WO2023074005A1 - 歯科治療用のオステオトーム、穴形成器具、テストポスト、ストッパーエクステンション、歯根膜ガード、水流チューブ、歯科治療計画の手技前検証用の模型 - Google Patents
歯科治療用のオステオトーム、穴形成器具、テストポスト、ストッパーエクステンション、歯根膜ガード、水流チューブ、歯科治療計画の手技前検証用の模型 Download PDFInfo
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- WO2023074005A1 WO2023074005A1 PCT/JP2021/041362 JP2021041362W WO2023074005A1 WO 2023074005 A1 WO2023074005 A1 WO 2023074005A1 JP 2021041362 W JP2021041362 W JP 2021041362W WO 2023074005 A1 WO2023074005 A1 WO 2023074005A1
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- patient
- hole
- treatment
- dentist
- osteotome
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Classifications
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- A61C—DENTISTRY; APPARATUS OR METHODS FOR ORAL OR DENTAL HYGIENE
- A61C1/00—Dental machines for boring or cutting ; General features of dental machines or apparatus, e.g. hand-piece design
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61C—DENTISTRY; APPARATUS OR METHODS FOR ORAL OR DENTAL HYGIENE
- A61C8/00—Means to be fixed to the jaw-bone for consolidating natural teeth or for fixing dental prostheses thereon; Dental implants; Implanting tools
- A61C8/0089—Implanting tools or instruments
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61C—DENTISTRY; APPARATUS OR METHODS FOR ORAL OR DENTAL HYGIENE
- A61C1/00—Dental machines for boring or cutting ; General features of dental machines or apparatus, e.g. hand-piece design
- A61C1/08—Machine parts specially adapted for dentistry
- A61C1/082—Positioning or guiding, e.g. of drills
- A61C1/084—Positioning or guiding, e.g. of drills of implanting tools
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- A61C—DENTISTRY; APPARATUS OR METHODS FOR ORAL OR DENTAL HYGIENE
- A61C8/00—Means to be fixed to the jaw-bone for consolidating natural teeth or for fixing dental prostheses thereon; Dental implants; Implanting tools
- A61C8/0003—Not used, see subgroups
- A61C8/0004—Consolidating natural teeth
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61C—DENTISTRY; APPARATUS OR METHODS FOR ORAL OR DENTAL HYGIENE
- A61C8/00—Means to be fixed to the jaw-bone for consolidating natural teeth or for fixing dental prostheses thereon; Dental implants; Implanting tools
- A61C8/0089—Implanting tools or instruments
- A61C8/0092—Implanting tools or instruments for sinus lifting
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61C—DENTISTRY; APPARATUS OR METHODS FOR ORAL OR DENTAL HYGIENE
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- G—PHYSICS
- G16—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
- G16H—HEALTHCARE INFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR THE HANDLING OR PROCESSING OF MEDICAL OR HEALTHCARE DATA
- G16H50/00—ICT specially adapted for medical diagnosis, medical simulation or medical data mining; ICT specially adapted for detecting, monitoring or modelling epidemics or pandemics
- G16H50/50—ICT specially adapted for medical diagnosis, medical simulation or medical data mining; ICT specially adapted for detecting, monitoring or modelling epidemics or pandemics for simulation or modelling of medical disorders
Definitions
- the present invention relates to an osteotome for dental treatment, a hole forming instrument, a test post, a stopper extension, a periodontal ligament guard, a water flow tube, and a model for pre-procedural verification of a dental treatment plan.
- a dentist who is an operator, usually uses a dental CT scan to obtain three-dimensional image data of the upper and/or lower jaw, including the patient's treatment position. Based on the three-dimensional image data, in addition to the treatment position, the dentist determines the position of the patient's maxillary maxillary sinus, the posterior superior alveolar artery, and the greater palatine artery, or the patient's mandibular inferior alveolar artery and Determine the position of the inferior alveolar nerve before the procedure.
- the dentist uses the tip of a hole forming instrument such as a drill as a predetermined non-reachable (non-contact) target for the patient's maxillary sinus mucosa, posterior superior alveolar artery, Also, perform the procedure so as not to reach the greater palatine artery.
- the dentist performs the procedure so that the tip of a hole forming instrument such as a drill does not reach the patient's inferior alveolar artery and inferior alveolar nerve as a predetermined non-reachable target.
- a surgical guide that guides a drill is sometimes used to form a hollow hole in the bone according to the treatment plan.
- a surgical guide is formed based on three-dimensional image data of the patient's upper and/or lower jaw. Surgical guides are used by fitting over the patient's teeth and gums. The surgical guide enables a dentist to form a hole for burying an implant body with the position, direction, diameter, etc. of the hole according to the treatment plan.
- a risk in implant therapy is the inability to visualize the location of non-reachable targets such as arteries and nerves during the procedure.
- implant treatment planning (including surgical guide creation) is prepared by the manufacturer's technician using the patient's CT image data (DICOM data) acquired by the dentist, for example, using the implant manufacturer's system. I have a lot to do.
- the dentist reviews the treatment plan prepared by the manufacturer's technician.
- the dentist is not on site when the treatment plan is created, and the tools available to the dentist are limited when modifying the treatment plan created by the manufacturer. Since the target is three-dimensional, the dentist's intention is to provide detailed instructions for the treatment plan, such as selection of the implant body, slight adjustment of the inner diameter, position, angle, etc.
- a surgical instrument such as a hole forming instrument
- the position of the tip of the surgical instrument when using the surgical instrument, the position of the patient's maxillary maxillary sinus mucosa, posterior superior alveolar artery, and greater palatine artery, or the position of the mandibular inferior alveolar artery and inferior alveolar nerve A pre-procedure verification system for dental treatment plans, a pre-procedure verification program for dental treatment plans, and a model for pre-procedure verification of dental treatment plans that enables the dentist who is the operator to verify the positional relationship with the unreachable target position in advance.
- the dentist himself confirms the design, equipment selection, and treatment plan safety, and realizes the best treatment plan. aim.
- the present disclosure provides osteotomes, hole forming instruments, test posts, and stoppers for dental treatment corresponding to these problems.
- the purpose is to provide extensions, periodontal ligament guards, water flow tubes, and models for preprocedural verification of dental treatment plans.
- the osteotome according to one aspect of the present invention is implanted from the surface to the deep part of the treatment site of the patient's jaw, and when the bone is expanded or compressed so as to displace the position of the mucous membrane behind the treatment site.
- the end diameter of the osteotome as described above may be larger than the end diameter of the osteotome dedicated to implants.
- the diameter of the end of the osteotome as described above may be 5 mm or more.
- the osteotome as described above is provided according to the surface shape of the treatment site of the patient, and is guided along a guide hole formed in a surgical guide that offsets a predetermined amount from a reference position that serves as a guideline for depth during treatment.
- the portion to be guided may be formed in a part of the body portion.
- Another aspect of the present invention is implanted from the proximal side to the distal side with respect to the treatment site of the patient's jaw, and spreads or spreads the bone so as to displace the position of the mucous membrane behind the treatment site.
- An osteotome used as an instrument for applying impact when compressing a body portion serving as the main body portion of the osteotome; an end formed at the tip of the body for displacing the position of the mucous membrane;
- a guided portion guided along a guide hole provided in a surgical guide that is formed according to the surface shape of the treatment site of the patient and offsets the reference position, which is a guideline for the height during treatment, by a predetermined amount. is formed in part of the body, an osteotome.
- One aspect of the present invention is a hole forming instrument having a drill for forming a hole for embedding a portion of an implanted body by advancing from the superficial layer to the deep part of the treatment site of the patient's jaw, wherein the diameter of the drill is is a hole preparation device that is sized appropriately for implanting a home-grown tooth.
- the drill diameter of the hole forming instrument as described above may be larger than the diameter of the drill when the embedded body is an implant body.
- the above-mentioned hole forming instrument may have a drill diameter of 5 mm or more.
- the hole forming instrument as described above is formed according to the surface shape of the treatment site of the patient, and is guided along the guide hole provided in the surgical guide that offsets the reference position, which serves as a guideline for the height during treatment, by a predetermined amount.
- the portion to be guided may be formed in a part of the hole forming instrument.
- One aspect of the present invention is a hole made of a resin material or a ceramic material and formed to embed a part of the implant in the treatment area of the patient's jaw, or a hole that conforms to the surface shape of the patient's treatment area. It is inserted into a guide hole formed in a surgical guide that offsets the reference position, which is a guideline for depth during treatment, by a predetermined amount, and is imaged in a radiographic image taken in that state.
- a diagnostic imaging test post that indicates the location of a hole or guide hole.
- the test post as described above may have a stepped shape.
- the test post as described above may have an outer diameter that is larger than the inner diameter of the guide hole of the surgical guide.
- the surgical guide is inserted into a guide hole formed in a surgical guide that is provided according to the surface shape of the treatment site of the patient and offsets a reference position that serves as a guideline for depth during treatment by a predetermined amount. It is a cylindrically formed stopper extension that extends the length.
- the stopper extension as described above may have a stepped shape.
- the stopper extension as described above may have an outer diameter that is larger than the inner diameter of the guide hole of the surgical guide.
- One aspect of the present invention is to cover a part or all of a portion of a home-made tooth to be transplanted, excluding a tooth root to be cut, and to apply it to the periodontal ligament around the root when cutting the tooth root. It is a periodontal ligament guard that reduces damage caused by a certain external factor.
- the periodontal ligament guard as described above may be made of a low-resilience material.
- the periodontal ligament guard as described above may be made of silicon.
- One aspect of the present invention is a water flow tube that is implanted from the surface to the deep part of a treatment site of a patient's jaw and ejects water from the distal end toward the position of the mucous membrane behind the treatment site,
- This is a water flow tube for implantation, the diameter of the tip of which is suitable for implanting a home-made tooth.
- a stepped portion may be formed at the distal end of the water flow tube as described above, the outer diameter of which gradually increases from the distal end to the proximal end.
- Another aspect of the present invention is formed based on a three-dimensional stereoscopic image of a patient's jaw, and has the same size and width as at least a part of the patient's teeth, gums, and alveolar bone covered by the gums to be treated.
- a model body having the same shape and simulating at least a part of a patient's teeth, gums, and alveolar bone to be treated;
- a non-contact target that is formed based on a three-dimensional stereoscopic image of a patient, is adjacent to or embedded in the alveolar bone to be treated of the patient, and is selected from a plurality of non-contact targets during treatment, the tip of which is to be non-contact with the patient.
- a target model part provided on the model main body in the same positional relationship as the positional relationship between the teeth, gums, and alveolar bone to be treated and the non-contact target; Based on a three-dimensional stereoscopic image of the patient, a hole in which the body to be treated can be embedded is formed at a position imitating the gums and alveolar bone of the patient to be treated in the model body.
- a dentist to visually recognize the positional relationship between a surgical instrument and a target when the surgical instrument in the three-dimensional stereoscopic image is fitted into the hole in the image and the surgical instrument is inserted into the hole in the three-dimensional stereoscopic image.
- the hole, and with This is a model for pre-procedural verification of a dental treatment plan, in which a fluid is built in to notify the contact when a surgical instrument comes into contact with the target model during pre-procedural verification.
- fluid for example, colored liquid
- the target model is It is possible to easily visually recognize that there has been contact with the part.
- FIG. 1 is a block diagram of a dental treatment plan preliminary verification system according to the first embodiment and the second embodiment;
- FIG. The schematic which shows an example of an implant body. Schematic diagram showing an example of a hole forming instrument. Schematic diagram showing a model for preliminary verification of a dental treatment plan according to the first embodiment.
- FIG. 4B is a schematic diagram showing the model viewed from a direction different from that of FIG. 4A;
- FIG. 4 is a schematic diagram showing a model for preliminary verification of a dental treatment plan according to a modified example of the first embodiment; Schematic which shows the surgical guide which concerns on 1st Embodiment.
- a flowchart showing a treatment plan for implant treatment. 7 is a flowchart showing a treatment plan for implant treatment following FIG. 6;
- FIG. 10 is a diagram showing a state in which third three-dimensional image data in which the positions of non-reachable targets are marked are superimposed on the first three-dimensional image data showing the inferior alveolar bone; A diagram showing a state in which fourth three-dimensional image data of the implant body is further superimposed on FIG. 8 .
- FIG. 9 is a diagram showing a state in which second three-dimensional image data of teeth and gums and fifth three-dimensional image data of a hole forming instrument are superimposed on FIG. 9 ; The figure which shows the 6th three-dimensional image data of a surgical guide. Schematic diagram showing gums, teeth, mandibular alveolar bone, implant bodies, and non-reachable targets with a surgical guide attached to the mandible.
- FIG. 16 Schematic showing gums, teeth, mandibular alveolar bone, hole preparation instrument, non-reachable target with surgical guide attached to mandible.
- FIG. 11 is a schematic diagram showing a gum, tooth, lower alveolar bone, hole forming instrument including a handle, and a non-reachable target, with a surgical guide attached to the lower jaw, according to a first modification; According to the second modification, third three-dimensional image data obtained by marking the position of the non-reachable target with respect to the first three-dimensional image data showing the inferior alveolar bone, fourth three-dimensional image data of the autologous tooth, and The figure which shows the state which superimposed the 5th three-dimensional image data of a hole formation tool.
- the first three-dimensional image data showing the maxillary superior alveolar bone, the maxillary sinus, the posterior superior alveolar artery and the greater palatine artery, the fourth three-dimensional image data of the implant body and the hole forming instrument The figure which shows the state which superimposed the 5th three-dimensional image data.
- FIG. 23 is a diagram showing a state in which the sixth three-dimensional image data is superimposed on the diagram shown in FIG.
- FIG. 22 shows 1st three-dimensional image data, 2nd three-dimensional image data, 3rd three-dimensional image data, 4th three-dimensional image data, and some surface image data of 5th three-dimensional image data are shown.
- figure. The figure which shows the surface image which superimposed the surface image data shown in FIG. 24, and subtracted the 4th three-dimensional image data and the 5th three-dimensional image data.
- 26 shows different views of the upper jaw shown in FIG. 25;
- FIG. 27 is a schematic diagram showing the positional relationship between the tooth and the maxillary sinus when performing the procedure of burying the implant body in the maxilla, following FIG. 27 ; A diagram showing a state in which the maxillary sinus mucosa of the maxillary sinus is superimposed on the second three-dimensional image data in FIG. 22 . It is a figure which shows an example of the osteotome in 3rd Embodiment. It is a figure which expands and shows a part of osteotome.
- FIG. 4 is a partially enlarged view of the osteotome with the bar portion shifted to the proximal side.
- FIG. 30B is a cross-sectional view taken along line XXXI-XXXI in FIG. 30B; FIG.
- FIG. 4 is a diagram showing an example of a bar portion with a large end diameter
- FIG. 10 is a diagram showing a state in which the surgical guide is fitted to teeth and gums near the treatment site of the patient's jaw. It is a figure which shows a mode that a recessed hole is formed in a treatment location with a hole forming instrument. It is a figure which shows the state after forming a recessed hole and pulling out a hole forming tool.
- FIG. 10 is a diagram showing how a hole forming instrument with a large diameter forms a larger recessed hole in a treatment site.
- FIG. 10 shows the state after forming a larger recess and then removing the hole forming tool.
- FIG. 10 shows a diagram showing a state in which the surgical guide is fitted to teeth and gums near the treatment site of the patient's jaw. It is a figure which shows a mode that a recessed hole is formed in a treatment location with a hole forming instrument. It is a figure which shows the state after
- FIG. 10 is a diagram showing a state in which the surgical guide is fitted again and the osteotome is inserted into the guide hole of the surgical guide.
- FIG. 10 is a diagram showing how the end of the osteotome is embedded in the surface layer of a large pit formed in the treatment area, and the position of the mucous membrane behind the treatment area is displaced.
- FIG. 10 is a diagram showing a state after displacing the mucous membrane and removing the osteotome and the surgical guide;
- FIG. 4 is a diagram showing a state in which an osteotome with a large end diameter is attached together with a surgical guide.
- FIG. 10 is a diagram showing how an osteotome with a large end diameter further displaces the position of the mucous membrane behind the treatment site.
- FIG. 10 is a diagram showing a state after the position of the mucous membrane is further displaced and the osteotome and surgical guide are removed.
- FIG. 10 shows an osteotome with a larger diameter end mounted with a surgical guide.
- FIG. 10 is a diagram showing how an osteotome with a larger end diameter further displaces the position of the mucous membrane behind the treatment site.
- FIG. 10 is a diagram showing a state after the position of the mucous membrane is further displaced and the osteotome and surgical guide are removed.
- FIG. 10 is a diagram showing a state in which the water flow tube is attached together with the surgical guide after the position of the mucous membrane is further displaced.
- FIG. 10 is a diagram showing how the position of the mucous membrane is displaced by the water ejected from the water flow tube.
- FIG. 10 is a diagram showing a state in which the position of the mucous membrane is further displaced by water ejected from the water flow tube;
- FIG. 10 is a diagram showing a state in which a self-made tooth is implanted in the recess after the position of the mucous membrane is further displaced by water jetted from the water jet tube. It is an image showing an actual example in which the position of the buried body is misaligned. It is an image which shows an example of a test post.
- FIG. 10 is a diagram showing another example of a test post; FIG.
- FIG. 4 is a diagram showing an example of a surgical guide actually created based on image data;
- FIG. 10 shows a surgical guide with test posts attached;
- FIG. 4 is a diagram showing an example of a CT image captured by a patient wearing a surgical guide with a test post attached thereto. It is a figure which shows an example of a stopper extension.
- FIG. 10 shows the stopper extension attached to the handle and holding the shank of the hole forming tool;
- FIG. 10 is a view showing a state in which part of the stopper extension attached to the handle and holding the shank of the hole forming instrument is inserted into the guide hole of the surgical guide;
- FIG. 2 is a diagram showing, for reference, an example of a homemade tooth before being covered with a periodontal guard.
- Fig. 1 shows a self-made tooth covered by a periodontal guard;
- FIG. 10 is a diagram showing a state in which a self-made tooth covered with a periodontal guard is held between fingers.
- a system for pre-procedure verification of a dental treatment plan (a model making system for verifying a dental treatment plan after creating a dental treatment plan and before a procedure) 10 according to the embodiment acquires, for example, various data of a certain patient, implant treatment, It forms part of a series of tasks from creating a treatment plan for a patient to performing the procedure on the patient.
- This system 10 for example, acquires affected part data of a certain patient, creates a dental treatment plan for a certain patient, and outputs an actual patient model (a model for pre-procedural verification of the dental treatment plan) 100. Used when performing a series of tasks for pre-procedural verification of a dental treatment plan. Acquisition of affected part data of a certain patient and output of model 100 may be performed by another system different from this system 10 .
- a system for preprocedural verification of a dental treatment plan (hereinafter simply referred to as system) 10 includes a control device 12, a first scanner 14, a second scanner 16, a display 18, and an operation.
- a unit (instruction input unit) 20 , a storage device 22 , a 3D printer 24 and a milling machine 26 are provided.
- the control device 12 controls the first scanner 14, the second scanner 16, the display section 18, the operation section 20, the storage device 22, the 3D printer 24, and the milling machine 26.
- a computer for example, is used as the control device 12 .
- the control device 12 includes, for example, processors such as CPU and MPU, RAM, ROM, and I/O interfaces.
- processors such as CPU and MPU, RAM, ROM, and I/O interfaces.
- a processor such as one or a plurality of CPUs develops a control program stored in a memory such as a ROM into a RAM, and the display unit 18, the operation unit 20, the storage device 22, the first scanner 14, Appropriate processing for the second scanner 16, 3D printer 24, and milling machine 26 is performed.
- control device 12 is configured such that a processor such as one or a plurality of CPUs reads a program via a network, and the display unit 18, the operation unit 20, the storage device 22, the first scanner 14, the second scanner 16, and the 3D scanner. Appropriate processing for printer 24 and milling machine 26 is performed.
- the control device 12 implements the function of controlling each part and performing processing such as image processing by means of software by having the processor read and execute a program stored in advance in the memory.
- the first scanner 14 is, for example, a dental CT scan.
- the first scanner 14 acquires three-dimensional image data (for example, DICOM data) of, for example, teeth, bones, and bone interiors of the patient's mandible, and outputs the data to the control device 12 .
- the control device 12 causes the storage device 22 to store the three-dimensional image data of the patient's mandibular teeth, bones, and bone interiors.
- the second scanner 16 is, for example, an intraoral scanner.
- the second scanner 16 acquires three-dimensional image data (for example, STL data) of the surface of the patient's mandibular teeth and gums, for example, and outputs the data to the control device 12 .
- the control device 12 causes the storage device 22 to store three-dimensional image data of the surface of the patient's mandibular teeth and gums.
- the display unit 18 is, for example, various displays such as a liquid crystal display and an organic EL display.
- the display unit 18 displays images related to the patient acquired by the first scanner 14 and the second scanner 16 and output to the control device 12, as well as various types of information.
- the control device 12 may read the three-dimensional image data of the patient stored in the storage device 22 and display it on the display section 18 .
- the operation unit 20 inputs instructions to the control device 12 .
- the operation unit 20 includes devices such as a keyboard and a mouse.
- the storage device 22 stores various data of the patient (e.g., three-dimensional image data (DICOM data) of the mandibular teeth, bones, and bone interiors, and three-dimensional image data of the surface of the patient's mandibular teeth and gums (e.g., STL data). )).
- the storage device 22 stores, for example, various three-dimensional image data (implant body data) 22a of the implant body 30 shown in FIG. data) 22b.
- control device 12 When the control device 12 reads various three-dimensional image data 22a of the implant body 30 and various three-dimensional image data 22b of the hole forming tool 40 via the network, various three-dimensional image data of the implant body 30 are stored in the storage device 22. 22a, storing various three-dimensional image data 22b of the hole forming tool 40 may not be necessary. That is, instead of the storage device 22, the control device 12 may use, for example, a database (implant body data 22a and hole forming instrument set data 22b) on a server. The control device 12 can read various data from the server.
- a database implant body data 22a and hole forming instrument set data 22b
- the actual hole forming tool 40 has, for example, a body 42 for boring, a shank 44 , a sleeve 46 and a stopper 48 .
- the body 42 and shank 44 are integrated, such as integrally molded.
- the shank 44 is fixed to a handpiece (not shown). Therefore, the body 42 and the shank 44 rotate about the predetermined rotation axis.
- the sleeve 46 covers the outside of the body 42 and fits or engages with a guide hole (through hole) 210 of an auxiliary instrument 200 such as a surgical guide, which will be described later.
- An end surface 48a of the stopper 48 on the body 42 side abuts on a defining surface 220 defining the guide hole 210 of the auxiliary tool 200, for example, in a state where the distance from the handpiece is defined.
- the 3D printer 24 forms a model 100 for preliminary verification of dental treatment, shown in FIGS. 4A and 4B, based on the 3D image data of the patient's lower jaw and the 3D image data created by the dentist.
- the 3D printer 24 is preferably owned by, for example, a dentist and operated by the dentist. can be output.
- the model 100 has a model main body 110 , a target model portion 120 and a hole portion 130 .
- the model body 110 is shaped to have the same size and shape as the actual treatment target region of the patient's mandible and its surroundings.
- the model main body 110 and the target model part 120 are formed in the same positional relationship as the positional relationship between the actual treatment target region of the patient's lower jaw and the target (non-contact target or contact target).
- the same positional relationship means that the area related to the procedure of the treatment target area is formed to have the same size and shape as the actual treatment target area of the patient's lower jaw and its surroundings.
- the hole 130 is defined by various parameters of the implant body 30 and the hole forming tool 40, which will be described later.
- the hole 130 is formed according to the setting of parameters relating to the shape (for example, length, outer diameter), angle, and position of the implant body 30 or hole forming tool 40 to be embedded in the hole 130 of the treatment target site.
- the model main body 110 has a defining surface 135 that forms the edge of the hole 130 .
- the defining surface 135 is the surface of the gum or inferior alveolar bone.
- the target model section 120 is preferably supported by the model main body 110.
- the model 100 further has a base portion (base) 140 that supports the target model portion 120 and is provided on the side opposite to the model main body 110 , and a strut 150 that connects the model main body 110 and the base portion 140 .
- the milling machine 26 cuts out the auxiliary instrument (surgical guide) 200 shown in FIG. 5 based on the three-dimensional image data of the patient's lower jaw and the three-dimensional image data created by the dentist.
- the milling machine 26 is preferably owned by, for example, a dentist and operated by the dentist. 200 may be output.
- the auxiliary instrument 200 that is actually used during dental treatment is made of a resin material that is medically approved and durable enough to withstand dental treatment.
- Auxiliary instruments 200 used during dental treatment may be produced by the 3D printer 24 .
- the assistive device 200 in this case is made of a medically approved material.
- the auxiliary instrument 200, which is not used during dental treatment but is used together with the model 100 for checking by the dentist, is preferably made of the same material as the model 100, for example. Since the model 100 is not used for actual treatment, it suffices if the relationship between the regulating surface 135 and the target model portion 120 is maintained, and the model 100 is made of an appropriate material with appropriate accuracy.
- the auxiliary instrument 200 is formed according to the surface shape of the treatment site of the patient.
- the auxiliary instrument 200 is used by fitting it to a tooth, gum, or jawbone near the gum of the patient to be treated with a screw after fixing.
- the auxiliary device 200 is fixed to the lower jaw while preventing rattling with the lower jaw.
- the auxiliary instrument 200 is used to form a recess set in the gum and alveolar bone, and to accurately form a recess in the body 42 of the hole-forming instrument 40 for inserting the implant body 30 set in the recess.
- the auxiliary instrument 200 has a main body 205 and a guide hole 210.
- the auxiliary instrument 200 is used by being fitted to the teeth, gums, and jawbone near the gums of the patient to be treated with screws after being fixed. It is used as a position defining part to define.
- Body 205 is shown fixed to an area of the patient's oral cavity, eg, along one or more teeth, although the patient's mandibular side may be completely edentulous.
- body 205 can be configured to connect to a smaller portion of the patient's oral cavity, such as only one or two teeth, only bone, or any combination thereof.
- the guide hole 210 defines the direction, shape (length, outer diameter) and angle of the recess formed by the body 42 of the hole forming instrument 40 when the body 205 is properly attached to the patient's mandibular teeth and gums. , position, etc.
- the auxiliary instrument 200 has a defining surface 220 that forms the edge of the guide hole 210 .
- the defining surface 220 is the surface opposite to the surface facing the gums or the inferior alveolar bone.
- the guide hole 210 of the auxiliary instrument 200 may be capable of inserting not only the hole forming instrument 40 but also other surgical instruments such as an electric scalpel for hemostasis.
- the regulation surface 220 regulates the insertion direction, angle, position, etc. of the electric scalpel. Therefore, the restricting surface 220 can be used not only as the restricting surface of the hole forming instrument 40 but also as the restricting surface of the surgical instrument. Therefore, the auxiliary instrument 200 is used as a position regulating body for the surgical instrument.
- the dentist can create the assistive device as three-dimensional image data (data representing a three-dimensional shape), and use the 3D printer 24 or the milling machine 26 to reproduce the lower jaw of the patient. It is possible to mold a real object that conforms to its shape and size.
- An image display program, an image processing program, an output program, etc. are stored in the control device 12 according to the present embodiment.
- the image display program causes the display unit 18 to display the data acquired by the first scanner 14 and the second scanner 16 .
- the image processing program superimposes the image data displayed by the image display program and various data stored in the storage device 22 based on the same coordinate axis.
- the image display program causes the display unit 18 to display the data superimposed based on the same coordinate axis using the image processing program.
- the image display program causes the display unit 18 to display three-dimensional image data created based on the intention of the dentist.
- the output program includes three-dimensional image data created based on the intention of the dentist using an image processing program, and surface data (data representing a three-dimensional shape (three-dimensional image data ), hereinafter referred to as surface data) is output.
- the output program can output surface data that causes the 3D printer 24 or milling machine 26 to model the actual object.
- the dentist uses the operation unit 20 to input various instructions to the control device 12, and creates a treatment plan for implant treatment according to the flow shown in FIGS. 6 and 7, for example.
- the dentist uses the first scanner 14 such as a dental CT scan to acquire three-dimensional image data (for example, DICOM data) of the patient's mandibular teeth, bones, and the inside of the bones, and stores them in the storage device 22 .
- first three-dimensional image data For example, DICOM data
- the dentist acquires three-dimensional image data (for example, STL data) of the surfaces of the teeth and gums using a second scanner 16 such as an intraoral scanner, and stores the data in the storage device 22 .
- second three-dimensional image data (first surface data) 52 This is referred to as second three-dimensional image data (first surface data) 52 .
- a dentist imports first three-dimensional image data and second three-dimensional image data into appropriate software (application) (step S1). Even if the data formats of the first three-dimensional image data 51 and the second three-dimensional image data 52 are different, the software can reproduce the first three-dimensional image data 51 and the second three-dimensional image data 52. Both data can be read.
- the dentist confirms, for example, the first three-dimensional image 51 based on the first three-dimensional image data on the display screen of the display unit 18, and based on various other conditions, implant treatment at the treatment site of a certain patient. Comprehensive judgment is made as to whether or not it is possible (step S2).
- the operation performed when the dentist determines that implant treatment is possible S2-Yes
- the dentist determines that the implant treatment is not possible S2-No
- step S2 acquisition of three-dimensional image data (for example, STL data) of the surface of teeth and gums using the second scanner 16 is performed in step S2. may be performed after the step of
- the dentist uses the software to create a hole 70 for embedding the implant body 30 during implant treatment in a first three-dimensional image 51 showing the bone of the mandible (lower alveolar bone).
- the inferior alveolar artery and inferior alveolar nerve are located so that the tip of the body 42 of the forming instrument 40 is a non-reachable (non-contact) target.
- the dentist marks the position of the unreachable target on the software (step S3, first processing). At this time, the dentist marks feature points of the non-reachable target so that the non-reachable target is three-dimensionally formed on the software.
- the dentist creates a non-reachable target as third three-dimensional image data (fourth surface data) 53 .
- the dentist sets or installs the shape (e.g., length, outer diameter), angle, position, etc. of the implant body simulating the implant body 30 at the treatment position on the software (step S4 ).
- Installation refers to importing into the system 10, for example, three-dimensional data acquired by a dentist using a 3D scanner or the like.
- the angle of the implant body refers to, for example, the installation orientation relative to the patient's treatment position.
- the implant body As for the implant body, three-dimensional image data including information on the same shape and the same size as the implant body 30 actually medically approved, corresponding to the implant body on a one-to-one basis, is used.
- the dentist considers the relationship between the abutment attached to the implant body 30 and the shape of the upper structure (crown).
- the dentist selects one implant that matches the settings from the three-dimensional image data 22a of the implant stored in the storage device 22, for example.
- the fourth three-dimensional image data (second surface data) 54 of the implant body selected by the dentist is provided by the manufacturer of the implant body 30, for example.
- the dentist may create the fourth three-dimensional image data 54 of the implant body by himself if it is not provided by the manufacturer of the implant body 30 .
- the control device 12 causes the storage device 22 to store the fourth three-dimensional image data 54 of the implant created by the dentist.
- the dentist can select the implant body 30 by himself/herself and optimally set the angle, position, etc. of the implant body 30 with respect to the mandibular bone according to the patient. At this time, the dentist can reselect the implant body and easily test the suitability of the implant body with different lengths and outer diameters for the treatment object of the patient.
- the dentist selects the depth, diameter, angle, and position of the recessed hole 70 for embedding the selected implant body from one or more manufacturer's drill sets used for patient treatment.
- Select the appropriate hole forming tool (second process).
- the hole forming tool three-dimensional image data including information on the same shape and the same size as the hole forming tool 40 which is actually medically approved and corresponds to the hole forming tool one-to-one is used.
- the dentist will typically select the hole forming tool 40 recommended by the manufacturer of the implant body 30 selected, although other hole forming tools 40 may be used.
- the dentist selects one hole forming tool 40 that matches the setting contents from the three-dimensional image data 22b of the hole forming tool imitating the hole forming tool 40 stored in the storage device 22 .
- the fifth three-dimensional image data (third surface data) 55 of the hole forming instrument 40 selected by the dentist is provided by the manufacturer of the hole forming instrument 40, for example.
- the dentist may create the fifth three-dimensional image data 55 by himself if it is not provided by the manufacturer of the hole forming instrument 40 .
- the control device 12 causes the storage device 22 to store the fifth three-dimensional image data 55 created by the dentist.
- the diameter of the hole 130 formed by the actual hole forming tool 40 is slightly smaller than the outer diameter of the actual implant body 30 .
- This relationship is the same as the relationship on software.
- the difference in outer diameter between the hole forming instrument and the implant body can be appropriately set by the dentist inputting it into the operation unit 20 as a parameter.
- the dentist aligns the coordinate axes of the first to fifth three-dimensional image data 51-55 on the software, the first three-dimensional image data 51, the third three-dimensional image data 53, and the fourth three-dimensional image data
- the second three-dimensional image data 52 is superimposed on the dimensional image data 54 and/or the fifth three-dimensional image data 55 on a predetermined coordinate system whose coordinate axes are aligned (step S5). Therefore, as shown in FIG. 10, the dentist uses software to clearly indicate the positional relationship between the surfaces of the teeth and gums of the mandible and the arteries and nerves inside the alveolar bone on the display unit 18 .
- the dentist creates three-dimensional image data of the auxiliary instrument (surgical template) according to the shape of the patient's lower jaw on the software displayed on the display unit 18 (step S6). That is, the dentist creates an auxiliary instrument as the sixth three-dimensional image 56 .
- the auxiliary instrument 200 shown in FIG. 5 guides the body 42 of the hole forming instrument 40 at the treatment site and covers the gums.
- the dentist outputs three-dimensional image data (for example, STL data) of the auxiliary instrument 200 for the 3D printer 24 or the milling machine 26, and prints the auxiliary instrument 200 with the 3D printer 24 or the milling machine 26. shape.
- This auxiliary tool 200 can be fitted or engaged with a model 100 (see FIGS. 4A and 4B) produced by the 3D printer 24 .
- the resin material used for the auxiliary instrument 200 differs depending on whether or not the auxiliary instrument 200 is actually used during treatment. When a resin material approved for medical use is used as the auxiliary instrument 200, this auxiliary instrument 200 can be used as it is.
- the auxiliary instrument 200 confirms that the tip of the hole forming tool 40 is placed at a predetermined position and does not come into contact with the target model part 120 when it is fitted with the model 100. It is used to verify the created treatment plan before the procedure.
- the dentist cannot confirm how many millimeters are dug from the surface of the alveolar bone (not the alveolar bone) at the time of forming the concave hole in the treatment target site of the patient.
- the dolphin and the distance from the surface of the alveolar bone to the artery can be confirmed in advance using tools that are actually used.
- FIG. 12 and 13 show schematic representations of a mandible 310 including alveolar bone 312, teeth 314, gums 316, pits 318, and unreachable targets 320 of the inferior alveolar artery and inferior alveolar nerve.
- a recess 318 is formed in the lower alveolar bone 312 and the gum 316 using the auxiliary instrument 200 and the hole forming instrument 40 .
- the recess 318 has a distance D1 from the top of the inferior alveolar bone 312 to the bottom of the recess 318, and a distance (offset value) D2 from the top (prescribed surface) 335 of the inferior alveolar bone 312 to the prescribed surface 220 of the auxiliary instrument 200.
- the depth is the sum of That is, the depth of the recess 318 is offset from the top of the inferior alveolar bone 312 to the defining surface 220 of the sub-instrument 200 when the sub-instrument 200 is used.
- the hole forming tool 40 and the implant body 30 are each selected such that the length D1 of the body 30 + (the offset value D2 when using the auxiliary tool 200).
- the dentist forms the recess 318 so that the bottom of the recess 318 or the bottom of the implant body 30 and the unreachable target 320 are separated from each other, and embeds the implant body 30 in the recess 318 .
- the dentist uses the shape (e.g., outer diameter), position, and angle of the implant body 30 or the inner diameter, position, and angle of the concave hole 70 as parameters, and appropriately manipulates the parameters H1, H2, D1, and D2 described above. Input using the unit 20, and create an optimal treatment plan while checking the condition of the patient's treatment target site. Setting or installing the parameters H1, H2 involves the dentist selecting the most suitable hole forming instrument 40 .
- the dentist provides a first three-dimensional image 51 of the mandibular bone, a second three-dimensional image 52 of the tooth and gum surfaces, and a third three-dimensional image 53 of the unreachable target.
- the fourth three-dimensional image 54 of the implant body and/or the fifth three-dimensional image 55 of the hole forming tool and the sixth three-dimensional image 56 of the auxiliary tool are superimposed on a predetermined coordinate system (step S7, fifth process).
- the dentist displays the sixth three-dimensional image 56, the fourth three-dimensional image 54 or the fifth three-dimensional image 55, and the third three-dimensional image on the display unit 18. 53 is confirmed.
- steps S3 to S7 are processed using an image processing program and displayed on the display unit 18 using an image display program.
- the dentist models the auxiliary instrument 200 with the 3D printer 24 or the milling machine 26 (step S8).
- the dentist confirms whether there are any corrections to the treatment plan on the software. If there is a problem, fix it. If there is no problem, the second three-dimensional image data 52, the third three-dimensional image data 53, the fourth three-dimensional image data 54, and the fifth three-dimensional image data 55 shown in FIG. superimposed on top (step S9). At this time, the second three-dimensional image data 52, the third three-dimensional image data 53, the fourth three-dimensional image data 54, and the fifth three-dimensional image data 55 are transferred to predetermined coordinates by the software for creating the treatment plan. Superimposed on the system.
- the dentist imports these three-dimensional image data into, for example, 3D CAD software, which is separate from the software that creates the treatment plan, if the data is still compatible, and superimposes these three-dimensional image data good too.
- 3D CAD software which is separate from the software that creates the treatment plan, if the data is still compatible, and superimposes these three-dimensional image data good too.
- the fifth three-dimensional image data 55 of the hole forming tool only the image of the sleeve (guide tube) (fifth three-dimensional image data 55a regarding the sleeve), for example, is imported, excluding the body and shank.
- the dentist removes the fourth three-dimensional image data 54 regarding the implant body and the fifth three-dimensional image data 55a regarding the sleeve in the software (step S10, third processing). . That is, the three-dimensional image data 110a of the model body 110 having the through holes 130 simulating the recesses for burying the teeth and the implant body, and the three-dimensional image data of the target model section 120 for the 3D printer 24 on the software. Three-dimensional image data (fifth surface data) 100a of the model 100 including 120a is created.
- Steps S9 to S10 are processed using an image processing program and displayed on the display unit 18 using an image display program.
- a model 100 (see FIGS. 4A and 4B) of the treatment site of the patient, including the target model portion 120 simulating the gums and the inferior alveolar artery having a through hole 130 simulating 70 (step S11, fourth processing) ).
- the dentist once ends the treatment plan creation process using the system 10 .
- the operation unit 20 of the system 10 described above provides a processing instruction to the control device 12 to identify the patient's treatment target site and the non-reachable target in the patient's three-dimensional stereoscopic image data, and the patient's three-dimensional image data.
- the 3D image data set various parameters of the implant body to be embedded in the treatment target site or install data acquired by the dentist using a 3D scanner or the like to imitate the recess for embedding the implant body.
- a processing instruction for setting a hole is issued.
- the operation unit 20 instructs the control device 12 to transfer the first surface data (data relating to the surface image), the second surface data or the third surface data, and the fourth surface data to a predetermined coordinate system.
- a processing instruction is input for creating fifth surface data indicating the positional relationship between the . That is, the operation unit 20 instructs the controller 12 to superimpose the first surface data, at least one of the second surface data and the third surface data, and the fourth surface data on a predetermined coordinate system.
- Processing instruction (coordinate transformation instruction) to be combined and subtracting the second surface data and the third surface data from the first surface data, and the positional relationship between the treatment target site including the hole and the fourth surface data is input, and the controller 12 processes them. If the second surface data is not used for the coordinate conversion instruction, it is not necessary to draw the second surface data when creating the fifth surface data. If the third surface data is not used for the coordinate conversion instruction, there is no need to draw the third surface data when creating the fifth surface data.
- the dentist fits, for example, an auxiliary tool 200 to the model 100 formed by the 3D printer 24, as shown in FIG.
- the dentist also inserts the body 42 of the hole forming instrument 40 into the guide hole 210 of the auxiliary instrument 200 .
- hole forming instrument 40 uses sleeve 46 and stopper 48 .
- the dentist visually confirms the positional relationship between the tip of the body 42 of the hole forming instrument 40 and the target model section 120 .
- the body 42 of the hole forming device 40 forms a recess for embedding the implant body 30. It is confirmed whether the body 42 of the hole forming instrument 40 faces the desired direction and whether the tip of the body 42 is kept away from the target model part 120 such as arteries and nerves when it is inserted into the through hole 130. .
- the tip of the hole forming instrument 40 be separated from the inferior alveolar nerve and the inferior alveolar artery by 3 mm or more.
- the respective target models 120 of the inferior alveolar nerve and the inferior alveolar artery are made larger than the actual ones by, for example, 3 mm or more toward the regulating surface 135 so that the tip of the hole forming instrument 40 does not contact and separate.
- the positional relationship between the body 42 side end surface 48a of the stopper 48 of the hole forming device 40 and the dentist can determine whether or not the hole forming device 40 is actually used for the patient. That is, for example, a dentist can form the target model portion 120 as a reachable (contact) target.
- the dentist can use the system 10 to obtain three-dimensional images 51 and 52 of the patient and three-dimensional images 54 and 55 of the implant body and the hole forming tool to obtain the same size and shape as the actual patient.
- the model 100 it is possible to perform preliminary verification of the procedure for creating the recess in which the implant body 30 is to be embedded, using the hole forming instrument 40 that is actually used. If there is no problem in the preliminary verification, the dentist performs the procedure on the actual patient according to the treatment plan. When a problem arises in the preliminary verification, the dentist modifies the treatment plan as necessary, recreates the model 100 and the auxiliary instrument 200, and performs preliminary verification of the procedure. The dentist repeats this work until there are no problems in the preliminary verification as necessary.
- the dentist may selectively use the three-dimensional images 54 and 55 of the implant body and the hole forming instrument.
- the position, size, angle, etc. of the through hole 130 of the model body 110 are formed to the final size for fitting the implant body 30 .
- the dentist gradually increases the hole diameter from a small hole and digs deeply. Therefore, when forming a concave hole in an actual procedure, the dentist gradually changes the drill body 42 from a short one with a small diameter to one with a thicker one with a longer diameter.
- the system 10 as a treatment plan, it is possible to describe what kind of hole forming instrument the dentist uses to form a concave hole.
- a final sized recess can be set in which the body 30 can be embedded.
- the dentist can use the model 100 to perform preliminary verification of proceeding with the procedure while gradually changing from a small and short drill diameter to a large and long drill diameter. That is, by using the model 100, not only the hole forming instrument 40 to be finally used, but also various surgical instruments to be used during the formation of the concave hole can be verified in advance. Examples of the surgical instruments used during the formation of the pits include bone grafting materials, fibrin gels containing platelets separated from collected blood, or injection instruments for injecting a mixture of these into the treatment target site.
- the dentist sets various parameters such as the length of the body 42 of the hole forming instrument, the height of the stopper 48, and the offset value according to the implant body 30 to be used. Calculations are sometimes performed. If the dentist makes a mistake in any one of the parameters, there is a possibility that the wrong instrument will be used, which may lead to a medical accident.
- the dentist himself/herself confirms in advance the validity of the use of each surgical instrument until the dentist forms the pit of the final size in the actual procedure. can be verified.
- a dentist or other person who creates a treatment plan in the system 10 may make a mistake in various parameters such as the length of the body 42 of the hole forming tool 40, the height of the stopper 48, and the offset value when creating the treatment plan. could be.
- the creator of the treatment plan may overlook errors in various parameters and terminate the creation of the treatment plan.
- the dentist performs preliminary verification of the treatment plan using the model 100 and the actual hole forming instrument 40, he/she can notice various parameter setting errors in the treatment plan.
- the dentist considers how parameters such as the length of the body 42 of the hole forming instrument 40 to be used, the height of the stopper 48, and the offset value can be changed to perform the procedure successfully.
- the auxiliary instrument 200 is prepared, and the dentist prepares a recess of a predetermined size at a desired position in the lower jaw of the patient, and embeds the implant body 30 in the recess. Is going.
- the tip of the body 42 of 40 was replaced by a hole forming device of another manufacturer based on the original idea of the unreachable target. Before the procedure, there was no means for the dentist to visually and actually confirm whether or not it was reached.
- the relationship between the model body 110 including the treatment target site of the patient, the target model section 120, the auxiliary tool 200, and the hole forming tool 40 or the implant body 30 is the same as that of the model 100 and the actual hole forming.
- the instrument 40 or implant body 30 can be used for pre-procedural verification by the dentist. That is, the dentist can pre-verify the created treatment plan before the actual procedure. Therefore, the dentist can perform the actual procedure after verifying the safety of the procedure using the hole forming instrument 40 in advance.
- the dentist can determine the reachable position of the tip of the body 42 of the hole forming instrument 40 with respect to the non-reachable target in the model 100, that is, the distance between the non-reachable target and the tip of the body 42 of the hole forming instrument 40. Since the distance or contact state is grasped in advance, the time spent by the dentist on the procedure can be shortened. Therefore, the dentist can perform a minimally invasive procedure on the patient by performing the procedure according to the treatment plan.
- the dentist has a gap between the medical practice of acquiring patient data using the first scanner (CT scan) 14 and the second scanner (intraoral scanner) 16 and the medical practice of actually performing the procedure on the patient.
- system 10 can be used to create a treatment plan.
- CT scan first scanner
- intraoral scanner second scanner
- system 10 can be used to create a treatment plan.
- a treatment plan In the present embodiment, an example in which a dentist himself creates a treatment plan has been described.
- the process of creating a treatment plan does not actually treat or diagnose a patient, it is an extremely important process that leads to a medical practice of embedding the implant body 30 in the mandible. For this reason, the dentist can create a treatment plan using the system 10, and perform preliminary verification of the procedure using the model 100 created based on the treatment plan and the auxiliary tool 200. This is an extremely effective process for ensuring For this purpose, it is extremely useful for dentists themselves to use the system 10 that allows them to create an optimal treatment plan for each patient in order to ensure the safety of treatment.
- the treatment plan itself is created by an unqualified person for dental treatment, such as a manufacturer's technician or a dental technician.
- the dentist can receive treatment plan creation data, review the treatment plan in the system 10, and issue correction instructions or make corrections by himself/herself.
- the dentist can use the model 100, the hole forming tool 40, the implant body 30, and the auxiliary tool 200 to verify the safety of the treatment in advance immediately before performing the actual procedure.
- the dentist himself/herself performs a series of operations using the system 10, thereby reducing the time spent communicating with vendors such as manufacturers. Therefore, when a dentist prepares a treatment plan and outputs the model 100 with the 3D printer 24, it is possible to significantly reduce the time, for example, by one week, compared to using a contractor. Therefore, the dentist can prepare the patient for the procedure earlier.
- the dentist can take the initiative and use trial and error to develop an optimal treatment plan. Therefore, even if the output of the auxiliary tool 200 and the model 100 is entrusted to the vendor, the number of corrections of the auxiliary tool 200 and the model 100 can be reduced. Therefore, the dentist can prepare the patient for the procedure earlier.
- auxiliary instrument surgical guide
- the cost of creating an auxiliary instrument is relatively high, for example, at least 35,000 yen or more, and it is not always necessary, so dentists use the auxiliary instrument 200.
- the dentist himself designs the auxiliary instrument 200 and outputs it using the 3D printer 24 or the milling machine 26 owned by the dentist himself, the auxiliary instrument 200 It is possible to achieve a significant cost reduction in the creation of Therefore, by using the system 10 according to the present embodiment, it is possible to spread the use of auxiliary instruments such as surgical guides among dentists during implant treatment.
- the creation of the treatment plan can be changed to the initiative of the dentist as much as possible, the cost of creating the treatment plan including the auxiliary tool 200 can be reduced, and the safer treatment using the auxiliary tool 200 can be achieved. can be spread.
- a system 10 for pre-procedural verification of a dental treatment plan that allows a dentist to verify in advance the positional relationship between the tip position of the surgical instrument when used and the target position such as the position of the lower alveolar artery and lower alveolar nerve of the patient's mandible.
- a program for pre-procedural verification of a dental treatment plan a method of manufacturing a model 100 for pre-procedural verification of a dental treatment plan, and a model 100 for pre-procedural verification of a dental treatment plan.
- the resin material of the model 100 created by the 3D printer 24 is, for example, transparent or translucent, and the target model portion 120 is attached to the inferior alveolar bone as a film-like body 145 that allows the dentist to visually confirm. Corresponding parts may be present.
- the model 100 displays a fourth three-dimensional image 54 of the implant body and a fifth three-dimensional image 55 of the hole forming tool from the lower left diagram in FIG. Formed in a removed state.
- the portion corresponding to the lower alveolar bone may be formed in a mesh shape as long as the positional relationship between the hole forming instrument 40 and the target model portion 120 can be visually recognized.
- the auxiliary tool 200 has a guide hole 210 for forming a concave hole for embedding the implant body 30 .
- the guide hole 210 and the recessed hole 70 are circular holes when formed by a rotary drill as the hole forming tool 40 .
- the guide hole 210 and the concave hole 70 may form non-circular holes without using a rotary drill.
- the first scanner 14 and the second scanner 16 has been described.
- a single scanner can acquire the first three-dimensional image data 51 and the second three-dimensional image data 52, multiple scanners may be unnecessary.
- the first scanner 14 and the second scanner 16 are owned by a dentist, and the dentist acquires three-dimensional image data of the patient's jaw.
- the modeling of the modeled object by the 3D printer 24 may be performed by an appropriate trader.
- the first scanner 14 and/or the second scanner 16 may be used to previously acquire three-dimensional image data of the patient, so the first scanner 14 and/or the second scanner 16 is also preferably not included in system 10 .
- 3D printer 24 and/or milling machine 26 are also preferably not included in system 10 .
- auxiliary tool 200 in the system 10 and using the auxiliary tool 200 in an actual procedure has been described.
- Auxiliary instrument 200 may not be necessary, for example, due to the selection of hole forming instrument 40 .
- FIG. 19 shows a first modification of the hole forming instrument 40 different from FIG.
- the hole forming tool 40 shown in FIG. 19 has a handle 50 in addition to a body 42, a shank 44, a sleeve 46 and a stopper 48. As shown in FIG. A lower end of the stopper 48 contacts the handle 50 . Therefore, the position of the tip of the body 42 of the hole forming tool 40 can be adjusted by adjusting the height of the handle 50 . For example, as the height of handle 50 increases, the bottom of recess 318 moves away from unreachable target 320 .
- the dentist uses the shape (length, outer diameter), position, and angle of the implant body 30 as parameters, and inputs the above-described parameters H1, H2, H3, D1, and D2 appropriately using the operation unit 20. Then, while confirming the condition of the patient's treatment target area, an optimal treatment plan is created.
- Setting or installing the parameters H1, H2, H3 involves the dentist selecting the most suitable hole forming instrument 40 .
- the implant body 30 is embedded in the concave hole 318 formed in the mandible has been described as an example.
- the system 10 described in the first embodiment is similarly used when forming a recessed hole for embedding the autologous tooth 400 as the embedded body shown in FIG. can be used to develop a treatment plan.
- the dentist can create three-dimensional image data (second surface data) of the autologous tooth 400 in the same way as creating three-dimensional image data of the implant body 30 .
- Three-dimensional image data of the autologous tooth 400 can be acquired using various devices.
- the three-dimensional image data of the autologous tooth 400 may be acquired using the second scanner 16, for example.
- the dentist uses the shape, position, and angle of the patient's own tooth 400 as parameters, and inputs the above-described parameters H1, H2, H3, D1, and D2 as appropriate using the operation unit 20 to determine the state of the patient's treatment target site. Create an optimal treatment plan while confirming Setting or installing the parameters H1, H2, H3 involves the dentist selecting the most suitable hole forming instrument 40 .
- the autologous tooth 400 differs in shape from patient to patient, unlike the implant body 30 that can be a ready-made product. For this reason, when the autogenous tooth 400 is embedded in the lower jaw, two or three concave holes may be made according to the shape of the autologous tooth 400 .
- the auxiliary tool 200 can also be used when forming these concave holes. When creating a recess, for example, the same or different hole forming tools 40a, 40b can be used in sequence.
- the dentist uses the shape, position, and angle of the cell tissue (for example, an aggregate of cell tissue) as an implant in regenerative medicine as parameters, and the above-described parameters H1, H2, H3, D1, and D2 are appropriately input using the operation unit 20, and an optimal treatment plan is created while confirming the condition of the patient's treatment target site.
- Setting or installing the parameters H1, H2, H3 involves the dentist selecting the most suitable hole forming instrument 40 . In this way, the dentist can use the above-described system 10 to create a treatment plan and a model for pre-procedural verification of the dental treatment plan even when performing regenerative medicine.
- the first scanner (dental CT scan) 14 acquires first three-dimensional image data (for example, DICOM data) 551 of, for example, teeth, bones, and bone interiors of the patient's upper jaw, and outputs them to the control device 12 .
- the control device 12 causes the storage device 22 to store the first three-dimensional image data 551 .
- the second scanner (intraoral scanner) 16 acquires second three-dimensional image data (eg, STL data) 552 of the surface of the patient's maxillary teeth and gums, for example, and outputs the data to the controller 12 .
- the control device 12 causes the storage device 22 to store the second three-dimensional image data 552 .
- the dentist uses a first three-dimensional image 551 showing the superior alveolar bone, the maxillary sinus, the posterior superior alveolar artery and the greater palatine artery obtained by the first scanner 14 on the software.
- the positions of the posterior superior alveolar artery, the greater palatine artery, and the floor of the maxillary sinus mucosa are specified when setting the pit 70 for embedding the implant body.
- the dentist creates non-reachable targets as third three-dimensional image data 553a, 553b, and 553c.
- the posterior superior alveolar artery, the greater palatine artery, and the maxillary sinus mucosa are adjacent to the superior alveolar bone.
- the right side view in FIG. 21 shows a three-dimensional image 553a of the maxillary sinus 551a portion, the posterior superior alveolar artery portion, and a three-dimensional image 553b of the greater palatine artery portion.
- the three-dimensional image data 553c corresponding to the maxillary sinus floor mucosa may be created like a part of an egg shell, or may be formed in a spherical shape as a whole (see FIG. 29). This is because, when performing preliminary verification of a treatment plan using a model, the site that affects the reachability of the tip of the body 42 of the hole forming instrument 40 is the site corresponding to the maxillary sinus floor mucosa, and the rest of the site is This is because it does not affect the arrival of the tip of body 42 of 40 .
- the dentist sets or installs the length, outer diameter, angle, position, etc. of the implant body simulating the implant body 30 at the treatment position on the software, as shown in FIG. 21 (step S4). At this time, the dentist appropriately sets the outer diameter, position, angle, and various parameters of the implant body 30 described in the first embodiment (including selection of the hole forming tool 40) to optimize the treatment plan. .
- the dentist aligns the coordinate axes of the first to fifth three-dimensional image data 551, 552, 553a to 553c, 54, 55 on the software to obtain the first three-dimensional image data 551,
- the second three-dimensional image data 552 is superimposed on the third three-dimensional image data 553a-553c and the fourth three-dimensional image data 54 and/or the fifth three-dimensional image data 55 on a predetermined coordinate system. match (step S5).
- the dentist clearly indicates the positional relationship between the surfaces of the teeth and gums of the upper jaw and the arteries inside the upper alveolar bone on the software.
- the dentist creates an auxiliary tool (surgical template) on the software according to the shape of the patient's upper jaw, as shown in FIG. 23 (step S6). That is, the dentist creates an auxiliary instrument as sixth three-dimensional image data 556 .
- the dentist displays the sixth three-dimensional image data 556, the fourth three-dimensional image data 54 or the fifth three-dimensional image data 55, and the third three-dimensional image data 553a and 553b on the display unit 18.
- the arrangement state is confirmed (step S7).
- the dentist outputs the auxiliary instrument (step S8).
- the dentist confirms whether there are any corrections to the treatment plan on the software. If there is a problem, fix it. If there is no problem, the first three-dimensional image data 551 showing the teeth and upper alveolar bone, the second three-dimensional image data 552 showing the teeth and gums, and the third three-dimensional image of the unreachable target shown in FIG.
- the data 553a and 553b, the fourth three-dimensional image data 54 of the implant body, and the fifth three-dimensional image data 55 of the hole forming tool 40 are superimposed on a predetermined coordinate system (step S9).
- the same software as the software for creating the treatment plan is used to generate the second three-dimensional image data 552, the third three-dimensional image data 553a and 553b, the fourth three-dimensional image data 54, and the fifth three-dimensional image data. 55 are superimposed on a predetermined coordinate system.
- the dentist removes the fourth three-dimensional image data 54 regarding the implant body 30 and the fifth three-dimensional image data 55a regarding the sleeve (step S10). That is, as shown in FIGS. 25 and 26, data for the 3D printer 24 of the tooth, the gum having a through-hole simulating the recess for embedding the implant body 30, and the non-reachable target (model surface data).
- the 3D printer 24 controlled by the control device 12 based on the dentist's instruction input, penetrates to imitate the concave hole for embedding the tooth and the implant body 30.
- a model of the treatment site of the patient is modeled, simulating the gums with holes, the posterior superior alveolar artery and the greater palatine artery as non-reachable targets (step S11).
- FIG. 27 shows the relationship between alveolar bone 712, tooth 714, and maxillary sinus 730 of maxillary 710.
- FIG. 28 shows the fixation of the implant body 30 to the upper jaw 710 using a sinus lift procedure such as a sinus lift (socket lift) procedure.
- a sinus lift procedure such as a sinus lift (socket lift) procedure.
- the thickness of the upper alveolar bone 712 shown in FIG. 27 may be insufficient.
- maxillary sinus floor elevation surgery is performed to push up the maxillary sinus floor mucosa 730a of the maxillary sinus 730 shown in FIG.
- the sinus floor mucosa 730a of the maxillary sinus 730 along with the posterior superior alveolar artery and the greater palatine artery, are also non-reachable targets for the drill body 42 as the hole forming instrument 40 when performing sinus floor elevation surgery.
- a concave hole 718 for embedding the implant body 30 is opened in the superior alveolar bone 712 .
- the concave hole 718 is opened to the vicinity of the bottom of the maxillary sinus 730, but the maxillary sinus floor mucosa 730a is not penetrated.
- the superior alveolar bone 712 is penetrated by an osteotome or the like instead of the hole forming instrument 40 .
- a bone filling material 740 is filled between the mucous membrane 730 a of the maxillary sinus 730 and the superior alveolar bone 712 .
- the implant body 30 is embedded.
- the bone filling material 740 and the implant body 30 do not break the maxillary sinus floor mucosa 730a.
- a model for pre-procedural verification of a dental treatment plan for example, as shown in FIG.
- a model is constructed that mimics the teeth, gums, posterior superior alveolar artery, greater palatine artery, and maxillary sinus mucosa.
- a dentist can confirm the positional relationship between the That is, the dentist can pre-verify the dental treatment plan to determine whether the dental treatment can be performed more safely.
- the maxillary model when the parts corresponding to the teeth and gums are used as the model body, it is preferable to support, for example, the maxillary sinus floor mucosa 730a with struts, like the model 100 described in the first embodiment. is.
- using the system 10 for the lower jaw can also provide the same effects as for the lower jaw.
- the surgical instrument is used when the surgical instrument is used.
- a pre-procedural verification system for dental treatment plans that allows dentists to pre-verify the positional relationship between the tip position of the , and target positions such as the positions of the patient's maxillary posterior superior alveolar artery and major palatine artery, and the maxillary sinus mucosa. 10.
- a program for pre-procedural verification of a dental treatment plan, a method for manufacturing a model for pre-procedural verification of a dental treatment plan, and a model for pre-procedural verification of a dental treatment plan can be provided.
- the autologous tooth 400 or cell tissue described in the modified example of the first embodiment can be used.
- the dentist uses the system 10 for pre-verification of dental treatment.
- the model 100, the hole forming instrument (manipulator) 40 scheduled to be used in actual dental treatment, and the implant body 30 or the autologous tooth 400 are used to solve problems in the treatment plan including the selection of various treatment instruments. It can be pre-verified before the procedure. For this reason, the dentist becomes skeptical about whether or not the tool (for example, the hole forming tool 40) used during the procedure can perform the prescribed treatment on the patient's treatment target site according to the treatment plan.
- the patient can be treated with less invasiveness.
- Dental treatment can be performed on
- the work of creating a treatment plan up to the creation of the three-dimensional image data of the model 100 is performed while being confirmed by the dentist who actually performs the treatment, not by the trader. Implantation treatment of the body 30 or autologous tooth can be performed more safely.
- the time for delivery of the three-dimensional image data and the time for transporting the model 100 can be omitted. It is possible to reduce the time spent on a series of tasks. Also, when correcting a treatment plan, the time required for a series of operations from correction of the treatment plan to preliminary verification of dental treatment using the model 100 can be shortened.
- a third embodiment of the invention relates to an osteotome for implantation.
- the osteotome 60 is implanted from the superficial layer of the treatment area of the patient's jaw toward the deep part, and is used to apply impact when expanding or compressing the bone so as to displace the position of the mucous membrane behind the treatment area. Used as a tool.
- the osteotome 60 of this embodiment includes a body portion 61, a bar portion 62, an end portion 63, a guided portion 64, a stopper portion 65, a display window 66, and a screw 67 (see FIG. 30A, etc.).
- the body part 61 is the main body part of the osteotome 60 and has a shape that is easy for a dentist to hold and operate.
- a hollow portion 61a for mounting the bar portion 62 is formed in the body portion 61 (see FIG. 31, etc.).
- the bar portion 62 is an elongated member that is attached to the hollow portion 61a of the body portion 61, and has an end portion 63 formed at its tip so as to displace the position of the patient's mucosa.
- the bar portion 62 of this embodiment is formed so as to be slidable in the longitudinal direction along the cavity portion 61a, so that the amount of protrusion to the end portion 63 and the overall length of the osteotome 60 can be freely changed. (See FIGS. 30A, 30C, etc.).
- a plurality of engagement grooves 62a are formed in the bar portion 62 at predetermined intervals along the longitudinal direction (see FIG. 30B, etc.).
- These engaging grooves 62a are formed so that the tip thereof engages when the screw 67 is turned. By engaging the tip of the screw 67 with the engaging groove 62a in this manner, the bar portion 62 is engaged. It is possible to position the bar portion 62 relative to the body portion 61 (see FIG. 31). Further, the bar portion 62 is provided with an information presenting portion 62b that presents information on the amount of protrusion to the end portion 63 or information on the embedding depth in the state of being positioned by the screw 67 (see FIG. 30B, etc.). . For example, in the present embodiment, the information is indicated numerically (see FIG. 30B), but this is just an example, and the specific method of presenting information by the information presenting unit 62b is not particularly limited.
- the end portion 63 is the tip portion of the bar portion 62, and is formed in a shape suitable for contacting the patient's mucosa and displacing its position (see FIG. 30B, etc.).
- the end portion A larger diameter 63 may be used to proceed with the procedure on the patient.
- a plurality of types of bar portions 62 having different diameters of the end portions 63 are prepared in advance so that the diameter of the end portions 63 can be changed by replacing the bar portions 62 .
- At least one of the plurality of bar portions 62 has an end portion 63 larger in diameter than the end portion diameter of the osteotome dedicated to implants.
- the diameter of the end portion 63 of such a bar portion 62 is, for example, 5 mm or more.
- the bar portion 62 having the size (diameter) of the end portion 63 as described above can be particularly suitably used for implanting a self-made tooth 400, and has not been used in a conventional implant osteotome. It can be said that it is a thing.
- the guided portion 64 is a portion guided along the guide hole 210 of the surgical guide 200, and is formed in a part of the body portion 61 according to the size and shape of the guide hole 210 (see FIG. 30B etc. ).
- the surgical guide 200 is provided according to the surface shape of the treatment site of the patient, and is formed so as to offset the reference position, which serves as a guideline for depth during treatment, by a predetermined amount.
- differences in skill between dentists and conditions of treatment sites for each patient can be accommodated. It is possible to reduce the variation that may occur when implanting in the treatment site due to differences, etc., and to improve the reproducibility and accuracy (see FIG. 34A, etc.).
- the stopper part 65 is a part formed so as to come into contact with the surgical guide 200 and restrict the movable range of the osteotome 60 .
- the base end side of the guided portion 64 is formed in a stepped shape having a diameter larger than that of the guided portion 64, and the stepped portion functions as a stopper portion 65 (see FIG. 30B, etc.). ).
- the display window 66 is formed in the body portion 61 so that the information in the information presentation portion 62b provided in the bar portion 62 can be visually recognized (see FIG. 30B, etc.).
- a display window 66 is formed by cutting out a part of the body portion 61 in the form of a window, and information (for example, numerical values) of the information presentation portion 62b of the bar portion 62 attached inside the display window 66 can be visually recognized. (see FIG. 30B, etc.).
- the screw 67 is a member used as a locking tool for locking the bar portion 62 at a predetermined position of the body portion 61 .
- the screw 67 By tightening the screw 67 provided in the body portion 61 and engaging the tip of the screw 67 with the engagement groove 62a of the bar portion 62, the bar portion 62 can be locked at a predetermined position.
- the screw 67 is turned in the opposite direction and loosened, the locked state of the bar portion 62 is released and the bar portion 62 can be slid in the longitudinal direction.
- two screws 67 are arranged so as to sandwich the bar portion 62, for example (see FIG. 31).
- engagement grooves 62a are provided on at least both sides of the bar portion 62 so that two screws 67 arranged to sandwich the bar portion 62 can both be engaged with the engagement grooves 62a. there is These two screws 67 may be displaced along the longitudinal direction (see FIG. 31).
- the advantages of the osteotome 60 of the present embodiment having the structure described above are as follows. ⁇ Because the overall length is variable, the overall length can be adjusted so that part of the osteotome 60 does not touch the lower jaw, for example, when a procedure is performed on the upper jaw of a patient. - From the display window 66, the information of the information presentation part 62b provided in the bar part 62 can be confirmed at a glance. - By moving the osteotome 60 while the guided portion 64 is aligned with the guide hole 210 of the surgical guide 200, it becomes easier to realize the concave hole 70 at the planned position, direction, and depth.
- the osteotome 60 as described above is only a suitable example.
- the position of the mucous membrane is displaced freehand without using the surgical guide 200 as described above.
- a screw type bar portion 62 having a structure in which helical unevenness is formed around the circumference is adopted, and the unevenness is formed on the inner wall of the hollow portion 61 a of the body portion 61 .
- the bar portion 62 By rotating the bar portion 62 , the bar portion 62 can be moved along the central axis direction to change the amount of protrusion from the body portion 61 .
- a fourth embodiment of the present invention relates to an implant hole forming device 40 .
- the hole forming instrument 40 is an instrument having a drill portion 41 that advances from the superficial layer of the treatment site of the patient's jaw toward the deep part and forms a hole for embedding a part of the implant (Figs. 33B and 33D). etc.).
- the diameter of the drill portion 41 has a size suitable for implanting the self-made tooth 400 (see FIG. 33D).
- the diameter of the drill part 41 suitable for implanting the self-made tooth 400 means that it is at least larger than the drill diameter of the hole forming instrument for implants, specifically at least 5 mm or more.
- the hole forming instrument 40 having the diameter of the drill portion 41 as described above can be particularly suitably used for implanting the self-made tooth 400, and has not been used in conventional hole forming instruments for implants.
- reference numeral 42 indicates the body
- reference numeral 42A indicates the distal end of the body 42
- reference numeral 42B indicates the proximal end of the body 42. As shown in FIG.
- a portion to be guided 43 and a stopper 48 are formed in a part of the hole forming tool 40 of this embodiment.
- the guided portion 43 is formed to be guided along the guide hole 210 of the surgical guide 200.
- the guided portion 43 is inserted into the guide hole 210 of the surgical guide 200 as described above.
- a hole 70 is formed using the hole forming instrument 40 (see FIG. 33B).
- a hole forming instrument 40 is withdrawn (see FIG. 33C).
- a hole forming tool 40 having a drill portion 41 with a larger diameter is used to form a larger concave hole 70 (see FIG. 33D).
- a drill part (drill head) 41 that is detachable from the shank 44 is employed, and after the shank 44 is inserted into the guide hole 210, the drill part is attached to the tip of the shank 44.
- 33D where the drill portion 41 larger than the inner diameter of the guide hole 210 exists between the surgical guide 200 and the patient's jaw) can be realized.
- the surgical guide 200 and the hole forming instrument 40 are removed, and then the surgical guide 200 is refitted to the patient's jaw (see FIG. 33E).
- FIG. 33E an example is shown in which drill diameters of two different sizes are used to form a concave hole 70 having a size suitable for implanting a self-made tooth 400 in a so-called two-stage procedure (Figs. 33B and 33D). ), this is a simplified example, employing three or more sizes of drill diameters, and using three or more steps of procedure to create a recess 70 of a size suitable for implanting a home-made tooth 400. can be formed.
- the osteotome 60 or the like is used to displace the position of the mucous membrane behind the concave hole 70 .
- the bar portion 62 of the osteotome 60 is inserted into the guide hole 210 of the surgical guide 200 from the end portion 63 side, and the base end side of the body portion 61 is repeatedly struck with the head 802 of the hammer 800, and the end portion 63 of the mucous membrane is removed.
- the position is gradually displaced (see Figure 34A).
- the manipulation (displacement of the position of the mucous membrane) by the osteotome 60 is continued until the stopper portion 65 contacts the surgical guide 200 (see FIG. 34B).
- 34A and the like this simply shows only the basic structure, and is not intended to show an osteotome with a different structure.
- 34A and 34B the length of the shaft portion (bar portion) of the osteotome 60 is different. It shows that the overall length of the osteotome 60 is appropriately changed.
- the osteotome 60 and the surgical guide 200 are temporarily removed (see FIG. 34C). After that, the osteotome 60 with the larger diameter end 63 is used to displace the position of the mucous membrane behind the concave hole 70 over a wider range (see FIGS. 34D and 34E).
- FIGS. 34D and 34E details are not shown in the figure, after replacing the bar portion 62 and inserting the base end side of the bar portion 62 into the guide hole 210 of the surgical guide 200, the bar portion 62 is attached to the body portion 61. 34D (the state in which the end 63 larger than the inner diameter of the guide hole 210 exists between the surgical guide 200 and the jaw of the patient) can be realized.
- the surgical guide 200 and the osteotome 60 are removed (see FIG. 34F), and the osteotome 60 whose end portion 63 has a diameter that is one step larger is used to displace the position of the mucous membrane behind the recess 70 over a wider range (see FIG. 34F). 34G, see FIG. 34H).
- the surgical guide 200 and the osteotome 60 are removed (see FIG. 35A).
- the osteotome 60 with three different sizes of the end portion 73 is used, and an example of displacing the mucous membrane by a so-called three-stage procedure is shown (see FIGS.
- the surgical guide 200 with the water flow tube 700 attached is fitted to the patient's jaw (for example, the upper jaw), and the tip 702 of the water flow tube 700 is applied to the concave hole 70 (see FIG. 35B).
- the stepped portion 704 formed on the tip portion 702 is in contact with the inner wall of the concave hole 70 (see FIG. 35B).
- test post 410 is a sample used for diagnostic imaging that is inserted into a hole at a predetermined location and forms an image in an image taken in that state using radiation to indicate the position of the hole.
- the hole at the predetermined location is, for example, a hole formed to embed a part of the embedded body (implant body 30 or homemade tooth 400) in the treatment location of the patient's jaw, or the surgical guide described above. It means the guide hole 210 formed in 200 .
- the position of the implanted body (for example, the white part near the center in FIG. 36A) 36A) may actually occur (see FIG. 36A).
- the reasons for this are considered to be matching mismatch, distortion of the impression material, swelling of the plaster, distortion of the scan, distortion when converting the CT data into three dimensions, and so on.
- the test post 410 of the present embodiment devised in view of such actual circumstances and circumstances enables timely checks as described above.
- test post 410 A specific example of the test post 410 will be explained.
- the test post 410 of this embodiment is made of a material that forms an image in an image captured using radiation, such as a resin material or a ceramic material such as zirconia (see FIG. 36B).
- a specific size of the test post 410 is not particularly limited, and it may be formed in a size corresponding to the concave hole 70 of the treatment site whose position is to be detected and the guide hole 210 of the surgical guide 200 .
- a test post 410 having a flange-shaped stepped portion 412 is employed so that the outer diameter changes midway (see FIG. 36B).
- the portion of the outer diameter portion 414 that is the maximum diameter of the test post 410 (corresponding to the stepped portion 412 portion in the case of the test post 410 shown in FIG. It may have a larger diameter.
- the outer diameter portion 414 functions as a stopper that abuts against the surgical guide 200 , and imaging can be performed while the surgical guide 200 is positioned at a predetermined position in the guide hole 210 .
- FIGS. 36C to 36F another mode of use of the test post 410 will be described (see FIGS. 36C to 36F).
- the surgical guide 200 actually created based on the sixth three-dimensional image (three-dimensional image of the surgical guide 200) 56 of the auxiliary instrument (see FIG. 36D), and the test post 410 is attached (see FIG. 36E ), the surgical guide 200 is actually attached to the patient while the test post 410 is attached, and a CT image is taken (see FIG. 36F).
- a CT image is taken (see FIG. 36F).
- a test post 410 for such applications, a test post 410 having a relatively long axial length at the portion of the outer diameter portion 414 that is the largest diameter can be employed (see FIG. 36C).
- a sixth embodiment of the present invention relates to a stopper extension.
- the stopper extension 500 is configured as a member that is inserted into the guide hole 210 of the surgical guide 200 and extends the guide length (see FIGS. 37A to 37C).
- the stopper extension 500 of the present embodiment is made of, for example, a resin-made stepped member formed in a cylindrical shape (see FIG. 37A).
- the outer diameter of the stopper extension 500 is formed to correspond to the inner diameter of the guide hole 50a at the tip of the handle 50, and a portion of the stopper extension 500 (excluding the stepped portion 502) is inserted into the guide hole 50a. Thus, it can be attached to the handle 50 (see FIG. 37B).
- the inner diameter of the stopper extension 500 is sized according to the diameter of the shank 44 of the hole forming tool 40 to be used.
- the outer diameter portion of the stopper extension 500 having a large diameter (corresponding to the stepped portion 502 in the case of the stopper extension 500 of the present embodiment) has a predetermined size, for example, larger than the inner diameter of the guide hole 210 of the surgical guide 200. 37B and 37C).
- the guide length in the axial direction can be made longer than when the hole forming instrument 40 or the like is guided only by the handle 50. At this time, it is possible to reduce sideways movement of the hole forming tool 40 and improve straightness.
- the stopper extension 500 serves not only as a member for extending the guide length, but also as a member for changing the contact position of the stopper (for example, the stopper 48 of the hole forming instrument 40, the stopper portion 65 of the osteotome 60, etc.). can also work.
- the contact position of the stopper can be displaced in units of a predetermined value.
- a seventh embodiment of the present invention relates to a periodontal ligament guard.
- the periodontal ligament guard 600 is a member that partially or entirely covers the portion of the self-made tooth 400 to be implanted, excluding the tooth root to be cut (see FIGS. 38A to 38C).
- external factors that may be applied to the periodontal ligament around the root when cutting the root for example, heat that may be generated when cutting, heat used when cutting, etc.
- Such a periodontal ligament guard 600 may be made of a low-resilience material.
- the periodontal ligament guard 600 formed of such a material, when the self-made tooth 400 wrapped in the periodontal ligament guard 600 is held between fingers, the periodontal ligament guard 600 is freely deformed into a shape that is easy to hold. Therefore, it becomes easier to perform an operation such as cutting the tooth root (see FIG. 38C, etc.). From this point of view, the periodontal ligament guard 600 may be made of silicon or the like. Although not shown, it is also possible to cover the entire self-made tooth 400 with the periodontal ligament guard 600 and cut the root together with the periodontal ligament guard 600 .
- An eighth embodiment of the invention relates to a water flow tube.
- the water flow tube 700 is an instrument that is embedded in the patient's jaw from the surface to the deep part of the treatment site (concave hole 70, etc.), and ejects water from the distal end 72 toward the position of the mucous membrane behind the treatment site. is.
- the diameter of the distal end portion 702 of the water flow tube 700 is set to a size that is particularly suitable for implanting the homemade tooth 400, more specifically, a recess that is generally larger than when the implant body 30 is embedded. The size is set to match the size of the hole 70 (see FIG. 35B, etc.).
- a stepped portion 704 is formed in the distal end portion 702 of the water flow tube 700 so that the outer diameter increases stepwise from the distal end toward the proximal end (see FIG. 35C, etc.).
- the stepped portion 704 can be formed of, for example, a plurality of steps of flange-like projections made of an elastic member (eg, rubber material).
- an elastic member eg, rubber material.
- the adhesion with the concave hole 70 is further improved by moderately elastically deforming, so that it is possible to further improve the efficiency when the mucous membrane is displaced by the ejected water. (Refer to FIG. 35C, FIG. 35D, etc.).
- the present invention is not limited to the above-described embodiments, and can be variously modified in the implementation stage without departing from the gist of the invention. Moreover, each embodiment may be implemented in combination as much as possible, and in that case, the combined effect can be obtained. Furthermore, the above-described embodiments include inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements.
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Abstract
Description
そして、歯科医師は、例えばインプラント治療において、治療対象が上顎であれば、ドリルなどの穴形成器具の先端を、所定の非到達(非接触)ターゲットとして患者の上顎洞粘膜、後上歯槽動脈、及び、大口蓋動脈などに到達させないように手技を行う。また、歯科医師は、治療対象が下顎であれば、ドリルなどの穴形成器具の先端を、所定の非到達ターゲットとして患者の下歯槽動脈及び下歯槽神経に到達させないように手技を行う。
例えばインプラント治療において、治療計画通りに骨に凹孔を形成するために、ドリルを案内するサージカルガイドが使用されることがある。サージカルガイドは、患者の上顎及び/又は下顎の3次元画像データに基づいて形成される。サージカルガイドは、患者の歯及び歯茎に嵌めて使用される。サージカルガイドは、歯科医師による手技時、インプラント体の埋設用の穴を形成するときの穴の位置、方向、径等を、治療計画の通りに形成可能とする。
インプラント治療の治療計画の作成(サージカルガイドの作成を含む)は、現状、歯科医師が取得した患者のCT画像データ(DICOMデータ)から、例えばインプラントのメーカーが持つシステムを用いてメーカーの技術者が行うことが多い。歯科医師は、メーカーの技術者が作成した治療計画を検討する。しかし、歯科医師は治療計画の作成時に作成現場におらず、また、歯科医師がメーカーが作成した治療計画の修正時に使用可能なツールは限られている。対象が3次元的であるため、歯科医師がインプラント体の選定、インプラント体を埋設する凹孔の内径、位置、角度等の僅かな調整、器具選択といった治療計画の細かな指示を歯科医師の意図通りに行うことが難しい。
本来であれば、インプラント治療の治療計画の作成から実際の治療まで、歯科医師が責任をもって行うべきである。そして、メーカーの技術者が作成した治療計画において例えば穴形成器具の各種パラメータの選択ミス等があったとしたときに、歯科医師が気づかずに誤った治療計画の通りに手技を行ってしまう可能性を排除することは難しい。
当該オステオトームの本体部たるボディ部と、
該ボディ部の先端に形成され、粘膜の位置を変位させる端部と、
を備え、端部の径が自家製歯の移植に適した大きさである、オステオトームである。
当該オステオトームの本体部たるボディ部と、
該ボディ部の先端に形成され、粘膜の位置を変位させる端部と、
を備え、患者の治療箇所の表面形状に合わせて形成され、治療の際の高さの目安となる基準位置を所定量オフセットさせるサージカルガイドに設けられたガイド孔に沿ってガイドされる被ガイド部がボディ部の一部に形成されている、オステオトーム。
先端部の径が自家製歯の移植に適した大きさである、移植用の水流チューブである。
患者の3次元立体画像に基づいて形成され、患者の治療対象の歯槽骨に隣接又は埋設され、治療時に複数から選択される手技器具の先端を非接触とするべき非接触ターゲットを模し、患者の治療対象の歯、歯茎、及び、歯槽骨と非接触ターゲットとの位置関係と同じ位置関係に、模型本体に設けられる、ターゲット模型部と、
患者の3次元立体画像に基づいて、模型本体における患者の治療対象の歯茎及び歯槽骨を模した位置に、治療対象に対する埋設体を埋設可能な孔を模して形成され、患者の3次元立体画像における孔に対し3次元立体画像における手技器具が嵌まり、3次元立体画像において手技器具が孔に挿入されたときに、手技器具とターゲットとの間の位置関係を歯科医師に視認可能とする、孔部と、
を備え、
ターゲット模型部に、手技前検証時に手技器具が接触した場合、接触したことを知らしめるための流体が内蔵されている、歯科治療計画の手技前検証用の模型である。
第1実施形態では、システム10を、多数から選択される埋設体としてのインプラント体30(図2参照)を患者の下顎に埋設するインプラント治療を行う例に用いる場合について説明する。
歯科医師は、自らインプラント体30を選択し、下顎の骨に対するインプラント体30の角度、位置等を患者に合わせて最適に設定できる。このとき、歯科医師は、インプラント体の選択をやり直し、患者の処置対象に対し、長さ、外径が異なるインプラント体の適合性を試すことも容易である。
図12に示すように、実際のインプラント治療において、補助器具200及び穴形成器具40を用いて、下歯槽骨312及び歯茎316には、凹孔318が形成される。凹孔318は、下歯槽骨312の頂部から凹孔318の底部までの距離D1と、下歯槽骨312の頂部(規定面)335から補助器具200の規定面220までの距離(オフセット値)D2を合わせた深さとなる。すなわち、補助器具200を用いる場合、凹孔318の深さは、下歯槽骨312の頂部から補助器具200の規定面220までオフセットされる。
なお、ステップS3からステップS7は、画像処理プログラムを用いて処理し、画像表示プログラムを用いて表示部18に表示させる。
すなわち、操作部20では、制御装置12に対し、第1の表面データと、第2の表面データ及び第3の表面データの少なくとも一方と、第4の表面データとを所定の座標系上で重ね合わせる処理指示(座標変換指示)、及び、第1の表面データから、第2の表面データ及び第3の表面データを引いて、孔を含む治療対象部位と、第4の表面データとの位置関係を示す第5の表面データを作成する処理指示、が入力され、制御装置12により、これらが処理される。なお、座標変換指示に第2の表面データを用いない場合、第5の表面データの作成時に第2の表面データを引く必要はない。座標変換指示に第3の表面データを用いない場合、第5の表面データの作成時に第3の表面データを引く必要はない。
なお、模型100を造形する場合、歯科医師は、インプラント体及び穴形成器具の3次元画像54,55を選択的に用いてもよい。
また、例えば歯科医師等のシステム10における治療計画の作成者は、治療計画の作成時において穴形成器具40のボディ42の長さ、ストッパー48の高さ、オフセット値などの各種パラメータを間違うことがあり得る。そして、治療計画の作成者は、各種パラメータの間違いを見逃して、治療計画の作成を終了してしまうことがあり得る。この場合であっても、歯科医師が模型100及び実際の穴形成器具40を使用して治療計画の事前検証を行うと、治療計画における各種パラメータの設定ミスに気付くことができ得る。そして、歯科医師は、模型100を用いて、使用する穴形成器具40のボディ42の長さ、ストッパー48の高さ、オフセット値などのパラメータをどのように変更すると上手く手技が行えるか、検討を行うことができる。このとき、治療計画の作成時に設定したメーカーの穴形成器具40以外の穴形成器具も、適宜に試すことができる。このため、歯科医師は、模型100を用いることにより、穴形成器具40を、自らが所有する器具の中から、適切に選択することができる。
したがって、本実施形態で説明した模型100を用いて歯科医師が手技の事前検証を行うことは、インプラント治療における治療の一環として必ず行うべきである。このため、歯科医師は、模型100を用いた手技の事前検証により、必要に応じて、穴形成器具40を適切に変更し、最適な治療を行うことができる。なお、歯科医師は、システム10を使用して治療計画を修正してもよいことはもちろんである。このため、歯科医師が本実施形態に係る模型100を用いることで、インプラント治療の安全性を大きく高めることができる。
歯科医師がシステム10を用いる場合、歯科医師が主導して、歯科医師が試行錯誤して最適な治療計画を立てることができる。このため、仮に、補助器具200及び模型100の出力を業者に任せる場合であっても、補助器具200及び模型100の修正回数を少なくすることができる。したがって、歯科医師は、患者に対して、より早期に手技を行える状態を整えることができ得る。
第1実施形態の第1変形例に係るシステム10について、図19を用いて説明する。ここでは、図3に示す穴形成器具40とは異なる穴形成器具40を用いる場合のパラメータの設定の違いについて説明する。
第1実施形態では、図12に示すように、インプラント体30を下顎に形成する凹孔318に埋設する場合を例にして説明した。例えば、インプラント体30を凹孔318に埋設する代わりに、図20に示す埋設体としての自家歯牙400を埋設する凹孔を形成する場合も、同様に、第1実施形態で説明したシステム10を用いて治療計画を作成することができる。
第2実施形態では、システム10を、多数から選択されるインプラント体30(図2参照)を患者の上顎に埋設するインプラント治療を行う例に用いる場合について、図21から図29を用いて説明する。第1実施形態で説明した事項と共通の事項については、適宜に説明を省略する。
なお、第2実施形態に係るシステム10においても、インプラント体30の代わりに、第1実施形態の変形例で説明した自家歯牙400又は細胞組織を用いることができる。
本発明の第3実施形態は、移植用のオステオトームに関する。オステオトーム60は、患者の顎部の治療箇所の表層から深部に向けて埋入され、当該治療箇所の奥の粘膜の位置を変位させるように骨を押し広げあるいは圧縮する際に衝撃を加えるための器具として用いられる。本実施形態のオステオトーム60は、ボディ部61、バー部62、端部63、被ガイド部64、ストッパー部65、表示窓66、スクリュー67を備えている(図30A等参照)。
・全体の長さが可変であるため、例えば患者の上顎の治療箇所を対象にして手技を行う場合に、オステオトーム60の一部が下顎に当たらないように全体長さを調整することができる。
・表示窓66から、バー部62に設けられた情報提示部62bの情報を一目で確認することができる。
・サージカルガイド200のガイド孔210に被ガイド部64を沿わせながらオステオトーム60を動かすことによって、計画通りの位置、方向、深さの凹孔70を実現しやすくなる。
本発明の第4実施形態は、移植用の穴形成器具40に関する。穴形成器具40は、患者の顎部の治療箇所の表層から深部に向けて進み、埋設体の一部を埋設するための穴を形成するドリル部41を有する器具である(図33B、図33D等参照)。本実施形態の穴形成器具40は、ドリル部41の径が自家製歯400の移植に適した大きさとなっている(図33D参照)。自家製歯400の移植に適したドリル部41の径とは、少なくとも、インプラント用の穴形成器具のドリル径よりも大きいということであり、具体的には、少なくとも5mm以上の大きさとなる。ドリル部41の径が上記のような穴形成器具40は特に自家製歯400の移植用として好適に用いることができるものであり、従来のようなインプラント用の穴形成器具では用いられてこなかったものであるといえる。なお、図33B等における符号42はボディ、符号42Aはボディ42の先端、符号42Bはボディ42の基端をそれぞれ示す。
本実施形態のごとき穴形成器具40、上記の第3実施形態のごときオステオトーム60、そして水流チューブ700を用いて、患者の顎部に自家製歯400の移植用の凹孔70を形成する際の歯科医師の手技の一連の流れを図に示しつつ説明する(図33A~図35E参照)。
本発明の第5実施形態は、テストポスト410に関する。テストポスト410は、所定の箇所の穴に挿入され、その状態で行われる放射線を利用した撮影画像中に結像して当該穴の位置を示す、画像診断に用いられる試料である。ここでいう所定の箇所の穴とは、例えば、患者の顎部の治療箇所に埋設体(インプラント体30や自家製歯400)の一部を埋設するために形成された穴、または上記のサージカルガイド200に形成されたガイド孔210のことをいう。
本発明の第6実施形態は、ストッパーエクステンションに関する。ストッパーエクステンション500は、サージカルガイド200のガイド孔210に挿入され、ガイド長さを延長させる部材として構成されている(図37A~図37C参照)。
本発明の第7実施形態は、歯根膜ガードに関する。歯根膜ガード600は、移植に供される自家製歯400のうち、カット対象たる歯根を除く部分の一部または全部を覆う部材である(図38A~図38C参照)。このような歯根膜ガード600を利用することで、歯根をカットする際に当該歯根の周囲にある歯根膜に与えることがある外因(例えば、カットする際に生じ得る熱や、カットする際に用いられる水流や油分、等)によるダメージを軽減させることが可能となる。このような歯根膜ガード600は、低反発素材で形成されていてもよい。このような素材で形成された歯根膜ガード600によれば、歯根膜ガード600で包まれた状態の自家製歯400を指で挟み持つ際、当該歯根膜ガード600が自在に変形して持ちやすい形状となるため、歯根をカットするといった作業が行いやすくなる(図38C等参照)。こういった観点から、歯根膜ガード600はシリコン製などであってもよい。なお、特に図示してはいないが、歯根膜ガード600で自家製歯400をすべて覆い、歯根膜ガード600ごと歯根をカットするというような用い方をすることもできる。
本発明の第8実施形態は、水流チューブに関する。水流チューブ700は、患者の顎部の治療箇所(凹孔70など)の表層から深部に向けて埋入され、当該治療箇所の奥の粘膜の位置に向けて先端部72から水を噴出させる器具である。本実施形態では、水流チューブ700の先端部702の径を、特に自家製歯400の移植に適した大きさ、より具体的には、インプラント体30を埋設するときよりも一般的には大きくなる凹孔70のサイズに合わせた大きさとしている(図35B等参照)。さらに、本実施形態では、水流チューブ700の先端部702に、先端から基端に向かうにつれ外径が段階的に大きくなる段部704を形成している(図35C等参照)。段部704は、例えば、弾性部材(例えばゴム材)からなる複数段のフランジ状突出部で形成することができる。このような段部704によれば、適度に弾性変形することによって凹孔70との密着性がさらによくなるため、噴出させた水で粘膜を変位させる際の効率をさらに向上させることを可能とする(図35C、図35D等参照)。
12…制御装置
18…表示部
20…操作部
30…インプラント体(埋設体)
40…穴形成器具
41…ドリル部
42…ボディ
42A…ボディの先端
42B…ボディの基端
43…被ガイド部
44…シャンク
46…スリーブ(ドリルスリーブ)
48…ストッパー
48a…ストッパー48のボディ42側の端面
50…ハンドル
50a…ハンドルのガイド孔
51…第1の3次元画像データ(第6の表面データ)
52…第2の3次元画像データ(第1の表面データ)
53…第3の3次元画像データ(第4の表面データ)
54…第4の3次元画像データ(第2の表面データ)
55…第5の3次元画像データ(第3の表面データ)
56…第6の3次元画像
60…オステオトーム
61…ボディ部
61a…空洞部
62…バー部
62a…係合溝
62b…情報提示部
63…端部
64…被ガイド部
65…ストッパー部
66…表示窓
67…スクリュー(係止具)
70…凹孔
100…模型
100a…3次元画像データ(第5の表面データ)
110…模型本体
110a…3次元画像データ
120…ターゲット模型部
120a…3次元画像データ
130…孔部(貫通孔)
200…サージカルガイド(補助器具)
210…ガイド孔
220…規定面
310…下顎
312…歯槽骨
314…歯
316…歯茎
318…凹孔
320…非到達ターゲット
400…自家歯牙(自家製歯)
410…テストポスト
412…段付き部
414…外径部
500…ストッパーエクステンション
502…段付き部
504…外径部
600…歯根膜ガード
700…水流チューブ
702…先端部
704…段部
800…トンカチ
802…ヘッド
H1…ドリルスリーブの基端部(46b)からドリルボディ(42)の先端までの長さ
H2…ドリルスリーブの基端部(46b)から先端のストッパー(48)までの長さ
D1…インプラント体(30)または自家歯牙の長さ
D2…サージカルガイドを用いたことによるオフセット量の値
Claims (21)
- 患者の顎部の治療箇所の表層から深部に向けて埋入され、当該治療箇所の奥の粘膜の位置を変位させるように骨を押し広げあるいは圧縮する際に衝撃を加えるための器具として用いられるオステオトームであって、
当該オステオトームの本体部たるボディ部と、
前記ボディ部あるいは当該ボディ部に取り付けられる部材の先端に形成され、前記粘膜の位置を変位させる端部と、
を備え、前記端部の径が自家製歯の移植に適した大きさである、オステオトーム。 - 前記端部の径が、インプラント専用のオステオトームの端部径よりも大きい、請求項1に記載のオステオトーム。
- 前記端部の径が5mm以上である、請求項2に記載のオステオトーム。
- 患者の治療箇所の表面形状に合わせて設けられ、治療の際の深さの目安となる基準位置を所定量オフセットさせるサージカルガイドに形成されたガイド孔に沿ってガイドされる被ガイド部が前記ボディ部の一部に形成されている、請求項3に記載のオステオトーム。
- 患者の顎部の治療箇所に対し基端側から先端側に向けて埋入され、当該治療箇所の奥の粘膜の位置を変位させるように骨を押し広げあるいは圧縮する際に衝撃を加えるための器具として用いられるオステオトームであって、
当該オステオトームの本体部たるボディ部と、
該ボディ部の先端に形成され、前記粘膜の位置を変位させる端部と、
を備え、患者の治療箇所の表面形状に合わせて形成され、治療の際の高さの目安となる基準位置を所定量オフセットさせるサージカルガイドに設けられたガイド孔に沿ってガイドされる被ガイド部が前記ボディ部の一部に形成されている、オステオトーム。 - 患者の顎部の治療箇所の表層から深部に向けて進み、埋設体の一部を埋設するための穴を形成するドリル部を有する穴形成器具であって、
前記ドリル部の径が自家製歯の移植に適した大きさである、穴形成器具。 - 前記ドリル部の径が、前記埋設体がインプラント体である場合のドリル部の径よりも大きい、請求項6に記載の穴形成器具。
- 前記ドリル部の径が5mm以上である、請求項7に記載の穴形成器具。
- 患者の治療箇所の表面形状に合わせて形成され、治療の際の高さの目安となる基準位置を所定量オフセットさせるサージカルガイドに設けられたガイド孔に沿ってガイドされる被ガイド部が当該穴形成器具の一部に形成されている、請求項8に記載の穴形成器具。
- 樹脂材料またはセラミック材料で形成され、患者の顎部の治療箇所に埋設体の一部を埋設するために形成された穴、または、患者の治療箇所の表面形状に合わせて設けられ、治療の際の深さの目安となる基準位置を所定量オフセットさせるサージカルガイドに形成されたガイド孔に挿入され、その状態で行われる放射線を利用した撮影画像中に結像して前記穴または前記ガイド孔の位置を示す、画像診断用のテストポスト。
- 段付き形状である、請求項10に記載のテストポスト。
- 前記サージカルガイドの前記ガイド孔の内径よりも大きい径である外径部を有する、請求項11に記載のテストポスト。
- 患者の治療箇所の表面形状に合わせて設けられ、治療の際の深さの目安となる基準位置を所定量オフセットさせるサージカルガイドに形成されたガイド孔に挿入され、ガイド長さを延長させる、筒状に形成されたストッパーエクステンション。
- 段付き形状である、請求項13に記載のストッパーエクステンション。
- 前記サージカルガイドの前記ガイド孔の内径よりも大きい径である外径部を有する、請求項13に記載のストッパーエクステンション。
- 移植に供される自家製歯のうち、カット対象たる歯根を除く部分の一部または全部を覆い、前記歯根をカットする際に当該歯根の周囲にある歯根膜に与えることがある外因によるダメージを軽減させる、歯根膜ガード。
- 低反発素材で形成される、請求項16に記載の歯根膜ガード。
- シリコン製である、請求項16に記載の歯根膜ガード。
- 患者の顎部の治療箇所の表層から深部に向けて埋入され、当該治療箇所の奥の粘膜の位置に向けて先端部から水を噴出させる水流チューブであって、
前記先端部の径が自家製歯の移植に適した大きさである、移植用の水流チューブ。 - 前記先端部に、先端から基端に向かうにつれ外径が段階的に大きくなる段部が形成されている、請求項19に記載の水流チューブ。
- 患者の顎部の3次元立体画像に基づいて形成され、前記患者の治療対象の歯、歯茎、及び、前記歯茎に覆われる歯槽骨の少なくとも一部と同じ大きさ及び同じ形状で、前記患者の治療対象の歯、歯茎、及び、歯槽骨の少なくとも一部を模す模型本体と、
前記患者の3次元立体画像に基づいて形成され、前記患者の治療対象の前記歯槽骨に隣接又は埋設され、治療時に複数から選択される手技器具の先端を非接触とするべき非接触ターゲットを模し、前記患者の治療対象の歯、歯茎、及び、歯槽骨と前記非接触ターゲットとの位置関係と同じ位置関係に、前記模型本体に設けられる、ターゲット模型部と、
前記患者の3次元立体画像に基づいて、前記模型本体における前記患者の治療対象の歯茎及び歯槽骨を模した位置に、前記治療対象に対する埋設体を埋設可能な孔を模して形成され、前記患者の3次元立体画像における前記孔に対し3次元立体画像における前記手技器具が嵌まり、前記3次元立体画像において前記手技器具が前記孔に挿入されたときに、前記手技器具と前記ターゲットとの間の位置関係を歯科医師に視認可能とする、孔部と、
を備え、
前記ターゲット模型部に、手技前検証時に前記手技器具が接触した場合、接触したことを知らしめるための流体が内蔵されている、歯科治療計画の手技前検証用の模型。
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US18/575,960 US20240335265A1 (en) | 2021-10-25 | 2021-11-10 | Osteotome for dental treatment, hole formation instrument, test post, stopper extension, periodontal ligament guard, water flow tube, and model for pre-procedural verification of dental treatment plan |
EP21962542.3A EP4424270A1 (en) | 2021-10-25 | 2021-11-10 | Osteotome for dental treatment, hole formation instrument, test post, stopper extension, periodontal ligament guard, water flow tube, and model for pre-procedural verification of dental treatment plan |
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