JP2019030677A - Multiple bite configuration - Google Patents

Abstract

To provide a system and method of digitally designing a dental component for a patient.SOLUTION: A method of digitally designing a dental component for a patient includes: obtaining a 3D representation of the patient's upper jaw; obtaining a 3D representation of the patient's lower jaw; obtaining at least a first 3D representation of a first bite configuration of the patient's jaws in a first occlusion and a second 3D representation of a second bite configuration of the patient's jaws in a second occlusion different from the first occlusion; digitally determining an occlusal contact movement of the patient's jaws relative to each other on the basis of the at least first 3D representation, the second 3D representation and contact between the patient's upper jaw and lower jaw; and digitally designing the dental component on the basis of the occlusal contact movement of the patient's jaw relative to each other.SELECTED DRAWING: None

Description

The present invention generally relates to a system and method for digitally designing a dental component of a patient.
More specifically, the present invention relates to the design of dental parts by obtaining various bites of the patient's jaws.

In dentistry, occlusion relates to tooth movement when teeth come in contact and artificial tooth arrangement that simulates natural teeth.
For example, as described in “Oxford Dictionary of Dentry”, first edition, 2010, ISBN 978-0-19-953301-5,
Occlusion: noun, 1. 1. Integrated movement when upper and lower teeth come into contact; Artificial tooth arrangement that mimics a natural dentition, and occlusion described in “Dorland's Illustrated Medical Dictionary”, 32nd edition, 2012, ISBN 978-1-4160-6257-8: [. ..] 4. In dentistry, (a) contact relationship of the occlusal surface of the moving tooth; (b) refer to an artificial tooth arrangement that fits the various positions of the mouth and serves the purpose of the natural tooth that is to be replaced by the artificial tooth That.

It is important to maintain occlusion when designing repair aids such as artificial teeth, crowns, bridges, and dentures.
If the occlusion is not accurate, the patient may experience reduced occlusal function, discomfort, and / or pain, and the repair aid may be cracked or damaged.

The use of so-called articulators is very common when designing repair aids manually.
However, there are various models and designs of articulators, and what is common to all articulators is that the articulator is used to simulate the articulation.
The articulator has an upper part with an upper jaw model and a lower part with a lower jaw model.
Its upper and lower parts can move relative to each other within certain limits.
Such restrictions, or at least some of those restrictions, can be adjusted by a variety of users to allow adjustment by the user and thereby achieve a better simulated reproduction of the patient's occlusion. Present in the articulator.
Adjustable limits, often referred to as articulator parameters, can be measured and obtained in various ways.
An example of such an articulator parameter is the articulator axis on which the maxillary and mandibular models rotate, in which case the facebow is often used to accurately position those models relative to this axis. The
Other such parameters can be, for example, condylar guidance, Bennett angle and Bennett shift.

However, with the introduction of 3D scanners and 3D printers in dental clinics and dental laboratories, the design of dental repair aids using CAD / CAM software is becoming very common.
Virtual articulators that simulate the physical articulator have been introduced in a number of applications, and many different ways of setting and determining virtual articulator parameters are being described.

  For example, U.S. Patent No. 6,057,056 discloses a method and apparatus for determining the patient's maxillary and mandibular axis and, in particular, using computerized visual images to model jaw movement about such axis. Please refer to.

However, the introduction of digital tools such as CAD / CAM software makes it possible to determine the occlusion in a great variety of ways.
Therefore, this specification does not use software to establish articulator parameters to simulate the occlusion of a physical simulator (physical articulator) with a digital simulation (virtual articulator). Directly estimating the occlusion and movement specific to the patient, or using a digital tool to directly simulate the occlusion and movement.

There are also so-called electronic facebows.
An electronic facebow is attached to the patient's face and records jaw movements.
An example of such an electronic facebow is the Zebulis Dental GmbH JMA system, which uses ultrasound to record jaw movements.
However, such electronic facebows are often time consuming to prepare, and the only use of electronic facebows is to detect jaw movements, which can be used to obtain electronic facebows. Is expensive.

  Thus, the present specification further determines patient-specific movements that are used for other purposes in dental clinics and dental laboratories and that are easier to apply and use the increasingly common hardware. Regarding alternative methods.

US Pat. No. 6,582,229

A method for designing a dental component of a patient comprising:
Obtaining a three-dimensional representation of the patient's upper jaw;
Obtaining a three-dimensional representation of the patient's lower jaw;
A first three-dimensional representation of a first occlusion of both jaws of the patient at least in a first occlusion and a second three-dimensional representation of a second occlusion of both jaws of the patient in a second occlusion different from the first occlusion Step to get the
Digitally determining an occlusal contact movement of the patient's jaws relative to each other based on the at least first three-dimensional representation, the second three-dimensional representation, and contact between the patient's upper and lower jaws;
Digitally designing the dental member based on the occlusal contact movement of the patient's jaws relative to each other.

As a result, it is advantageous that a physically or spatially possible movement or movement of the patient's jaws can be estimated based on at least two bites.
In particular, the occlusal contact movement is an appropriate movement to maintain when designing repair aids and other dental components to avoid pain and discomfort to the patient, so estimate the occlusal contact movement It is an advantage to do.
Advantageously, the occlusal contact movement can be recorded.
This allows the motion to be visualized later to design the dental component or to be replayed later to use the motion.

The bite need not necessarily include the full bite of the upper and lower jaws.
Advantageously, only a part of the actual occlusion is used for the three-dimensional representation of each of those engagements.
This saves time and is particularly advantageous when using an intraoral scanner.
The application of current methods using an intraoral scanner is further discussed herein.

Each 3D representation of the bite can be used to align the 3D representation of the patient's upper jaw with the 3D representation of the patient's lower jaw.
Therefore, when the occlusal contact movement of both jaws is determined, the movement can be imaged on the monitor using the occlusal contact movement.

Such alignment is well known in the art.
Typically, such an alignment is provided by an initial alignment and subsequent optimization by using, for example, an ICP (Iterative Closest Point) algorithm.
For further information see, for example, Paul J. et al. Besl and Neil D. McKay, Proc. See “Methods for registration of 3-D shapes” in SPIE, Vol. 1611, Sensor Fusion IV: Control Paradigms and Data Structures, page 586 (April 30, 1992).
In particular, this alignment is advantageous because dental members, such as repair aids or orthodontic appliances, can be designed based on the determined occlusal contact movement of the upper and lower jaws relative to each other.

  In one embodiment, when the dental member is inserted into the patient, the dental member should be designed to maintain the determined occlusal contact motion, so the design when designing the dental member This alignment can be done by using the teeth of the three-dimensional representation of the patient's jaws as a reference.

For example, a tooth in a three-dimensional representation of a patient's jaw during an occlusal contact movement can be used to define a reference reference, for example by tracing a face or boundary, which affects the occlusal contact movement The boundary is defined so that a dental member can be designed that is not, and thus maintains a movement specific to the patient even after the restoration operation.
At the same time, with proper contact of elements such as dental repair aids by regenerating the contact movement and adjusting the repair aid to ensure proper contact and function of the repair aid during exercise. The occlusal contact movement can be used for functional design.

For example, the designer can design the dental member such that at least one contact area is provided between the dental member and the reference reference.
Thus, when inserted into the patient's mouth, occlusal contact is achieved for the dental member and the corresponding tooth or repair aid.
This can be used by a dental member such as a repair aid to schedule a suitable occlusal function that supports dynamic occlusion.

In an alternative embodiment, the motion itself can be used as a boundary.
For example, when a dental member is placed on the lower jaw, the upper jaw essentially prevents the occlusal contact movement from being accurately reproduced from the dental member while regenerating the occlusal contact movement. It can be treated as a solid object that cuts or deletes an object.
Alternatively, such an overlap can be identified, for example, by marking the overlap in red, so it is up to the designer to decide whether the area should be removed or redesigned.

As implied by the expression, an occlusal contact movement is a movement of both jaws in which at least one contact area between the upper jaw (upper jaw) and lower jaw (lower jaw) teeth is maintained.
This movement is often called dynamic occlusion.

  To determine or estimate the occlusal contact movement of the patient's jaws relative to each other, for example, 3, 4, 5, 6, 7, 8, 9, 10, etc. Occlusion can be required.

The bite can be recorded using an intra-oral 3D scanner such as the 3Shapes TRIOS scanner.
The dentist asks the patient to engage the upper and lower jaws, and while the patient is engaged in the first position, the dentist scans the patient's teeth with an intraoral scanner to obtain the first three-dimensional representation To do.
Next, the dentist asks the patient to re-engage the upper and lower jaws, and while the patient is engaged in the second configuration, the dentist performs scanning of the patient's teeth with an intraoral scanner and performs the second tertiary. Get the original expression.
If more occlusion is desired or necessary to determine the occlusal contact movement of the jaws relative to each other, the dentist asks the patient to do the third, fourth, fifth etc. occlusion Scanning for.

In one embodiment, the digital determination of the occlusal contact movement includes at least two three-dimensional representations of the patient's jaw occlusion at each successive series of occlusions.
By continuously photographing such a series of meshing, it is possible to directly acquire a real motion without performing any estimation or interpolation between the meshing.

Such a series of bites can be obtained, for example, by holding a scanner, such as the TRIOS scanner described above, against the patient's teeth while the patient moves both jaws in an occlusal contact movement.
The TRIOS is then set to record a series of three-dimensional scans during the occlusal contact movement.
Each 3D scan can then be used to align the upper and lower jaws, after which the upper and lower jaws are each in an order corresponding to the order in which the meshing was acquired during successive recordings of the 3D scan. Can be presented in alignment.
Thus, in some embodiments, the method includes using an intraoral scanner to obtain a three-dimensional representation of multiple bites of the patient's jaw.

This is particularly advantageous in embodiments such as those described above where a three-dimensional representation of a plurality of meshes is recorded as a series of consecutive frames.
For example, the frames can be used to create an animation that shows both jaw movements.
The frame may advantageously be a three-dimensional frame, i.e. a frame in which the upper and lower jaws are aligned with respect to the respective engagement of the upper and lower jaws, thereby rotating the three-dimensional representation of the upper and lower jaws. it can.
However, those frames can alternatively be two-dimensional images.

In particular, in one embodiment, if a three-dimensional representation of the mesh is obtained at a sufficiently short interval to create an occlusal contact motion with sufficiently high resolution for a given application, the three-dimensional representation of multiple meshes Alternatively, the occlusal contact motion can be determined directly using a three-dimensional representation of a series of consecutive bites.
Therefore, the occlusal contact motion of the three-dimensional representation has been adapted to be played back as a video stream.

  Also, in one embodiment, the speed can be varied when replaying the occlusal contact movement, for example by showing the upper and lower jaws moving relative to each other in a virtual environment, for example the occlusal contact movement in slow motion Can show.

As understood above and as further clarified, the method described herein thus allows an intraoral scanner to obtain a three-dimensional representation of both jaws and the bite product. Are particularly advantageous for use with this intraoral scanner.
Also, dentists or dental technicians use intraoral scanners for many other purposes, and thus intraoral scanners are instruments that are becoming very versatile in their use.

Occlusion can also be obtained by the dentist taking a physical impression using different impressions in the patient's mouth for different occlusions.
The impressions should then be scanned, for example with a 3D desk scanner, in order to later obtain a 3D representation of these different meshes.

The method of digitally designing a dental component is usually performed by a dental technician using a software CAD program such as 3Shape's Dental System CAD software running on a computer.
The dental technician usually obtains various three-dimensional representations, ie the patient's maxillary, mandibular, first and second meshing representations as computer files and then loads these files into a software program The occlusal contact movements of the patient's jaws can then be determined automatically by a software program or digitally by a dental technician.
The dental technician can then design the dental member, or the member can be designed automatically by a software program.

When a dentist performs scanning using an intraoral 3D scanner, various 3D representations can be acquired from the dentist as computer files.
If physical impressions are created, the dental technician can scan the impressions themselves in the dental laboratory, then obtain the 3D representation obtained by the scanning as a computer file and use a software CAD program Can be loaded into a computer for use in
The method can be a computer-implemented method.

  In some embodiments, the digital determination of the occlusal contact movement of the patient's jaws relative to each other includes interpolating the movement between the measured bite.

In one embodiment, the interpolation is a linear interpolation of both jaw positions and rotations / angles over multiple steps.
The number of steps may be determined based on the number of three-dimensional representations of the occlusal harvest and / or the distance between the three-dimensional representations of the bite harvest.
Increasing the number of steps results in occlusal contact motion with higher resolution, however, greater processing power is required.

In some embodiments, the interpolation includes performing a rigid transformation.
In some embodiments, the interpolation includes performing a linear transformation.
In some embodiments, the interpolation includes performing a non-linear transformation.
In some embodiments, the interpolation is a combination of linear and non-linear transformations.
In some embodiments, the transformation includes translation and rotation.
In some embodiments, the interpolation is performed for teeth that lie within a known data point from at least the first and second engagements.

If there are teeth along the interpolation path, the interpolation is a non-linear translation and / or rotation.
In other words, to ensure proper contact when tooth collisions occur, i.e. overlapping of those three-dimensional representation regions that are impossible in the physical world are detected during interpolation. Avoid duplication by moving both jaws with interpolation.
Thus, in one embodiment, the method detects, during interpolation, an overlapping region of a patient's upper three-dimensional representation tooth and the patient's lower three-dimensional representation of the tooth, and until no overlapping region is detected. The method further includes separating the three-dimensional representation of the upper jaw of the patient from the three-dimensional representation of the lower jaw of the patient.

Considering the overlap region when interpolating provides a better estimate of the occlusal contact motion and, as a result, a better fit of the designed dental member.
Next, whether there is no occlusal contact between the three-dimensional representations of both jaws can be detected during interpolation in a similar manner.

Thus, in one embodiment, the method detects upon interpolation that there is no overlap area between the teeth of the patient's upper jaw and the teeth of the patient's lower jaw, and at least The method further includes moving together the three-dimensional representation of the patient's upper jaw and the three-dimensional representation of the patient's lower jaw until a contact area is detected.

Separating each jaw or moving together / moving towards each other can be performed linearly.
However, both jaws can be closed (moved together) and opened (released) along the rotational movement.
This can be performed around an initial axis of rotation set by the system or user.
However, it can also be performed on the basis of a physical / biological model in order to obtain a higher accuracy in the determination of the occlusal contact movement.

In some embodiments, the occlusal contact movement of the patient's jaws is forward displacement,
Rearward shift,
Outward dislocation,
Outer-backward dislocation,
Includes inward dislocation and / or immediate sideshift.

In one embodiment, the occlusal contact motion is replayed in the order in which the occlusal contact motion was determined.
For example, first obtain a lateral 3D representation of the occlusal harvest, then obtain a 3D representation of the occlusal harvest during forward transposition, and then obtain a 3D representation of the occlusal harvest after backward transposition. When the occlusal contact motion is determined by obtaining the same, the occlusal contact motion is reproduced in the same order.
This can be slightly different when the occlusal contact movement is reproduced in reverse order due to anatomy such as muscle movement, jaw configuration, etc. Increases sex.

  However, in some embodiments, the risk of losing high accuracy may be acceptable in exchange for being able to reproduce the occlusal contact movement in any order and direction.

In some embodiments, determining the occlusal contact movement of the patient's jaws includes determining the extreme points of the jaw movements.
In some embodiments, at least one of the three-dimensional representations provides constraints on the occlusal contact movement of the patient's jaws.
In some embodiments, the method indicates which occlusion / movement of both jaws is by recorded occlusion and which occlusion / movement of both jaws is by a determined occlusal contact movement including.

In some embodiments, the bite is an overbite bite with contact between at least some of the upper and lower teeth;
Lie / skew bit to the left,
Includes right / skew bite and / or occlusion when the teeth and jaws are in stationary occlusion.

In some embodiments, the engagement includes one or more occlusal records, wherein the occlusal records are a center position and / or a maximum intercuspal position,
right side,
Includes left side and / or front side.

  In some embodiments, at least one of the engagements includes an extreme point of the movement of the jaws.

In some embodiments, the engagement is a maximum outer dislocation,
Maximum inward dislocation,
Maximum immediate side shift,
Maximum outer-backward dislocation,
Including a maximum anterior displacement of the patient and / or a maximum posterior displacement of the patient.

In some embodiments, the dental member is designed for the patient based on the determined occlusal contact movement of the patient's jaws.
In some embodiments, the method comprises an option to alternate between occlusal / movement inspection and imaging of the jaw, which is due to the engagement recorded by the operator during the design of the dental component. Including.
In some embodiments, the dental member is a dental repair aid or orthodontic appliance.
In some embodiments, the dental repair aid is a crown, abutment, bridge, full denture, partial denture, inlay, onlay, and the like.
In some embodiments, the orthodontic appliance is a brace, aligner, retainer, or the like.

In some embodiments, the three-dimensional representation is by intracavity scanning of the patient's teeth and / or by scanning a physical impression of the patient's teeth and / or by scanning a physical model of the patient's teeth. To be acquired.
In some embodiments, the three-dimensional representation is obtained by obtaining a three-dimensional scan.

In some embodiments, the three-dimensional scan is an intraoral scan of at least a portion of a patient's set of teeth, a scan of at least a portion of the patient's set of teeth, and / or a set of the patient's teeth. A scan of at least a portion of a physical model.
In some embodiments, the three-dimensional scan is performed by laser light scanning, LED scanning, white light scanning, fluorescence scanning, probe scanning, X-ray scanning, and / or CT scanning.

In particular, a system for designing a dental component of a patient,
Means for obtaining a three-dimensional representation of the upper jaw of the patient;
Means for obtaining a three-dimensional representation of the lower jaw of the patient;
A first three-dimensional representation of a first occlusion of both jaws of the patient at least in a first occlusion and a second three-dimensional representation of a second occlusion of both jaws of the patient in a second occlusion different from the first occlusion Means for obtaining,
Means for digitally determining an occlusal contact movement of the patient's jaws relative to each other based on the at least first three-dimensional representation, the second three-dimensional representation, and contact between the patient's upper and lower jaws And a means for digitally designing the dental member based on the occlusal contact movement of the patient's jaws relative to each other is disclosed herein.

  Furthermore, the present invention provides a computer program product comprising program code means for causing the data processing system to execute the method according to any one of the preceding embodiments when the program code means is executed on the data processing system, and the program code The present invention relates to a computer program product comprising a computer readable medium having stored means.

Furthermore, the present invention is a computer program configured for performing computer-aided digital design of a dental component of a patient,
Obtaining a three-dimensional representation of the patient's upper jaw;
Obtaining a three-dimensional representation of the patient's lower jaw;
A first three-dimensional representation of a first occlusion of both jaws of the patient at least in a first occlusion and a second three-dimensional representation of a second occlusion of both jaws of the patient in a second occlusion different from the first occlusion To get the
Digitally determining an occlusal contact movement of the patient's jaws relative to each other based on the at least first three-dimensional representation, the second three-dimensional representation, and contact between the patient's upper and lower jaws; and A non-transitory computer readable medium storing the computer program comprising digitally designing the dental member based on the occlusal contact movement of the patient's jaws relative to each other.

The above and / or other objects, features, and advantages of the present invention are further illustrated by the following exemplary, non-limiting details of embodiments of the present invention with reference to the accompanying drawings.
FIG. 6 shows an example of a flow chart of a method for designing a patient dental member in a digital manner. It is a figure which shows the example of various meshing. It is a figure which shows the example of various meshing. It is a figure which shows the example of various meshing. It is a figure which shows the example of various meshing. It is a figure which shows the example of various meshing. It is a figure which shows the example of various meshing. FIG. 4 is a diagram illustrating an embodiment of the present invention in which an occlusal contact motion is determined using interpolation. FIG. 6 is a diagram further illustrating a tooth collision and gap correction method during interpolation in one embodiment of the present invention. FIG. 6 is a diagram further illustrating a tooth collision and gap correction method during interpolation in one embodiment of the present invention. FIG. 6 illustrates an embodiment of a method in which an occlusal contact motion is used to design a dental member, eg, a repair aid.

Reference will be made to the accompanying drawings in the following description. The drawings illustrate the manner in which the invention can be practiced.
FIG. 1 shows an example of a flow diagram of a method for digitally designing a patient's dental component.
In step 101, a three-dimensional representation of the patient's upper jaw is obtained.
In step 102, a three-dimensional representation of the patient's lower jaw is obtained.
In step 103, at least a first three-dimensional representation of the first jaw of the patient's jaws and a second three-dimensional representation of the second jaw of the patient's jaws are obtained.
In step 104, the occlusal contact movement of the patient's jaws relative to each other is determined digitally based on at least the first 3D representation and the second 3D representation.
In step 105, the dental member is designed digitally based on the occlusal contact movement of the patient's jaws relative to each other.

FIG. 2 shows various examples of engagement.
FIG. 2a shows the bite 200 when the patient's upper jaw 201 and lower jaw 202 are in a stationary occlusal state.
FIG. 2 b shows the engagement 200 when the right canine 203 of the patient's upper jaw 201 is in contact with the right canine 204 of the patient's lower jaw 202.
FIG. 2 c shows the meshing 200 when the cutting edge 205 of the front tooth 206 of the upper jaw 201 is in contact with the cutting edge 207 of the front tooth 208 of the lower jaw 202.
FIG. 2d shows an interlock 200 having the most forward shift of both jaws 201, 202 and some lateral shift.
FIG. 2e also shows a mesh 200 that has the most forward dislocation of both jaws 201, 202 and some lateral dislocation, in which case the lateral dislocation differs from FIG. 2d.
FIG. 2f shows an interlock 200 having a strong rearward displacement of both jaws 201,202.

  FIG. 3 shows that five three-dimensional representations of different bites 300, 301, 302, 303, 304 at each bite are acquired, and the movement of the patient's jaws relative to each other is between these three-dimensional representations. An embodiment determined by the interpolation is shown in a schematic diagram.

When considering the direction of motion, especially right and left, that direction is with respect to the patient, especially when reading the description relating to FIGS.
However, the images are presented so that the observer faces the patient. Thus, what is left for the patient is right for the observer and vice versa.

  The movement determined in this embodiment is a natural mastication movement of the patient. A large number of meshes allows the motion to be more accurately determined relative to the natural motion, but it is possible to reasonably obtain the motion with as few as 5 meshes.

  Interlocking is obtained when the upper jaw 310 and the lower jaw 311 are in the central occlusal state 300. This is the patient's natural occlusion. Usually this is also the position where the teeth are in maximum occlusal contact.

Lateral movement of the jaws during occlusion can be determined using central occlusion with left bite 302 where the patient's lower jaw is moved to the left and right bite 301 where the patient's lower jaw is moved to the right.
The lateral movement is then determined by interpolating between the right side bite 301 and the central bite 300 and between the central bite 300 and the left side bite 302.

The interpolation can be linear.
However, dental arch motion usually defines curvilinear motion.
Thus, the side motion can be determined by interpolating along the side curve 305.
Interpolation paths / curves 305, 308, 312 preferably define an average motion resulting from a typical motion of the patient's jaw.

When the system interpolates, it can check the occlusal contact between the lower and upper jaw teeth.
If the system finds that the maxillary and mandibular teeth overlap when moved along the lateral line, the movement opens both jaws and the teeth maintain contact but do not overlap.
Similarly, if the system finds that there is no contact between the teeth, eg, the jaw is open, the movement closes the upper and lower jaws together until contact occurs.
This is further illustrated in FIGS. 4a-4c and 5a-5c.

The opening and closing of both jaws can be a linear movement.
However, the opening and closing of both jaws can also be a rotation around the initial axis.
The initial axis can be set as an initial value by a computer, set by a user, or otherwise determined.
Thus, the side motion 306 is determined when the system interpolates between the meshes along the side curve 305 while maintaining occlusal contact.

Similarly, a posterior shift 307, a posterior movement from the central occlusion to the posterior engagement 303 with the lower jaw retracted, can be determined by interpolating along the posterior displacement curve 308 as described above.
Similarly, the anterior displacement 309, which is the anterior movement of the mandible relative to the upper jaw from the central position occlusion to the anterior engagement 304, can also be determined by interpolating as described along the anterior displacement curve 312.

As can be seen from the determined occlusal motion, the occlusal motion can deviate from the interpolation line, whether it is a lateral motion, a backward motion, or a forward motion.
However, since each point representing each three-dimensional representation of the mesh is a well-known position, those interpolation lines pass through these points.
For improved accuracy, an additional three-dimensional representation of the mesh may be obtained, which has also been mentioned previously.

4 and 5, the way in which the method takes into account overlap and gaps during interpolation will be discussed further.
FIG. 4 a shows a three-dimensional representation of the engagement when the three-dimensional representation of the patient's upper jaw 310 and the three-dimensional representation of the patient's lower jaw 311 are in the central occlusal state 300.
FIG. 4b shows the actual patient specific movement when the lower jaw 311 is moved to the right as indicated by the arrow.
FIG. 4 b shows the placement of the upper and lower jaws during lateral movement between the central bite and the right side bite 301.
The movement is performed while maintaining at least one contact point between the maxillary and mandibular teeth.
These contact points do not necessarily exist in the cross section shown, but can occur between other teeth in the first three-dimensional tooth model.
However, in this case, the contact point 350 exists between the two molar teeth 337 and 327.

Thereafter, the lower jaw 311 is moved in the left direction from the central bite 300 toward the left bite 302 as shown in FIG. 4c.
Similar to FIG. 4 b, FIG. 4 c shows the relative positions of the upper and lower jaws when a contact point 351 exists between the two molars 317 and 347.
Figures 4a, 4b and 4c show the relative positions of the upper and lower jaws during actual patient-specific movement.
Other such cross-sections could be obtained at other points, in other areas, also during side movements or during other movements such as forward or backward shifts.

However, as shown in FIGS. 5a, 5b and 5c, correction may be necessary when using interpolation to determine patient specific motion, ie occlusal contact motion.
FIG. 5 a shows the bite with the upper and lower jaws in the central occlusal state 300.
This engagement is identical to FIG. 4a as recorded for that position.

However, when interpolating between the central occlusal engagement and the right engagement 301, an overlap 352 is detected between the molars 327 and 337 as shown in FIG. 5b corresponding to the position shown in FIG. 4b. The
Therefore, in order to compensate for this overlap, both jaws are separated until there is no overlap area, but to the extent that occlusal contact still exists.
Similarly, as shown in FIG. 5c, which corresponds to the position in FIG. 4c, there is no contact between the upper and lower jaws as a result of the interpolation.
Therefore, the jaws are moved together until occlusal contact is obtained, although the 3D representations do not overlap.

With reference to FIG. 6, it is described how an occlusal contact motion can be used in the design of a dental member.
When the first three-dimensional tooth model follows the occlusal contact movement 602, the trace surface 600 is created by tracing the tips of the teeth 601 of the three-dimensional tooth model.
The trace surface can then be used as a reference reference for the design of the dental member.
For example, the trace surface 600 may be used as a cutting surface for cutting a dental member when the dental member penetrates the tracing surface and thus interferes with the actual patient-specific occlusal contact movement performed by the patient. Can be done.
Although only one tooth 601 is shown in FIG. 5, the trace surface is usually the sum of the trace lines or trace surfaces of each tooth in each jaw.

Although several embodiments have been described and explained in detail, the invention is not limited to these embodiments and can be implemented in other ways within the scope of the content defined in the following claims.
In particular, it is to be understood that other embodiments may be utilized and structural and functional modifications may be made without departing from the scope of the present invention.

In the device claim enumerating several means, several of these means can be embodied by one and the same item of hardware.
The mere fact that certain measures are recited in mutually different dependent claims or described in different embodiments does not indicate that a combination of these measures cannot be utilized.

  A claim may refer to any of the preceding claims, and “any” is understood to mean “any one or more” of the preceding claims.

  As used herein, the term “comprises / comprising” is used to refer to the presence of the described feature, completeness, step, or element. It should be emphasized that, although taken for clarity, it is understood that it does not exclude the presence or addition of one or more other features, completeness, steps, elements, or groups thereof.

The above and subsequent method features may be implemented in software and executed on a data processing system or other processing means by execution of computer-executable instructions.
These instructions can be program code means which are read from a storage medium or from another computer via a computer network into a memory, for example a RAM.
Alternatively, the described features may be implemented by a hardwired circuit instead of or in combination with software.

<Embodiment>
The following series of embodiments should not be construed as limiting the present invention, but should be understood as a series of advantageous embodiments and examples.

1. A method for designing a dental component of a patient comprising:
Obtaining a three-dimensional representation of the patient's upper jaw;
Obtaining a three-dimensional representation of the patient's lower jaw;
A first three-dimensional representation of a first occlusion of both jaws of the patient at least in a first occlusion and a second three-dimensional representation of a second occlusion of both jaws of the patient in a second occlusion different from the first occlusion Step to get the
Digitally determining an occlusal contact movement of the patient's jaws relative to each other based on the at least first three-dimensional representation, the second three-dimensional representation, and contact between the patient's upper and lower jaws;
Digitally designing the dental member based on the occlusal contact movement of the patient's jaws relative to each other.

2. 2. The method of embodiment 1, wherein the step of digitally determining the occlusal contact movement includes at least two three-dimensional representations of the bite of the patient's jaws in a series of consecutive bites.
3. The method further comprises obtaining at least two three-dimensional representations of the bite of the patient's jaws in the series of successive bites using an intraoral scanner. 2. The method according to 2.
4). 4. A method according to claim 2 or 3, wherein the method further comprises the step of recording the three-dimensional representation of the mesh as a series of consecutive frames.
5. Embodiment 2, 3 or 4 wherein the method comprises obtaining a three-dimensional representation of multiple bites of the patient's jaw, wherein the three-dimensional representation is adapted to be played as a video stream The method described.

6). 2. The method of embodiment 1, wherein the step of digitally determining the occlusal contact movement of the patient's jaws relative to each other comprises interpolating the movement between the measured bite and bite.
7). 7. The method of embodiment 6 wherein the step of digitally determining the occlusal contact movement of the patient's jaws relative to each other comprises interpolating the movement between the measured bite and bite.
8). Embodiment 8. The method of embodiment 6 or 7, wherein the interpolation comprises performing a rigid transformation.
9. Embodiment 9. The method of embodiment 6, 7 or 8, wherein the interpolation comprises performing a linear transformation.
10. Embodiment 9. The method of embodiment 6, 7 or 8, wherein the interpolation comprises performing a non-linear transformation.
11. Embodiment 9. The method of embodiment 6, 7 or 8, wherein the interpolation is a combination of linear and non-linear transformation.
12 12. The method according to any one of embodiments 6-11, wherein the transformation includes translation and rotation.
13. 13. The method as in any one of embodiments 6-12, wherein the interpolation is performed on teeth that are within a range of known data points from at least the first and second engagements.

14 Detecting the overlapping region of the three-dimensional representation of the patient's upper jaw and the three-dimensional representation of the patient's lower jaw during interpolation;
14. The method of any one of embodiments 6-13, further comprising separating the three-dimensional representation of the patient's upper jaw from the three-dimensional representation of the patient's lower jaw until no overlapping region is detected.
15. 15. The method of any one of embodiments 1-14, wherein the method further comprises obtaining a third three-dimensional representation of a third bite of the patient's jaws.
16. The method digitally includes at least the three-dimensional representation of the upper jaw, the three-dimensional representation of the lower jaw, the first three-dimensional representation of the first mesh and the second three-dimensional representation of the second mesh. Including aligning,
Embodiment 16. The method according to any one of embodiments 1 to 15.

17. The occlusal contact movement of the patient's jaws is
Rearward shift,
Outward dislocation,
Outer-backward dislocation,
Embodiment 17. The method of any one of Embodiments 1 to 16, comprising inward dislocation and / or immediate sideshift.
18. 18. The method according to any one of embodiments 1-17, wherein the determination of the occlusal contact movement of the patient's jaws includes determining the extreme point of movement of the jaws.
19. 19. The method according to any one of embodiments 1-18, wherein at least one of the three-dimensional representations provides constraints on the occlusal contact movement of the patient's jaws.
20. Embodiment 1 wherein the method comprises the steps of indicating which movements of the jaws are due to recorded engagement and which movements of the jaws are due to the determined occlusal contact movement. The method according to any one of 19 to 19.
21. 21. The method according to any one of embodiments 1-20, wherein the occlusal contact motion is regenerated in the order in which the occlusal contact motion is determined.

22. An overbite where the engagement is in contact between at least some of the upper and lower teeth;
Lie / skew bit to the left,
22. The method of any one of embodiments 1-21, comprising right lie / skew bite and / or occlusion when the teeth and jaws are in a stationary occlusal state.

23. The bite includes one or more occlusal records, in which case the occlusal records are
Center position and / or maximum cusp mating position,
right side,
Embodiment 23. The method of any one of embodiments 1-22, comprising a left side and / or a front side.

  24. 24. The method of any one of embodiments 1 to 23, wherein at least one of the engagements includes an extreme point of the movement of the jaws.

25. The meshing is the maximum outer dislocation,
Maximum inward dislocation,
Maximum immediate side shift,
Maximum outer-backward dislocation,
25. The method of any one of embodiments 1-24, comprising the patient's maximum anterior displacement and / or the patient's maximum posterior displacement.

26. 26. The method according to any one of embodiments 1-25, wherein the dental member is designed for the patient based on the determined occlusal contact movement of the patient's jaws.
27. An embodiment wherein the method comprises the option of alternating between the occlusion / movement inspection and imaging of the jaws, which is due to the engagement recorded by the operator during the design of the dental member 27. A method according to any one of 1 to 26.
28. 28. The method according to any one of embodiments 1-27, wherein the dental member is a dental repair aid or an orthodontic appliance.
29. 29. The method according to any one of embodiments 1-28, wherein the dental repair aid is a crown, abutment, bridge, full denture, partial denture, inlay, onlay, and the like.
30. 30. The method of any one of embodiments 1-29, wherein the orthodontic appliance is a brace, aligner, retainer, or the like.

31. Embodiments wherein the three-dimensional representation is obtained by intracavity scanning of the patient's teeth and / or by scanning a physical impression of the patient's teeth and / or by scanning a physical model of the patient's teeth. 31. The method according to any one of 1 to 30.
32. 32. The method according to any one of embodiments 1-31, wherein the three-dimensional representation is obtained by obtaining a three-dimensional scan.
33. The three-dimensional scan is an intraoral scan of at least a portion of the patient's set of teeth, a scan of at least a portion of the patient's set of teeth, and / or a physical model of the patient's set of teeth 33. A method according to any one of the preceding embodiments, wherein the method is a partial scan.
34. 34. The method of any one of embodiments 1-33, wherein the three-dimensional scan is performed by laser light scanning, LED scanning, white light scanning, fluorescence scanning, probe scanning, X-ray scanning, and / or CT scanning. .

35. 35. The method according to any one of embodiments 1-34, wherein the occlusal contact movement defines a standard reference that is used as a design standard when designing the dental member.
36. 36. The method of embodiment 35, wherein the at least one contact surface is provided between the dental member and the reference reference.
37. 37. The method of embodiment 35 or 36, wherein the occlusal contact movement defines a trace surface as a design criterion when designing the dental member.
38. 38. The method of claim 37, wherein the trace surface is used as a cutting plane for cutting and trimming the dental member.
39. 38. The method of claim 37, wherein at least a portion of the dental member is cut to the trace surface.

  40. A computer program product comprising the program code means for causing the data processing system to perform the method of any one of the preceding claims when the program code means is executed on a data processing system.

  41. A computer program product according to the embodiment comprising a computer readable medium storing the program code means.

  42. A non-transitory computer readable medium storing a computer program configured for performing a computer-aided digital design of a patient's dental component by performing the method of any one or more of the preceding claims.

43. A system for designing a dental component of a patient,
Means for obtaining a three-dimensional representation of the upper jaw of the patient;
Means for obtaining a three-dimensional representation of the lower jaw of the patient;
A first three-dimensional representation of a first occlusion of both jaws of the patient at least in a first occlusion and a second three-dimensional representation of a second occlusion of both jaws of the patient in a second occlusion different from the first occlusion Means for obtaining,
Means for digitally determining an occlusal contact movement of the patient's jaws relative to each other based on the at least first three-dimensional representation, the second three-dimensional representation, and contact between the patient's upper and lower jaws And means for digitally designing the dental member based on the occlusal contact movement of the patient's jaws relative to each other.

Claims (20)

A method for designing a dental component of a patient comprising:
Obtaining a three-dimensional representation of the patient's upper jaw;
Obtaining a three-dimensional representation of the patient's lower jaw;
A first three-dimensional representation of a first occlusion of both jaws of the patient at least in a first occlusion and a second three-dimensional representation of a second occlusion of both jaws of the patient in a second occlusion different from the first occlusion Step to get the
Digitally determining an occlusal contact movement of the patient's jaws relative to each other based on the at least first three-dimensional representation, the second three-dimensional representation, and contact between the patient's upper and lower jaws;
Digitally designing the dental member based on the occlusal contact movement of the patient's jaws relative to each other;
A method characterized by. Determining the occlusal contact movement digitally;
The method of claim 1, comprising at least two three-dimensional representations of the bite of the patient's jaws in a series of consecutive bites.   The method further comprises obtaining at least two three-dimensional representations of the bite of the patient's jaws in the series of successive bites using an intraoral scanner. 2. The method according to 2.   4. A method according to claim 2 or 3, wherein the method further comprises the step of recording the three-dimensional representation of the mesh as a series of consecutive frames. Digitally determining the occlusal contact movement of the patient's jaws relative to each other;
The method of claim 1, comprising interpolating the movement between the measured engagement and engagement.   6. A method according to claim 4 or 5, characterized in that the interpolation comprises the implementation of a rigid transformation, a linear transformation, a non-linear transformation and / or a combination of a linear transformation and a non-linear transformation.   The method according to claim 4, 5 or 6, wherein the transformation comprises translation and rotation.   The interpolation according to claim 4, 5, 6 or 7, characterized in that the interpolation is carried out on teeth that lie within a range of known data points at least from the first and second engagements. Method. The method comprises
Detecting overlapping regions of the three-dimensional representation of the patient's upper jaw and the three-dimensional representation of the patient's lower jaw during interpolation;
Separating the 3D representation of the patient's upper jaw from the 3D representation of the patient's lower jaw until no overlapping region is detected;
Further including
9. A method according to any one of claims 4 to 8, characterized in that   10. The method according to any one of claims 1 to 9, wherein the method further comprises obtaining a third three-dimensional representation of a third bite of the patient's jaws.   The method digitally includes at least the three-dimensional representation of the upper jaw, the three-dimensional representation of the lower jaw, the first three-dimensional representation of the first mesh and the second three-dimensional representation of the second mesh. 11. A method according to any one of the preceding claims, comprising the step of aligning.   12. A method according to any one of the preceding claims, wherein at least one of the three-dimensional representations provides constraints on the occlusal contact movement of the patient's jaws. The method comprises
The method includes the steps of indicating which movement of the jaws is due to the recorded engagement and which movement of the jaws is due to the determined occlusal contact movement. The method according to any one of 1 to 12.   The method according to claim 1, wherein the occlusal contact movement is regenerated in the order in which the occlusal contact movement is determined.   15. A method according to any one of the preceding claims, characterized in that the occlusal contact movement defines a standard reference to be used as a design standard when designing the dental member.   The method of claim 15, wherein the at least one contact surface is provided between the dental member and the reference reference.   17. A method according to claim 15 or 16, characterized in that the occlusal contact movement defines a trace surface as a design criterion when designing the dental member.   The method of claim 16, wherein the trace surface is used as a cutting plane for cutting and trimming the dental member.   The method of claim 16, wherein at least a portion of the dental member is cut to the trace surface. A system for designing a dental component of a patient,
Means for obtaining a three-dimensional representation of the upper jaw of the patient;
Means for obtaining a three-dimensional representation of the patient's lower jaw;
A first three-dimensional representation of a first occlusion of both jaws of the patient at least in a first occlusion and a second three-dimensional representation of a second occlusion of both jaws of the patient in a second occlusion different from the first occlusion Means for obtaining
Means for digitally determining an occlusal contact movement of the patient's jaws relative to each other based on the at least first three-dimensional representation, the second three-dimensional representation, and contact between the patient's upper and lower jaws When,
Means for digitally designing the dental member based on the occlusal contact movement of the patient's jaws relative to each other;
Comprising
A system characterized by that.