an embodiment of the present invention, and FIG. 11 is an exemplary view illustrating a process for confirming the bending angle of the fixing bar according to an embodiment of the present invention.

10 to 11 , the alveolar bone is cut and flattened by being guided by the flattening guide, and the fixture f is implanted in the alveolar bone 1a that is cut and flattened by the surgical guide. And, the holder device (1400 in FIG. 12) is fixed to the upper side of the fixture (f). Here, the holder device ( 1400 in FIG. 12 ) includes a holder abutment 1410 and a fixing bar 1430 .

The holder abutment 1410 is fixed to the upper side of the fixture (f) through a fastening screw (1420 in FIG. 12), and a diesel insert 1414 recessed along the longitudinal direction is formed at the upper end. At this time, the fixing bar 1430 is inserted into the light oil insertion part 1414, and the pressing means (1440 in FIG. 12) is coupled to the upper end of the fastening hole (1413 in FIG. 12) of the central part through which the fastening screw 1420 passes. As a result, the fixing bar 1430 is clamped and fixed between the inner lower end of the light oil insertion part 1414 and the pressing means (1440 in FIG. 12).

Here, the fixing bar 1430 is bent so as to intersect the two implantation points A1 on the anterior side and the two implantation points A2 on the posterior side among the plurality of implantation information A set along the dental arch. At this time, the fixing bar 1430 may be provided in a trapezoidal shape by bending both ends based on a preset bending point, and the central portion of the fixing bar 1430 intersects the pair of anterior implantation points A1. It is provided, and both ends are provided to intersect the posterior implantation point (A2), respectively. Accordingly, the bending point position and the bending angle can be clearly set based on the three-dimensional planning image M, and the bent state can be stably maintained. Through this, it is possible to prevent in advance the damage or breakage of the alveolar bone due to the spring back (spring bhack) after bending the fixed bar 1430 to be round in the prior art.

Meanwhile, bending path information for guiding the bending of the fixed bar 1430 is set based on the three-dimensional planning image (M). That is, the implantation information (A) includes a pair of the anterior implantation points (A1) that intersect the center line (B1) of the bending path information and a pair of the molars that intersect the both sides line (B2) of the bending path information. It is set corresponding to the side implantation point A2. In addition, the fixing jig base 10 and the pivot guide jig base 20 for guiding the light oil insertion part 1414 of the holder abutment 1410 to be opened corresponding to the bending path information are prepared.

Referring to Figure 10 (a), the fixture (f) is implanted at each of the implantation points (A1, A2), the fixture (f) is placed corresponding to the pair of the anterior implantation points (A1) The holder abutment 1410 is disposed on the upper end of the . Then, the fixing jig base 10 is coupled to each upper end of the holder abutment 1410 .

The fixing jig base 10 is formed with an alignment protrusion 12a that is engaged with the light oil insertion portion 1414 on the inner periphery of the receiving groove 12 into which the holder abutment 1410 is inserted at the upper end. In addition, an alignment groove 15 is formed across the upper surface in parallel to the alignment protrusion 12a, and a through hole 13 communicating with the receiving groove 12 is formed. Therefore, when the alignment grooves 15 of each of the fixing jig base 10 are aligned to communicate in a straight line, the opening direction of the diesel insert 1414 fitted to the alignment protrusion 12a also communicates in a straight line. It can be rotationally aligned as possible.

In a state in which each of the alignment grooves 15 communicate in a straight line, the alignment fixing bar (u) is simultaneously inserted in the rotationally aligned state, thereby constraining the rotationally aligned state. And, when a rotation means such as a screwdriver is inserted into each of the through holes 13 of the fixing jig base 10, the rotation is restricted, and the fastening screw 1420 is fastened to the fixture (f). A butt 1410 is fixed to the anterior side.

Referring to (b) of FIG. 10 , the pivot guide jig base 20 is alternately coupled to the holder abutment 1410 fixed to the anterior side. The jig base 20 for the pivot guide has an alignment groove 25 formed on its upper surface and a cylindrical receiving groove 22 into which the upper end of the holder abutment 1410 is inserted. Accordingly, the pivot guide jig base 20 may be rotated while being supported by the holder abutment 1410 while being coupled to the holder abutment 1410 .

The holder abutment 1410 is disposed above the fixture f implanted at the posterior implantation point A2, and the fixing jig base 10 is provided on the holder abutment 1410. are combined And, the alignment groove 15 of the jig base 10 for fixing disposed on the posterior side and the alignment groove 25 of the jig base 20 for the pivot guide disposed on the anterior side are rotationally aligned so that they communicate in a straight line. The alignment fixing bar (u) is inserted at the same time, the rotational alignment state is constrained. Accordingly, in the holder abutment 1410 on the posterior side, the light oil insertion portion 1414 may be aligned and fixed in correspondence with the both sides line B2.

The fixing jig base 10 and the pivot guide jig base 20 have the inner periphery diameter of each of the receiving grooves 12 and 22, the receiving grooves 12 and 22 and the alignment grooves 15 and 25, respectively. ) is standardized to correspond to the standard of the holder abutment 1410 and the bending angle unit of the fixed bar 1430, so that it is preferably prepared for general use.

Therefore, since the hassle of individually designing and manufacturing the jig base for fixing the holder abutment 1410 in the correct direction for each patient is minimized, the overall process and time of dental restoration is shortened, and the cost is reduced, which is economical. In addition, since the alignment direction of the neighboring jig base through the alignment fixing bar (u) guides the fastening of the fastening screws in a state constrained in parallel with the preset bending path information, the coupling tolerance is formed substantially close to 0, thereby forming the implant Ting accuracy can be significantly improved.

11 (a) to (b), the fixing jig base 10 is recombined to each upper end of the holder abutment 1410 coupled to and fixed to the fixture (f), the fixing A curable resin is applied to a predetermined thickness so as to simultaneously cover each upper end of the paper jig base 10 . Then, the curable resin is cured to form an alignment support portion 10A as a bridge for integrally connecting a plurality of the fixing jig base 10 . That is, the position of the fixing jig base 10 and the alignment direction of the alignment protrusion 12a may be fixed through the alignment support portion 10A.

Then, the holder analog 4 is inserted into each receiving groove 12 of the fixing jig base 10 fixed through the alignment support portion 10A. The holder analog 4 is formed with an angular alignment portion 4a corresponding to the light oil insertion portion 1414 at the upper end thereof. Accordingly, when the upper end of the holder analog 4 is inserted into the receiving groove 12 , the angle alignment portion 4a is fitted to the alignment protrusion 12a.

Referring to (c) of FIG. 11 , the lower ends of the holder analogs 4 aligned and inserted into each of the receiving grooves 12 are integrally connected through a curable material such as gypsum. And, when the curable material is cured, it has rigidity to maintain a spaced distance between the lower ends of the holder analog 4 . Accordingly, the holder analog 4 may be formed as an angle confirmation model 10B constrained in a state in which it is disposed corresponding to the implantation point. Further, on the outer periphery of the holder analog 4, a constraint alignment surface 4b formed as a discontinuous surface such as a decut surface is formed. Accordingly, rotation of the holder analog 4 is restrained while the curable material fills between the lower portions of the holder analog 4 and hardens.

Referring to (d) of Figure 11, the bending angle of the fixed bar 1430 is confirmed through the angle confirmation model (10B). That is, when the fixing bar 1430 is inserted into the angle alignment part 4a without interference, it can be determined that the fixed bar 1430 is bent at a desired bending angle. On the other hand, when the fixing bar 1430 is inserted into the angle alignment part 4a, if it interferes or is not properly inserted, it is determined that a bending error has occurred and the fixing bar 1430 can be corrected.

As such, in the present invention, since the angle confirmation model 10B is generated based on the holder abutment 1410 directly fixed to the cut and flattened alveolar bone 1a, the fixing bar 1430 corresponds to the actual oral environment. can be precisely calibrated. In addition, since the bending error of the fixing bar 1430 is determined and corrected outside the oral cavity after the holder abutment 1410 is fixed in the oral cavity, discomfort due to frequent visits or repeated confirmation of the patient can be minimized.

12 is an exemplary diagram illustrating a process of correcting temporary dentures according to an embodiment of the present invention, and FIG. 13 is an exemplary diagram illustrating a process in which a corrected scanning image is swapped according to an embodiment of the present invention. On the other hand, the temporary denture 30 can be corrected by occlusion between the upper and lower jaw or the holder analog and the impression model to which the holder device 1400 is actually fixed. What is corrected is described and illustrated by way of example.

Referring to FIG. 12 , a temporary denture 30 that is softened during heating to a preset softening temperature range is prepared, and the temporary denture 30 is disposed between the upper and lower jaws to which the holder device 1400 is fixed. And, the temporary denture 30 is occlusal correction so that the deformation corresponding to the vertical height of the patient through the occlusal pressure of the patient. Through this, the temporary mounting part 35 into which the holder device 1400 is inserted into the inner surface of the temporary denture 30 is formed under pressure.

In detail, the temporary denture 30 may be manufactured by 3D printing a base resin including an acrylic oligomer to correspond to the shape of the temporary denture 30 , and has a space exceeding the volume of the holder device 1400 . It is formed to include an allowance groove (33a) recessed on the inner surface side. When the temporary denture 30 is heated, it is preferable that the inner surface side of the temporary gum portion 33 except for the side of the temporary tooth portion 32 occluded with the opposing tooth is heated and softened, and the allowance groove (33a) In a state in which the relining resin 34 is filled, occlusion can be corrected between the upper and lower jaws.

Through this, the temporary mounting part 35 corresponding to the outer shape of the holder device 1400 is formed in an intaglio on the relining resin 34, and the temporary gum part 33 side is the actual dental arch and gum of the patient. It may be corrected corresponding to the shape of the minor outer surface. Furthermore, as the corrected temporary denture 30 is photocured, it can be completely hardened to a strength capable of supporting the masticatory pressure. Therefore, it is possible to temporarily use the temporary denture 30 until the initial production of the dental restoration.

Referring to FIG. 13 , a temporary denture image m30 is obtained by scanning the entire inner and outer surfaces of the temporary denture 30 in which the temporary mounting part 35 is corrected on the inner surface. Then, from the temporary denture image (m30), the three-dimensional external information (m35) of the temporary mounting part and the three-dimensional external information (m33) of the inner part of the temporary gum part corrected corresponding to the restoration target gum part are exposed to the outside. A corrected corrected scanning image m30A is obtained.

In detail, a boundary line X is set between the three-dimensional external information of the temporary gum part and the three-dimensional external information of the temporary tooth part. Then, unnecessary image data except for the inner surface of the boundary line X is set as the erasing area m39 and erased. Through this, the three-dimensional external information (m35) of the temporary mounting part formed on the inner side of the temporary denture is swapped so as to be exposed to the outside, and is obtained as the corrected scanning image (m30A).

In this case, it is preferable that the corrected scanning image m30A is replaced with a virtual holder device m40 previously stored in the digital library. The virtual holder device m40 preferably corresponds to the outer shape of the holder abutment 1410, and includes a virtual fixing bar m43 and a virtual clip m67 that is virtually engaged with the virtual fixing bar m43. It is preferable to do That is, as distortion or noise that may occur during the scanning process of the temporary denture 30 or surface irregularities, notch, processing, or scanning of the temporary denture 30 that occurs during occlusion of the temporary denture 30 is swapped with the virtual holder device m40, design accuracy and The precision can be significantly improved.

Moreover, the overall scanning image including the temporary denture image m30 is stored as face information without thickness. In addition, the virtual data stored in the digital library is pre-stored as data that itself can be utilized as design information. Accordingly, the scanning image or the corrected scanning image m30A can be easily utilized as the design information of the overdenture, and the image processing difficulty is lowered and the speed is increased, so that the design convenience can be remarkably improved.

14 is an exemplary view showing the design process of the overdenture and the cutting guide according to an embodiment of the present invention, Figure 15 is an artificial tooth according to an embodiment of the present invention showing the process of being corrected and fixed to the artificial gums It is also an example.

14 to 15, the cutting guide 70 for adjusting the height of the artificial tooth part 61 to fit the patient's vertical diameter based on the three-dimensional planning image M is preferably designed and manufactured. do.

Referring to FIG. 14 , the virtual tooth m61 is virtually disposed between the restoration target gum image m2 including the virtual flat surface E and the opposing side image m3, and the virtual tooth ( The virtual artificial gum part m62 is set so as to overlap the root side of m61).

The virtual artificial gum unit m62 may selectively extract data pre-stored in the digital library and virtually place it on the scanned image, or may be set based on the restoration target gum unit image m2. At this time, it is preferable that the artificial tooth part 61 is standardized and provided as a ready-made product, and the virtual tooth m61 is a 3D external information about the artificial tooth part 61 prepared as a ready-made product that is pre-stored in the digital library. It is desirable to understand Through this, the inconvenience of complexly designing and separately manufacturing each artificial tooth of the artificial tooth part 61 can be minimized, and the manufacturing process and period of the overdenture 60 can be shortened.

On the other hand, the occlusal end (m61d) of the virtual tooth is aligned to virtual occlusion with the occlusal side image (m3) based on the occlusal plane (op). At this time, when the height of the virtual tooth m61 exceeds the patient's vertical diameter, the root end m61c of the virtual tooth protrudes below the outer shape information of the restoration target gum image m2. In addition, a virtual base gum part m62 corresponding to the inner surface part of the restoration target gum part image m2 is virtually disposed on the scanning image, and the virtual tooth m61 and the virtual base gum part m62 overlap each other. The deleted area is set as the deletion area u2.

That is, the intersecting lines e1 and e2 are set along the edge formed by intersecting the inner and outer surface information of the virtual base gum portion m62 and the surface information of the virtual tooth m61, and the intersecting lines e1, The image of the virtual base gum part m62 located inside the e2) is erased. At the same time, in the virtual tooth image m61, the image located outside the intersection lines e1 and e2 is erased, but the image located inside the intersection lines e1 and e2 is the virtual base gum portion m62 ) is integrated with Accordingly, a virtual merging surface u1 may be set along the inner periphery of the deletion region u2.

At this time, the design information of the cutting guide includes three-dimensional outer shape information of the cutting hole formed through the corresponding virtual mating surface u1. In addition, the virtual artificial gum portion is formed with an inner periphery based on the virtual mating surface u1, the inner contour of the virtual base gum portion m62, that is, a preset seating interval w4 from the virtual flat surface E. Including the inner surface information (m62c) of the coupling groove spaced apart. That is, the design information of the cutting guide and the virtual artificial gum part are designed based on the virtual base gum part m62, which is the same design data, and the three-dimensional outer shape information of the cutting hole corresponds to the virtual convex surface u1. It is formed through the virtual base gum portion (m62). In addition, the virtual artificial gum portion may be set to be shielded by a thickness corresponding to the inner surface information m62c of the coupling groove on the virtual mating surface u1. The design information of the cutting guide and the virtual artificial gum part set based on the three-dimensional planning image M are transmitted to the manufacturing device and manufactured into a real cutting guide 70 and a real artificial gum part 62 .

Referring to FIG. 15A , each of the artificial teeth 61b of the artificial tooth part 61A prepared for general use is inserted into each of the cutting holes 72 of the cutting guide 70 . At this time, when one side of the outer periphery of each artificial tooth 61b is engaged with the inner circumferential surface of each of the cutting holes 72, the apical end 61c of the artificial tooth portion 61A protrudes toward the inner surface of the cutting guide 70. do. The apical end portion 61b of the protruding artificial tooth portion 61A may be cut and corrected based on the inner edge 72a of the cutting hole 72 . Through this, the height of the artificial tooth part 61 can be corrected in response to the patient's vertical height.

15 (b), each artificial tooth 61bb of the artificial tooth part 61 cut-corrected is fitted to each of the coupling grooves 62a formed in the artificial gum part 62, but is adhered through an adhesive. The overdenture 60, which is the final dental restoration, is manufactured. Here, the inner surface portion 62b of the artificial gum portion 62 is fitted to the restoration target gum portion, and the mounting portion is formed. In this case, a bottom surface 62c corresponding to the seating interval w4 may be formed between the coupling groove 62a and the inner surface portion 62b of the artificial gum portion 62 . At this time, in consideration of the thickness difference between the cutting guide 70 and the artificial gum portion 62, which has a step difference corresponding to the seating interval w4, each of the artificial teeth 61bb is the three-dimensional planning image (M) It is preferable that the correction cutting is additionally performed by the preset seating interval w4.

As such, in the present invention, the artificial tooth part 61A is compared to a standardized size without a complicated design process, and manufacturing convenience is improved, while each tooth apical end part 61b is a cutting guide manufactured based on the three-dimensional planning image (M) ( 70), cutting correction is appropriate for the patient's vertical height. Accordingly, since it is corrected appropriately for the vertical diameter of each patient, economical efficiency and precision of the dental restoration can be remarkably improved.

At this time, it is preferable that the index jig 80 for aligning each artificial tooth 61b of the artificial tooth part 61A at the same time is further manufactured. The index jig 80 has an alignment jig groove 81 formed on the basis of the three-dimensional external information of the occlusal end m61d of the virtual tooth displayed in the three-dimensional planning image M. Through this, since the respective artificial teeth 61b and 61bb are aligned and coupled between the index jig 80 and the cutting guide 70/artificial gum portion 62 at the same time, cutting of each artificial tooth 61b or each of the artificial teeth The attachment of (61bb) can be guided to a quick and precise position.

16 is an exemplary view illustrating a process in which a clip is fixed to an artificial gum part according to an embodiment of the present invention.

Referring to FIG. 16 , the artificial gum part 62 includes a fixing hole 66 communicating with the mounting part 65 in which a mounting part 65 is formed on the inner surface part based on the virtual holder device m40. is manufactured by The mounting part 65 includes a first molded part 65a corresponding to the outer shape of the holder abutment and a second molded part 65b corresponding to the external shape of the fixing bar, and according to the step difference, the holder device ( When the artificial gum unit 65 is coupled to 1400 , the positions may be aligned. In addition, the end of the clip 67 is inserted into the fixing hole 66 and fixed through the resin r that is filled and cured in the fixing hole 66 . Therefore, when the clip 67 fixed to the inside of the mounting part 65 is bitten by the fixing bar 1430 , the artificial gum part 62 and/or the overdenture 60 is the holder device 1400 . It is supported on the oral cavity and can be maintained in a mounted state.

At this time, the clip 67 is engaged at a preset position of the fixing bar 1430 , and when the artificial gum part 62 is mounted so that the holder device 1400 is inserted into the mounting part 65 , the clip 67 ) may be positioned so that the end is inserted into the fixing hole 66 . In addition, when the resin r is filled and cured into the fixing hole 66 , the clip 67 may be fixed to the artificial gum portion 62 .

Alternatively, the artificial gum part 62 is mounted so that the holder device 1400 is inserted into the mounting part 65 and the clip 67 is inserted through the fixing hole 66 to the fixing bar 1430. can be bitten In addition, when the resin r is filled and cured into the fixing hole 66 , the end of the clip 67 may be embedded and fixed in the fixing hole 66 . At this time, the fixing hole 66 is penetrated so as to have an inner circumference wider than the cross-sectional area of the clip 67 , and the clip 67 is attached to the clip holder and can be introduced into the fixing hole 66 .

The resin (r) is preferably provided with the same material used to manufacture the artificial gum portion (62). Therefore, when the resin r is filled in the fixing hole 66 and then cured, the fixing force can be improved through high adhesion between the same materials. In addition, the outer surface of the end of the clip 67 may be treated with fine irregularities. Accordingly, as the contact area with the resin r increases, the adhesive force may further increase. Here, it is preferable that a rubber dam covering the surface of the gum tissue is covered to prevent the resin r from flowing toward the gum tissue before it is cured.

On the other hand, terms such as "comprises", "comprises", "provide" or "have" described above mean that the corresponding component may be inherent, unless otherwise stated. It should be construed as not excluding components, but may further include other components. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs, unless otherwise defined. Terms commonly used, such as those defined in the dictionary, should be interpreted as being consistent with the contextual meaning of the related art, and are not interpreted in an ideal or excessively formal meaning unless explicitly defined in the present invention.

As described above, the present invention is not limited to each of the above-described embodiments, and variations can be implemented by those of ordinary skill in the art to which the present invention pertains without departing from the scope of the claims of the present invention. and such modifications are within the scope of the present invention.

M: Planning image m2: Gum image to be restored
m3: contralateral image m14: virtual abutment
m30: erasing model m40: virtual holder device
m51: virtual placement guide sleeve 40: flattening guide
50: surgical guide 60: overdenture
1400: holder device 1410: holder abutment
1430: fixed bar E: virtual flat surface

Claims (10)

A three-dimensional planning image is generated by superimposing a CT image of a scanning image including three-dimensional external information of the upper and lower jaws whose at least one side is the restoration target gum, and the three-dimensional planning image contains a plurality of implant placement information along the dental arch. A first step of designing and manufacturing an implanting guide device that is set to and guides an instrument for alveolar bone planarization and implant placement;
Guided by the implanting guide device, the alveolar bone is flattened and the implant is implanted, the holder device comprising a holder abutment and a fixing bar fixed to the via insertion part of the holder abutment is fixed to the upper side of the implant. Step 2;
The temporary dentures are occluded between the upper and lower jaws so that the temporary mounting part into which the holder device is inserted is formed on the inner part of the temporary denture softened during heating to a preset softening temperature range so as to be deformed in response to the patient's vertical height through occlusal pressure. a third step to be corrected;
A fourth step in which a corrected scanning image is obtained from the corrected scanning image of the temporary denture so that the 3D external information of the temporary mounting unit is exposed to the outside, the 3D external information of the temporary mounting unit is replaced with a virtual holder device ; and
Dental restoration implanting comprising a fifth step in which a mounting part is formed on the inner surface based on the virtual holder device, and the artificial tooth part is fixed to an artificial gum part to which a clip engaged with the fixing bar is fixed to produce a final dental restoration. Way. The method of claim 1,
In the first step, a virtual implantation guide sleeve in which a virtual implant selected from a digital library based on the CT image is virtually placed corresponding to the implantation information and spaced apart from the upper end of the virtual implant to be virtually placed concentrically is the scanning image A step that is nested and integrated and stored in
Extracting one erased model matching the restoration target gum part from among the erased models stored in a plurality of standardized to a semi-cylindrical shape corresponding to the anatomical dentition in the digital library;
Virtually adjusting the extracted erasing model to correspond to a second reference plane spaced downward by a preset clearance distance from the first reference plane corresponding to the upper end of the virtual implant, at least one surface of which is virtually placed based on the occlusal plane of the upper and lower jaws; ,
and the step of forming a virtual flat surface by erasing an overlapping portion with the erasing model from the three-dimensional external information of the restoration target gum portion. 3. The method of claim 2,
In the first step, the implanting guide device
Flattening designed and three-dimensionally printed, including the step of forming an inner contour based on the three-dimensional external information of the restoration target gum part, and forming a flat guide surface along an edge that is opened at a position corresponding to the virtual flat surface Dental restoration implanting method comprising a guide. 4. The method of claim 3,
In the first step, the implanting guide device
The inner contour is formed based on the outer contour of the flattening guide, and a virtual coupling hole corresponding to the outer periphery of the virtual implantation guide sleeve is formed at the upper end, including a surgical guide designed and three-dimensionally printed. Dental restoration implanting method, characterized in that 3. The method of claim 2,
In the first step, the implanting guide device
An inner contour is formed based on the three-dimensional external information and the virtual flat surface of the restoration target gum part, and a virtual coupling hole corresponding to the outer periphery of the virtual implantation guide sleeve is formed at the upper end. Dental restoration implanting method comprising a surgical guide. 3. The method of claim 2,
In the first step, the implanting guide device
The step of setting a virtual guide body part in which an inner contour is formed based on the three-dimensional external information of the restoration target gum part and a virtual coupling hole corresponding to the outer periphery of the virtual implantation guide sleeve is formed;
Virtually disposing a plurality of three-dimensional virtual cutout blocks with one surface matching the first reference surface and the other surface having a thickness matching the second reference surface matching the circumference of the guide body;
The virtual incision block and the virtual guide body portion overlapping area are erased to form a cutout slot hole, designed and manufactured as a pair, at least one of the pair is divided along the cutout slot hole to form a lower first body Dental restoration implanting method, characterized in that it comprises a surgical guide formed as an additional flattening guide. The method of claim 1,
The first step includes the step of setting the placement information of the implant corresponding to the anterior and posterior implantation points via the bending path information and the bending path information of the fixed bar in which both ends are bent at a preset angle. and
The second step is
Preparing a fixing jig base in which an alignment protrusion into which the light oil insertion part is fitted is formed in an inner periphery of a receiving groove so as to be interlocked with the holder abutment, and a pivot guide jig base rotatably supported by the holder abutment;
A pair of the holder abutments disposed corresponding to the anterior implantation point are aligned so that the light oil insertion part communicates in a straight line through the pair of fixing jig bases and fixed to the anterior side;
The jig base for the pivot guide is alternately coupled to the holder abutment fixed to the anterior side, and the fixing jig base is coupled to the upper end of the holder abutment disposed in correspondence to the adjacent posterior implantation point;
Dental restoration implanting comprising the step of fixing the holder abutment supported on the fixing jig base rotated and constrained to communicate in a straight line with the alignment groove of the pivot guide jig base on the posterior side Way. 8. The method of claim 7,
The second step is
Recombining the fixing jig base to each upper end of the holder abutment fixed to the anterior side and the posterior side and integrally connecting through a curable resin;
A step of inserting a holder analog in which an angle alignment part corresponding to the light oil insertion part is formed in each of the receiving grooves is inserted and integrally connected through a curable material;
and a fixing bar bent in response to the bending path information is simultaneously inserted into each of the angle alignment units of the analog holder connected integrally to determine and correct a bending error. The method of claim 1,
The fifth step is
The step of being in communication with the mounting portion and mounting the artificial gum portion through which a fixing hole through which the end of the clip is fixed is formed in the oral cavity to which the holder device is mounted;
and the end of the clip fixed to the fixing bar is embedded in the fixing hole through a resin that is filled and cured, and the clip is fixed to the artificial gum portion. The method of claim 1,
In the first step, a virtual base gum part whose inner contour corresponds to the three-dimensional external information of the restoration target gum part is virtually disposed, and the cross-overlapping part of the virtual tooth exceeding the vertical height and the virtual base gum part is an erased area A virtual mating surface is set along the inner periphery where the erased area is erased, and a cutting guide including a cutting hole formed through the virtual mating surface corresponding to the virtual mating surface and a coupling groove corresponding to the virtual mating surface are included. Including the step of designing and manufacturing the artificial gum part,
The fifth step is a step in which one side of the outer periphery of the artificial tooth part is engaged with the inner peripheral surface of each of the cutting holes of the cutting guide, and the inner surface of the cutting guide so that the height of the artificial tooth part is corrected corresponding to the vertical height. Dental restoration implanting method, characterized in that it comprises the step of calibrating the apical end of the artificial tooth protruding to the side based on the inner edge of the cutting hole.

Images