CN116269872A - Diagnostic prosthesis for full-course digital intelligent occlusion reconstruction and manufacturing method thereof - Google Patents

Abstract

The invention discloses a method for manufacturing a diagnostic prosthesis for full-process digital intelligent occlusion reconstruction and the diagnostic prosthesis obtained by the manufacturing method, which is characterized in that the diagnostic prosthesis comprises 17, 16, 15 and 14 dental diagnostic prostheses, 13, 12, 11, 21, 22 and 23 dental diagnostic prostheses, 24, 25, 26 and 27 dental diagnostic prostheses, 34, 35, 36 and 37 dental diagnostic prostheses, 33, 32, 31, 41, 42 and 43 dental diagnostic prostheses and 44, 45, 46 and 47 dental diagnostic prostheses. The present invention provides an aesthetically pleasing, toothless diagnostic prosthesis that can be carried away by a single visit to a patient, while not interfering with the need for multiple adjustments of the bite relationship in sequential therapy. The patient can set requirements for aesthetic effect of front teeth and overall occlusion relation at any time, reduce the number of re-diagnosis, improve the communication efficiency of doctors and patients and reduce the expenditure of various medical materials.

Description

Diagnostic prosthesis for full-course digital intelligent occlusion reconstruction and manufacturing method thereof

Technical Field

The present invention relates to a diagnostic prosthesis and a method for producing the same.

Background

Patients with severe dentition abrasion due to gastroesophageal reflux, acidic food or drink, night-time teeth or congenital enamel hypoplasia need full-mouth bite reconstruction to restore the patient's chewing, pronunciation, aesthetic appearance and relief of symptoms such as temporomandibular joint discomfort. The three stages of wearing the removable bite block, wearing the diagnostic prosthesis and wearing the final prosthesis are generally experienced during the full-mouth bite reconstruction/elevation treatment, and functional design and aesthetic requirements are continuously adjusted and verified in the first two stages to improve the success rate of the final prosthesis.

During sequential treatment of bite reconstruction/elevation, the process of removable bite pads and donning the diagnostic prosthesis is critical, which is typically over 3 months. Firstly, continuously adjusting newly established occlusion position relation by using the removable bite pad, changing the removable bite pad into a diagnostic prosthesis after a patient adapts to the new position relation, and verifying, fine-tuning and determining the beautiful requirements of the patient in the mouth of the patient. However, the conventional procedure described above has the following problems:

first), the occlusal plate in the traditional process has larger volume, no tooth appearance, poor aesthetic property, strong foreign body sensation of patients and low wearing willingness. At the same time, the bite plate needs to be worn for at least 12 hours every day, which brings great inconvenience to patients.

Second), the patient also needs to replace the diagnostic prosthesis after adapting to the bite site, communicate with the physician and then determine the anterior tooth profile. The need to replace the diagnostic prosthesis again if the aesthetic effect is not satisfactory increases the number of re-diagnoses of the patient, the working time of the oral technician and the oral physician, and increases the medical expenditure.

Third), in the traditional process, there are at least two transfer processes of the occlusion relationship, the patient goes through the transition from the occlusal pad to the diagnostic prosthesis and then from the diagnostic prosthesis to the final prosthesis, each time the record and transfer of the occlusion relationship are increased, the deviation of the position record of the final prosthesis is reduced, and the number of times of the re-diagnosis and the total time of the visit of the patient are increased.

Fourth), the traditional procedure is a semi-digitizing process, and transferring the already adapted bite plate relationship in the patient's mouth to the diagnostic prosthesis also increases the errors of the digitizing procedure, negatively affecting the accuracy of the final prosthesis.

Fifth), conventional diagnostic prostheses (temporary prostheses) require dental preparation procedures on patients, and many patients fear of grinding teeth, resulting in discontinuation of the bite reconstruction procedure before the diagnostic prostheses are worn after the bite plate treatment, requiring a simple, easy-to-wear, less damaging diagnostic prosthesis to give the patient sufficient confidence to enter the subsequent treatment session.

Disclosure of Invention

The purpose of the invention is that: provided is a diagnostic prosthesis which can reduce the number of times of patient re-diagnosis, improve the efficiency of patient hospitalization, and enhance the wearing feeling of a patient. It is another object of the present invention to provide a method of making such a diagnostic prosthesis.

In order to achieve the above purpose, the technical scheme of the invention is to provide a manufacturing method of a diagnostic prosthesis for full-process digital intelligent occlusion reconstruction, which is characterized by comprising the following steps:

step 1, after collecting intraoral and extraoral data of a current patient, designing and recording a new occlusion relationship of the current patient based on the intraoral and extraoral data;

step 2, in the oral cavity digital software, tooth data base is utilized to arrange teeth under the new occlusion relation recorded in the step 1, and static function requirements, dynamic function requirements and aesthetic requirements are met during tooth arrangement, wherein:

in order to meet the static function requirement, the plane-fitting inclination is designed in a targeted manner during the engagement design so as to achieve a harmonious state of functions and structures;

by satisfying the dynamic functional requirements, the diagnostic prosthesis is enabled to function properly during dynamic occlusion, including proper lateral and anterior motions, wherein: the correct lateral movement means that when the mandible is bitten laterally, the upper and lower teeth of the working side and the premolars are uniformly contacted/the upper and lower teeth of the working side are contacted, and the upper and lower teeth of the non-working side are not contacted; the correct forward extension movement means that when the mandible is in forward extension movement, the functions of the upper front teeth and part of the cuspids play a role in guiding the lower front teeth, and the rear teeth are separated from occlusion contact, so that occlusion interference of the rear teeth is avoided, and protection of the mandible is realized;

in order to meet aesthetic requirements, carrying out facial scanning on a current patient to obtain a maxillofacial digital model, simultaneously carrying out intraoral scanning on the current patient to obtain a dentition digital model, and combining maxillofacial data of the current patient, registering and reproducing a maxillofacial three-dimensional structure of the patient in software, thereby realizing analysis on the face of the patient and designing tooth shapes, sizes, positions and arrangements which meet aesthetic standards;

step 3, designing a sectional diagnostic prosthesis digital model in oral cavity digital software according to the occlusion relation determined in the step 2, and further comprising the following steps:

step 301, setting the positioning direction of the diagnostic prosthesis at a certain included angle with the dislocation force direction and drawing outline high-point lines of the remained teeth in the direction according to the design principle of the removable partial denture, determining new model data by utilizing the tooth database to arrange 17, 16, 15 and 14 teeth in the occlusion relation determined in step 2, automatically calculating the diagnostic prosthesis model data by utilizing Boolean operation, and selecting the edge thickness to be 0.5-1mm, thereby obtaining 17, 16, 15 and 14 teeth diagnostic prosthesis digital models;

step 302, repeating the method described in step 301 5 times, and respectively making 13, 12, 11, 21, 22 and 23 dental diagnostic prosthesis digital models, 24, 25, 26 and 27 dental diagnostic prosthesis digital models, 34, 35, 36 and 37 dental diagnostic prosthesis digital models, 33, 32, 31, 41, 42 and 43 dental diagnostic prosthesis digital models and 44, 45, 46 and 47 dental diagnostic prosthesis digital models, so as to finally obtain six sections of diagnostic prosthesis digital models;

and 4, manufacturing six-section diagnostic prosthesis objects according to the six-section diagnostic prosthesis digital model obtained in the step 3.

Preferably, in step 2, in order to meet the static function requirement, when designing the engagement: reducing the occipital slope for patients with excessive occipital slope; the occipital slope is increased for patients with too small an occipital slope.

Preferably, in step 2, to meet the static function requirement, an occlusal surface inclination of about 15 degrees of intersection angle with the occlusal plane of the orbit ear is designed according to CBCT data of the patient, the intercommissural distance is halved, and the prosthesis is designed to restore the occlusal plane of the patient.

Preferably, in step 2, to obtain correct lateral movement, the occlusion of the current patient is simulated by computer aided design software, and during the simulation, the shape, slope, contact points of the diagnostic prosthesis digital model are adjusted to achieve the desired occlusion function by observing the diagnostic prosthesis digital model in the dynamic occlusion and virtual occlusion.

Preferably, in step 2, in order to obtain the correct forward extension movement, the posterior teeth are provided with a multi-point stable contact during the dental cusp interlacing, and are coordinated with the condyloid slope after determining the tangential slope and the dental cusp slope, so that the dental cusp height is ensured, and the posterior teeth are separated from the occlusal contact during the forward extension occlusion.

Preferably, in step 2, the personalized occlusion parameters of the current patient are obtained through the electronic facebow, and the mandibular function motion track of the patient is digitally reproduced by using the virtual fitting frame, so that the tooth morphology and occlusion are adjusted, complications possibly occurring in occlusion reconstruction are avoided, and the correct protrusion motion is obtained.

Preferably, in step 301, the new shell tooth socket data is generated by boolean operation and then compared with the contour high-point line, if the new shell tooth socket data edge is in the contour high-point line crown direction, the diagnostic prosthesis model data is obtained without processing, and if the new shell tooth socket data edge is in the contour high-point line gingiva direction, the contour high-point line is taken as the edge to finally obtain the diagnostic prosthesis model data.

Preferably, in step 4, the six-section diagnostic prosthesis object is directly manufactured according to the six-section diagnostic prosthesis digital model obtained in step 3, or after the six-section diagnostic prosthesis digital model obtained in step 3 is printed, the six-section diagnostic prosthesis object is manufactured by adopting an additive or subtractive method.

The invention also provides a diagnostic prosthesis for full-process digital intelligent occlusion reconstruction, which is characterized by comprising 17, 16, 15 and 14 dental diagnostic prostheses, 13, 12, 11, 21, 22 and 23 dental diagnostic prostheses, 24, 25, 26 and 27 dental diagnostic prostheses, 34, 35, 36 and 37 dental diagnostic prostheses, 33, 32, 31, 41, 42 and 43 dental diagnostic prostheses and 44, 45, 46 and 47 dental diagnostic prostheses.

The present invention provides an aesthetically pleasing, toothless diagnostic prosthesis that can be carried away by a single visit to a patient, while not interfering with the need for multiple adjustments of the bite relationship in sequential therapy. The patient can set requirements for aesthetic effect of front teeth and overall occlusion relation at any time, reduce the number of re-diagnosis, improve the communication efficiency of doctors and patients and reduce the expenditure of various medical materials.

Drawings

FIG. 1 is a flow chart of a method of making the present disclosure;

FIG. 2 illustrates a segmented diagnostic prosthesis designed according to outline high-point lines (FIG. 2 illustrates only a partial effect);

FIG. 3 illustrates a physical object of a segmented diagnostic prosthesis made of a subtractive material;

fig. 4 illustrates the wearing effect of the segmented diagnostic prosthesis provided by the present invention.

Detailed Description

The invention will be further illustrated with reference to specific examples. It is to be understood that these examples are illustrative of the present invention and are not intended to limit the scope of the present invention. Further, it is understood that various changes and modifications may be made by those skilled in the art after reading the teachings of the present invention, and such equivalents are intended to fall within the scope of the claims appended hereto.

Referring to fig. 1, the method for manufacturing a diagnostic prosthesis for full-process digital intelligent occlusion reconstruction disclosed in this embodiment specifically includes the following steps:

step 1, collecting intraoral and extraoral data of a patient, including but not limited to: facial scan data, upper and lower dentition, bite data, and bite relationship recorded by electronic facebow, CBCT data (including but not limited to patient alveolar bone and tooth data recorded by CBCT).

Step 2, designing and recording a new occlusion relationship by adopting various conventional medical means known to a person skilled in the art based on the intraoral data and the extraoral data of the patient acquired in the step 1.

Step 3, in digital software commonly used by those skilled in the art, teeth are arranged in the new occlusion relationship recorded in step 2 by using a tooth database.

In this embodiment, the aforementioned digitizing software commonly used by those skilled in the art includes, but is not limited to, conventional oral digitizing software such as 3shape, exocad, planmeca.

When teeth are arranged in a new occlusion relationship, the static function requirement, the dynamic function requirement and the aesthetic requirement need to be met, and the specific logic is as follows:

1) Static functional requirements:

the need for diagnostic prostheses to meet functional requirements in the static state is primarily referred to as the correct in-plane slope. The abnormality of the occlusal inclination is related to occurrence of dentition abrasion and distribution of abrasion, and the occlusal inclination is designed in a targeted manner in order to achieve a state of functional and structural harmony, wherein: patients with excessive occlusal inclination are prone to posterior tooth wear, and the occlusal inclination needs to be reduced; patients with too small a occipital slope are prone to anterior tooth wear, requiring an increase in occipital slope.

After determining the treatment plan, the doctor and technician can design an occlusal slope at an angle of about 15 degrees to the orbital auricular occlusal plane (FH occlusal plane) based on the CBCT data of the patient, bisect the interocclusal distance and design a prosthesis to restore the patient's occlusal plane.

2) Dynamic functional requirements:

the need for a diagnostic prosthesis to meet the functional requirements under dynamic conditions mainly means that the prosthesis is able to function correctly during dynamic occlusion, including correct lateral and anterior movements. The lateral movement is designed into double-sided group tooth function or cuspid guiding combination: refers to the uniform contact (group tooth function fit) of upper and lower teeth of the working side and the contact (cuspid guide fit) of upper and lower teeth of the working side when the mandible is engaged laterally, and the non-working side upper and lower rear teeth are not contacted. The physician can simulate the patient's bite with computer aided design software using the above-described acquired digitized information. During simulation, doctors and technicians can achieve the desired dental occlusion by observing the prosthesis in the dynamic occlusion and virtual occlusion frames, adjusting the prosthesis shape, slope, contact points.

The reasonable forward extension movement means that when the mandible is in forward extension movement, the functions of the upper front teeth and part of the cuspids play a role in guiding the lower front teeth, and the rear teeth are separated from occlusion contact, so that occlusion interference of the rear teeth is avoided, and protection of the mandible is realized. If the posterior teeth are contacted when the mandible is extended forwards, the posterior teeth are subjected to lateral force, periodontal damage occurs, and related injuries of temporomandibular joints, such as excessive contraction of masticatory muscles, abrasion of condyles and the like, are caused. Therefore, in the process of designing the prosthesis, the rear teeth have stable contact at multiple points when the tooth tips are staggered, and coordinate with the condyloid slope after the cutting slope and the tooth tip slope are determined, so that the tooth tip height is ensured, and the rear teeth are separated from occlusion contact when the front teeth are engaged. In order to achieve the aim, the personalized occlusion parameters of a patient are obtained through the electronic facial arch, and the mandibular function movement track of the patient is digitally reproduced by utilizing the virtual combination frame in software, so that the tooth morphology and occlusion are adjusted, and complications possibly occurring in occlusion reconstruction are avoided.

3) Aesthetic requirements:

bite reconstruction includes aesthetic reconstruction in addition to functional reconstruction. Tooth morphology, size, location and arrangement designed to meet aesthetic criteria are targets for aesthetic reconstruction. Analysis of a patient's face, i.e. "face guidance", is critical to personalized aesthetic repair. The 4 important factors affecting anterior tooth aesthetics are incisor edge position in the upper jaw, clinical crown length ratio, gingival margin position and upper anterior tooth width ratio. It is worth noting that in addition to the coordination of gums and teeth, the profile of the anterior teeth needs to be adapted to the contours of the patient's face, lips, etc. In the traditional method, doctors carry out aesthetic reconstruction design after obtaining data through the ways of observing the face of a patient, taking out-of-mouth pictures, preparing research models and the like. In the invention, the face of a patient is scanned to obtain a maxillofacial digitized model, and simultaneously, the intraoral scanning is performed to obtain a dentition digitized model. And combining the CBCT data of the jaw of the patient, and registering in software to reproduce the three-dimensional structure of the jaw face of the patient. Therefore, the front tooth aesthetics can be more intuitively and comprehensively designed, and communication with a patient in terms of final aesthetic restoration effect is facilitated.

Step 4, designing a segmented diagnostic prosthesis in digital software according to the occlusion relation determined in the step 3, and further comprising the following steps:

and step 401, setting the positioning direction of the diagnostic prosthesis and drawing outline high-point lines on the residual teeth by following the design principle of the removable partial denture and forming a certain included angle with the dislocation force direction, utilizing a tooth database to arrange 17, 16, 15 and 14 teeth under the occlusion relation determined in the step 3, determining new model data, performing spatial subtraction on the new model data and the original tooth data by using Boolean operation, generating new empty shell tooth socket data, comparing the new empty shell tooth socket data with the outline high-point lines after generating the new empty shell tooth socket data, if the edge of the new empty shell tooth socket data is in the outline high-point line crown direction, not processing the new empty shell tooth socket data, and if the edge of the new empty shell tooth socket data is in the outline high-point line gingiva direction, taking the outline high-point line as the edge, and selecting the edge thickness to be 0.5-1mm, thereby obtaining the 17, 16, 15 and 14 tooth position diagnostic prosthesis digital model.

Step 402, the method described in step 401 is repeated 5 times to prepare 13, 12, 11, 21, 22, 23 dental diagnostic prosthesis digital models, 24, 25, 26, 27 dental diagnostic prosthesis digital models, 34, 35, 36, 37 dental diagnostic prosthesis digital models, 33, 32, 31, 41, 42, 43 dental diagnostic prosthesis digital models and 44, 45, 46, 47 dental diagnostic prosthesis digital models, respectively, and finally obtain six-segment diagnostic prosthesis digital models as shown in fig. 2.

And 5, directly manufacturing the six-section diagnostic prosthesis according to the six-section diagnostic prosthesis digital model obtained in the step 5, or printing the six-section diagnostic prosthesis digital model obtained in the step 5, and manufacturing the six-section diagnostic prosthesis by using manufacturing methods well known to those skilled in the art such as silicone rubber turnover mould and the like by adopting an additive adding or material subtracting method, as shown in fig. 3.

And 6, fitting and fine blending in the mouth, and cementing the diagnostic prosthesis, wherein the wearing effect is shown in figure 4.

The invention divides the diagnostic prosthesis into six sections, and determines the edge of the prosthesis according to the contour of the dented dentition, has the advantages of ensuring that the interior of the prosthesis has no undercut, being capable of being positioned in the straight joint, simultaneously having retention force in the direction of disengaging from the occlusal position, and improving the retention rate of the prosthesis in the mouth.

Claims (9)

1. The manufacturing method of the diagnostic prosthesis for full-process digital intelligent occlusion reconstruction is characterized by comprising the following steps of:

step 1, after collecting intraoral and extraoral data of a current patient, designing and recording a new occlusion relationship of the current patient based on the intraoral and extraoral data;

step 2, in the oral cavity digital software, tooth data base is utilized to arrange teeth under the new occlusion relation recorded in the step 1, and static function requirements, dynamic function requirements and aesthetic requirements are met during tooth arrangement, wherein:

in order to meet the static function requirement, the plane-fitting inclination is designed in a targeted manner during the engagement design so as to achieve a harmonious state of functions and structures;

by satisfying the dynamic functional requirements, the diagnostic prosthesis is enabled to function properly during dynamic occlusion, including proper lateral and anterior motions, wherein: the correct lateral movement means that when the mandible is bitten laterally, the upper and lower teeth of the working side and the premolars are uniformly contacted/the upper and lower teeth of the working side are contacted, and the upper and lower teeth of the non-working side are not contacted; the correct forward extension movement means that when the mandible is in forward extension movement, the functions of the upper front teeth and part of the cuspids play a role in guiding the lower front teeth, and the rear teeth are separated from occlusion contact, so that occlusion interference of the rear teeth is avoided, and protection of the mandible is realized;

in order to meet aesthetic requirements, carrying out facial scanning on a current patient to obtain a maxillofacial digitized model, simultaneously carrying out intraoral scanning on the current patient to obtain a dentition digitized model, and combining with the current patient's jaw CBCT data, registering and reproducing the patient's maxillofacial three-dimensional structure in software, thereby realizing analysis on the patient's face and designing tooth morphology, size, position and arrangement which meet aesthetic standards;

step 3, designing a sectional diagnostic prosthesis digital model in oral cavity digital software according to the occlusion relation determined in the step 2, and further comprising the following steps:

step 301, setting the positioning direction of the diagnostic prosthesis and drawing outline high-point lines on the remained teeth by following the design principle of the removable partial denture and forming a certain included angle with the dislocation force direction, determining new model data by utilizing tooth databases to arrange 17, 16, 15 and 14 teeth in the occlusion relation determined in the step 2, automatically calculating the diagnostic prosthesis model data by utilizing Boolean operation, and selecting the edge thickness to be 0.5-1mm, thereby obtaining 17, 16, 15 and 14 teeth diagnostic prosthesis digital models;

step 302, repeating the method described in step 301 5 times, and respectively making 13, 12, 11, 21, 22 and 23 dental diagnostic prosthesis digital models, 24, 25, 26 and 27 dental diagnostic prosthesis digital models, 34, 35, 36 and 37 dental diagnostic prosthesis digital models, 33, 32, 31, 41, 42 and 43 dental diagnostic prosthesis digital models and 44, 45, 46 and 47 dental diagnostic prosthesis digital models, so as to finally obtain six sections of diagnostic prosthesis digital models;

and 4, manufacturing six-section diagnostic prosthesis objects according to the six-section diagnostic prosthesis digital model obtained in the step 3.

2. The method for manufacturing a diagnostic prosthesis for full-process digital intelligent occlusion reconstruction according to claim 1, wherein in step 2, in order to meet the static function requirement, during occlusion design: reducing the occipital slope for patients with excessive occipital slope; the occipital slope is increased for patients with too small an occipital slope.

3. The method of claim 1, wherein in step 2, to meet the static functional requirement, designing an occlusal surface slope of about 15 degrees from the occlusal plane of the orbit ear according to CBCT data of the patient, bisecting the interocclusal distance and designing the prosthesis to restore the occlusal plane of the patient.

4. The method of claim 1, wherein in step 2, to obtain correct lateral movement, the occlusion of the current patient is simulated by computer aided design software, and during the simulation, the shape, inclination and contact point of the digital model of the diagnostic prosthesis are adjusted by observing the digital model of the diagnostic prosthesis in the dynamic occlusion and virtual occlusion frames to achieve the ideal dental occlusion.

5. The method of claim 1, wherein in step 2, in order to obtain a correct forward motion, the posterior teeth have stable contact at multiple points during the tooth tip interlacing, and coordinate with the condylar canal slope after determining the tangential slope and the tooth tip slope, thereby ensuring the tooth tip height and ensuring that the posterior teeth are out of occlusion contact during the forward biting.

6. The method for manufacturing a diagnostic prosthesis for full-process digital intelligent occlusion reconstruction according to claim 1, wherein in step 2, the personalized occlusion parameters of the current patient are obtained through an electronic facebow, and the mandibular function motion track of the patient is digitally reproduced by using a virtual fitting frame, so that the tooth morphology and occlusion are adjusted, complications possibly occurring in occlusion reconstruction are avoided, and the correct protrusion motion is obtained.

7. The method for manufacturing a diagnostic prosthesis for full-process digital intelligent occlusion reconstruction according to claim 1, wherein in step 301, a new empty shell dental socket data is generated by using boolean operation and then compared with the contour high-point line, if the new empty shell dental socket data edge is in the contour high-point line crown direction, the diagnostic prosthesis model data is obtained without processing, and if the new empty shell dental socket data edge is in the contour high-point line gingiva direction, the contour high-point line is taken as the edge to finally obtain the diagnostic prosthesis model data.

8. The method for manufacturing the diagnostic prosthesis for the full-process digital intelligent occlusion reconstruction according to claim 1, wherein in the step 4, six sections of diagnostic prosthesis objects are manufactured directly according to the six sections of diagnostic prosthesis digital models obtained in the step 3, or after the six sections of diagnostic prosthesis digital models obtained in the step 3 are printed, six sections of diagnostic prosthesis objects are manufactured by adopting an additive or subtractive method.

9. A diagnostic prosthesis for full-process digital intelligent occlusion reconstruction, which is manufactured by the method of claim 1 and comprises 17, 16, 15 and 14 dental diagnostic prostheses, 13, 12, 11, 21, 22 and 23 dental diagnostic prostheses, 24, 25, 26 and 27 dental diagnostic prostheses, 34, 35, 36 and 37 dental diagnostic prostheses, 33, 32, 31, 41, 42 and 43 dental diagnostic prostheses and 44, 45, 46 and 47 dental diagnostic prostheses.

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