DE102013102412A1 - Method for producing a telescopic prosthesis - Google Patents

Abstract

The invention proposes a method for producing a telescopic prosthesis for a set of teeth, comprising the following steps: providing a digital data record of a 3D image of the upper and / or lower half of the set of teeth, and producing the telescopic prosthesis on the basis of the data record. According to the invention, the data record contains the upper half of the dentition including the palate area and / or the lower dentition half including the sublingual space, and the telescopic prosthesis is also produced on the basis of the 3D image of the palate area or the sublingual space.

Description

I. Field of application

The invention relates to a method for producing a telescopic prosthesis for a denture.

II. Technical background

Telescopic prostheses are partial dentures that are attached to so-called telescopic crowns, i. Inner telescopes, to be fixed. The inner telescopes sit on tooth stumps and are so firmly arranged on the jaw. They have a support and holding function for the removable partial denture. This removable partial denture is used to replace missing teeth and is thus assigned to the combined dentures. The partial dentures extend over the two quadrants of the upper or lower half denture. Usually, they are attached to at least one tooth stump per quadrant on the inner telescopes. The telescopic crowns can also be referred to as inner telescopes.

For the manufacture of an inner telescope, the dentist first prepares abutment teeth by abrading. Tooth stumps result from these pierced stumps, which later ensure a stable hold of the telescopic prosthesis in the bit. To protect these stumps the inner telescopes are permanently attached in the form of cap-shaped attachments on the tooth stumps, for example by cementing. However, to make the inner telescopes, it is first necessary that the dentist makes an impression of the upper or lower half of the teeth. By default, such a denture impression is made by the dentist in a manual manner by means of a mass formed on the denture.

In more modern methods, optical scanning methods are increasingly used for this purpose. In the latter, the denture is scanned by means of a digital camera with a very high sampling frequency. The digital impression is then computed by a computer by composing the individual images into a record of the 3D image. However, these digital scanning methods are still at a very early stage of development and are therefore mainly used for smaller sections of a bit half, for example for 2 or 3 teeth on which a bridge is to be built.

Until the completion of the internal telescopes, the patient usually receives temporaries on the tooth stumps.

Once the inner telescopes have been completed, the outer telescopes can be made in a next step. These are cap-shaped adhesive elements that correspond in number and shape to the inner telescopes. The outer telescopes have the function of providing a capillary effect to ensure reliable adhesion between the internal telescoping jaws and the removable connecting element (which forms the support for the artificial teeth). For this purpose, they are fixed to the connecting element produced later, for example, glued.

The fastener, which in the finished state the dentures, i. The artificial teeth that will wear usually consists of steel and is cast. The connecting element has the main function of forming a stable support for the dental prostheses. For this purpose, it must be attachable via the outer and inner telescopes with sufficient adhesion to the tooth stump, possibly distributed on both quadrants of a half-teeth.

In addition, the middle part of the connecting element between the two quadrants must rest against the oral cavity so that it does not disturb the wearer of the telescopic prosthesis. If the telescopic prosthesis is intended for the upper jaw, the connecting element must rest against the palate. For this purpose, a connecting element in the form of a plate adapted to the palate is usually used, which connects the left with the right quadrant. However, if the telescopic prosthesis is a combined dental prosthesis for the lower jaw, then the connecting element usually has the form of a bracket, which is arranged below the row of teeth on its inner side and establishes a connection between the two quadrants. Also in this case, the connecting element must be adapted to the oral cavity, in particular to the sublingual space, so that it does not disturb the wearer of the telescopic prosthesis. A reliable adaptation to the oral cavity is also conducive to additional stabilization of the telescopic prosthesis when wearing, since thus the forces can be transmitted to the palate or sublingual space and not only to the tooth stumps.

However, the production and adaptation of the connecting element represents a complex and labor-intensive process. In particular, several treatment sessions at the dentist are required for the preparation, since several fittings on the patient and new impressions of the jaw are needed. Due to the high costs of the dental appointments, the total price of the telescopic prosthesis increases enormously. A technical challenge is that for a correct preparation, the connecting element not only individual teeth, but an impression of the entire upper or lower jaw are needed, ie the corresponding row of teeth together with the lying between the quadrants oral cavity, ie the palate or the sublingual space. For a reliable image, on the basis of which the dental technician can then produce the connecting element, the dentist makes one or more mold impressions on the patient. However, the dentist can only make these mold impressions once he has fitted the inner telescopes into the dentition of the patient.

The term "mold impression of the upper and / or lower half of the dentition" thus means a molded impression of the denture half. For this purpose, an impression is first taken from the oral cavity of the patient by means of a curable impression material, filled with plaster and made from this impression a so-called master model. By means of this master model, a working model is usually produced by the so-called duplication, which serves as a template for the production of the telescopic prosthesis.

Although these form impressions are a proven method of providing a (total) dentition model that provides fairly reliable results, the known approach also has various weaknesses:
On the one hand, inaccuracies in the form impression can arise because the patient, for example triggered by a gagging, slightly moves the impression during the impression in the dentition, as a result of which the molding compound no longer rests on all teeth and the oral cavity without a gap.

On the other hand, in the method described above, it is fundamentally necessary for several, at least two impressions to be made, namely firstly a first impression for the production of the inner telescopes, and then at least one second impression for the production of the connecting element. For example, by the inaccuracies described above, this discrepancies between the two impressions can result, whereby the inner telescopes no longer correspond exactly in shape to the fitting thereon connector. As a result, the dentist usually has to make additional adjustments to the inner telescopes and the connector, or reprint, whereupon the dental technician must then make further adjustments to the elements.

Current developments show that the digital data-based generation of denture models by means of which dental technicians produce dental prostheses is increasingly finding their way onto the market. So, for example, suggests DE 10 2004 052 364A1 a method for producing a dental model, in which a 3D printer is used to make the model. In this case, however, the dental model in question only relates to a section of a denture half, for example to two teeth, it being possible to produce a bridge based thereon.

III. Presentation of the invention

a) Technical task

It is the object of the present invention to provide a method for producing a denture telescopic denture in which the number of working steps, in particular on the part of the dentist, can be minimized. At the same time the reliability of the production of a tailor-made telescopic prosthesis should be improved by the inventive method.

b) Solution of the task

This object is solved by the features of claim 1. Advantageous embodiments will be apparent from the dependent claims.

The invention proposes a method for producing a telescopic denture prothesis.

Initially, a digital data set of a 3D image of the upper and / or lower half of the dentition is provided, preferably after the tooth stumps have already been prepared, i. have been ground down. Usually, for this purpose, an oral scanner is used, which has a pin-shaped, digital camera. Preferably, the dentist moves with the camera first the row of teeth of the upper or lower jaw, and then the lying between the quadrant oral cavity, i. So the palate or the sublingual space. He should at each position of the row of teeth for their scanning with the camera from outside the jaw inwardly around the teeth in question, so as to obtain all the views of this dentition section. It is especially advantageous if he basically also mitabtastet a piece of the lying between the quadrant oral cavity. Namely, the later composite 3D image is formed by using the overlapping regions of the individual images from the computer to combine the overall 3D image. The relationship between the row of teeth and the end of the oral cavity can therefore be more easily calculated by the computer, if there are sufficiently overlapping or overlapping areas.

Preferably, the up to the completion of the inner telescopes are placed on the tooth stumps provisional on the basis of the digital Record produced. It is also possible that for this purpose only the tooth stumps, either in the unpolished or in the ground state, are scanned, and the temporaries are made on the basis of these separate recordings. In this case, starting from a scan of the tooth stumps in the unpolished state, an estimated cut-off of, for example, 1 mm could be included. Thus, it is conceivable that first a 3D image of each unsmooth tooth stump is produced, this recording or recordings are transmitted to the dental technician for the preparation of temporaries and the dentist abrades the stumps until the completion of the temporaries and then the record of the 3D recording of the upper and / or lower half of the teeth to make the telescopic prosthesis.

Due to the recent developments in the field of oral scanners, which provide a digital raw data set due to their high resolution and high sampling frequency with, for example, 3000 frames per second or more, which can be reliably assembled by modern calculation algorithms to a 3D recording of the half-teeth, the Possibility of digital imaging of such a larger area, ie an entire half-dentition including the oral cavity located therein, increasingly reliable. Although the recording of a portion of a half-bite by means of 3D scanner is already known, but was previously removed from the inclusion of larger areas, especially an entire half-teeth, since their reliability or accuracy for the correct preparation of a usable denture model was not sufficient. So it was completely absurd to produce only on the basis of a digital data set, the entire telescopic prosthesis.

However, this is precisely what the invention proposes. According to the invention, the provided digital data set not only contains a 3D image of the upper and / or lower half of the dentition, but in addition the data set also contains the 3D image of the area of the oral cavity bounded by the denture half, i. of the palate or the sublingual space. On the basis of this data set, the telescopic prosthesis is produced, not only based on the 3D image of the upper or lower half of the dentition, but also on the basis of the upper or lower half of the oral cavity.

Advantageously, therefore, only one digital data set can be used to create the telescopic prosthesis. Further illustrations, especially in the form of form impressions made by the dentist, are no longer necessary.

According to the invention, both the inner telescopes can thus be created on the basis of this one digital data record, that is to say also the connecting element. The inner telescopes can be made directly by the dental technician when he has received the digital record from the dentist, for example by milling the inner telescopes.

The external telescope can also be calculated directly on the basis of this data set by the dental technician and then manufactured. Of course, the enlargement of the tooth stumps by the inner telescopes fixedly mounted on them must be taken into account. However, as the dental technician also creates the internal telescopes, he has this information. Preferably, he can digitally design both the inner telescopes and the outer telescopes arranged to promote adhesion to the connection element and the connection element in the same work step on the basis of the data set obtained from the dentist, i. on a computer design.

In a preferred embodiment, however, the connection element is not produced directly on the basis of the digital data record. Instead, a dentition model based on the data set is first produced, for example by means of a 3D printer. Subsequently, the connecting element is designed on the basis of this physically existing dentition model, which has been produced as a physical object, including the area of the oral cavity limited by the denture. The dentition model may correspond to an impression made by the dentist on the patient. In contrast to the latter, however, in the invention, this extra step for the dentist can be saved. The connecting element is preferably cast, for example made of steel.

The production method according to the invention also results in an acceleration for the dental technician. While in conventional manufacturing processes, the dental technician can initially only produce the inner and outer telescopes on the basis of a digital 3D image of the tooth stumps relevant for the inner telescopes or a corresponding impression, in order to wait until the dentist tries on the inner telescopes on the patient and then made a mold impression of the entire half of the dentition including the oral cavity area and sent back to the dental technician, the denture mold corresponding to the mold impression can be produced in the invention, as soon as the data set of the bit half including Mundhöhlenbereich has been generated. The indoor and outdoor telescopes can So be prepared and parallel, ie at the same time, the denture model according to the invention can be produced.

Since the denture model is made relatively quickly, and normally before completion of the inner and outer telescopes, the dental technician can subsequently, i. After completion of the inner and outer telescopes, immediately adapt them to the denture model and then design and manufacture the connection element.

It is also conceivable that the finished inner telescopes, preferably together with external telescopes, be tried on the denture model or the real dentition of the patient. The try-in on the patient has only control function and is not absolutely necessary. Here, the aesthetics can be checked. It can then be made of each so covered tooth stump another scan using the dental scanner. These recordings can be integrated into the already existing data set by the tooth stumps shown therein being replaced by the new recordings, i. the tooth stumps are replaced with attached inner and possibly outer telescopes.

The connecting element is then preferably produced on the basis of the thus modified data record. As a result, the inner and outer telescopes can be taken into account.

Alternatively or additionally, however, it is also conceivable that the digital designs of the inner telescopes are integrated directly into the data record so as to be able to take the inner telescopes into consideration in the production of the connecting element. Preferably, the outer telescopes can also be taken into account, since their intended thickness is known.

Finally, the invention also relates to a telescopic prosthesis which has been produced by the method according to the invention.

c) embodiments

Embodiments according to the invention are described in more detail below by way of example. Show it:

1 : a flow chart of the manufacturing method according to the invention,

2a u. 2 B ): different views of the 3D recording of an upper half of the teeth according to the invention,

3a ) - 3c ): different views of the 3D recording 2a ) / b) with removable and marked tooth stumps,

4a ) / b): two different teeth models according to the invention with inner and outer telescopes, and

5 : An inventive denture model with an inventive, patch connection element.

1 shows an example of the manufacturing method according to the invention. In step S1, the teeth of the upper or lower jaw are first scanned. In addition, the oral cavity area enclosed by these teeth, ie, the palatal area or the sublingual space, is also scanned. It is also conceivable that, in this way, both upper and lower jaw are taken in one step, if prostheses on both the upper and on the lower jaw are necessary. This procedure is usually performed in a dental office on the patient. Likewise, it could also be done on an existing dentition model.

• – Cara Trios von Hereus (Hersteller 3 Shape)
• – mit anderen Scannern funktioniert es in der Theorie wenn sie einen Gaumen erfassen können.

The scanning, ie the scan is preferably carried out with a specially designed dental scanner, for example with

• - Cara Trios by Hereus (Manufacturer 3 Shape)
• - With other scanners it works in theory if they can capture a palate.

It should be noted that preferably only that palate area or area of the sublingual space is scanned, at which later the connecting element according to the invention will be present.

• – 3 shape dental Manager oder Designer/Model Builder

The raw data generated by the dental scanner, ie the images taken by him are supplied to a computer, the in step 2 from these images, the digital data set of the 3D image of the upper or lower half of the teeth, including the palate or sublingual space is calculated. This calculation can be done either directly in the dental office, ie on the computer to which the dental scanner is connected, or the raw data can also be forwarded unprocessed or possibly only compressed to a remote computer for processing. The remote computer may be, for example, a computer of the dental laboratory or an external service provider. The following software is preferably used to calculate the 3D image:

• - 3 shape dental manager or designer / model builder

In the 2a ) and 2 B ) show two different views of a 3D image of an upper half of a dentition calculated in step S2, together with the palatal area enclosed by the denture half. As can be seen, the 3D image has an upper half of the bit 1 together with the palate area 2 on.

In step S3, the data set is further processed by removable tooth stumps in the digital 3D image 7 be designed. In the 3a ) -D) show different views of the resulting 3D image. This was the tooth stumps 7 , which are later used in real dentition as abutment teeth, ie as holding points for the telescopic prosthesis, constructed as removable from the bit half pins. However, it is important that the outer shape of the tooth stumps 7 , which serve as a form specification for the later to be manufactured inner telescopes, is not affected. The removal of the tooth stumps 7 is an optional feature and has the advantage that the later manufactured inner telescopes easier on the corresponding tooth stumps 7 tried on and adapted.

• – Projet MP oder Objet Eden oder M120 von Inovation Medeitech

Subsequently, in the manufacturing method according to the invention, two parallel processes take place, namely, on the one hand, the production of the inner and outer telescopes, and, on the other hand, the printing of the denture model. Alternatively, however, the production of the inner telescopes in step S4 as well as the production of the outer telescopes in step S5 can directly follow step S2, and step S3 merely precedes step S6. In this case, so could the production of the inner telescopes in step 4 Immediately begin as soon as in the 2a ) and b), composite 3-D image (step S2) is completed. Namely, the design of the removable tooth stumps made in step S3 is necessary only for the printing of the denture model in step S6. To print the denture model 6 with removable tooth stumps 7 , these are preferably in step S3 yet - after their digital design as separate from the bit half parts - moved to an area next to the bit half in the digital 3D recording. Thus, they are printed in the 3D printer as separate parts next to the bit half and can be inserted into the half of the bit after completion. As a 3D printer, one of the following devices is preferably used:

• - Projet MP or Objet Eden or M120 from Inovation Medeitech

In step S4, based on the data set of the 3D images of the teeth halves, ie in particular based on the tooth stumps represented by these 7 Interior telescopes designed, preferably digital. Each tooth stump gets 7 Such an inner telescope in the form of an essay or a cap that covers and protects the tooth stump and protects. The inner telescopes are milled. They are preferably made of ceramic, such as zirconium or zirconium oxide, titanium or steel. Internal telescopes consisting of different materials, for example with a special coating, are also conceivable.

The thus finished inner telescopes can then, as indicated by the dashed arrow in 1 indicated, immediately tried on the printed denture model and adjusted if necessary. Usually, an at least slight further processing, ie adaptation of the inner telescopes is then still necessary.

It is also possible as in 1 It has been shown that directly after the inner telescopes have been manufactured, the outer telescopes are produced by electroplating on the inner telescopes. As a result, external telescopes can be produced in the form of thin hoods, which correspond to the outer shape of the inner telescopes. The outer telescopes preferably have gold, in particular with a high, for example, 99% gold content. They preferably have a thickness of 0.25 mm to 0.35 mm. Since the inner telescopes are often made of electrically non-conductive ceramics, it is also necessary that the inner telescopes are first coated with an electrically conductive lacquer, for example made of silver, prior to the manufacture of the outer telescopes. This electrically conductive lacquer also has the advantage that the outer telescopes can be solved by the inner telescopes after their completion. The paint can then be removed, for example by means of an acid.

In step S7 then the inner telescope 3 , possibly with the external telescope sitting on it 4 on the printed denture model 6 tried on and the shape of the tooth stumps to be covered 7 customized. In the 4a ) and 4b ) are two different printed denture models 6 shown on which inner telescopes 3 and outdoor telescopes 4 (sitting on corresponding inner telescopes, which are covered by this) have been placed on the tooth stumps. As can also be seen here, the inner telescopes and thus the protected by this Zahnstümpfe are distributed on both quadrants of the half-teeth.

Subsequently, in step S8, the in 5 shown connecting element 5 designed. Usually, it is first constructed on the computer as a 3D digital image, adapting it to the shape of the bit, and in particular to the shape of the area of the oral cavity where it will be applied later. Therefore, it is also conceivable that this design of the connecting element in step S8 directly after step S2 (as indicated by the dashed arrow in FIG 1 indicated) and thus parallel to the preparation of the inner and outer telescopes in steps S4 and S5 and the printing of the denture model in step S6. For example, the connecting element could be milled on the basis of the digital data record of the 3D recording of the bit half.

Preferably, however, it is cast, in particular made of steel or a steel alloy. Since a mold is necessary for this purpose, the design of the connecting element in step S8 and the production of the connecting element in step S9 will be made only when the printed denture model and the adapted thereto inner and outer telescopes are completed. On the basis of the printed denture model, in particular with inner and outer telescopes mounted thereon, a casting mold can be produced for the connecting element to be produced 5 to be provided. Nowadays, it is also possible to dispense with the casting of steel and to produce the model casting by means of laser melting, eg at Concept Laser in Lichtenfeld.

If the connecting element has been cast in step S9, the outer telescopes are then firmly inserted into the connecting element, in particular glued in step S10. Subsequently, the connecting element 5 on the printed denture model 6 tried on and adapted. However, prior to this fitting, it is usually polished and treated with a sandblaster on its inside, particularly at the locations where the external telescopes are inserted. When adjusting the connector 5 to the denture model 6 make sure that the connection element is absolutely stress-free on the denture model. The edges of the connecting element must rest and the connecting element 5 , especially his plate 8th must not rock.

In 5 is a finished fastener 5 shown as it is on the denture model 6 sitting. As can be seen, the connecting element has 5 retaining caps 9 which in their number and form the inner telescopes 3 correspond and by means of the tooth stumps 7 a secure hold of the connecting element 5 on the half of the bit 1 guarantee. These are in the retaining caps 9 the outer telescopes 4 firmly arranged and cause together with saliva due to the capillary effect adhesion to the inner telescopes 3 , The connecting element 5 furthermore has a plate as the middle part 8th in its shape to the surface of the underlying oral cavity, in this case adapted to the palate. Thanks to the invention, this adaptation can take place on the basis of the 3D digital image initially taken in step S1. A later made form print, but possibly also another shot, is not necessary.

LIST OF REFERENCE NUMBERS

1

upper half of the bit

2

palatal area

3

interior telescope

4

outdoor telescope

5

connecting element

6

denture model

7

tooth stump

8th

plate

9

retaining cap

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102004052364 A1 [0013]

Claims (14)

Method for producing a denture telescopic prosthesis, comprising the following steps: providing a digital data record of a 3D image of the upper and / or lower denture half, and producing the telescopic prosthesis based on the data set, characterized in that the data set is the upper denture Bite half including palate area and / or the lower half of the teeth including sublingual space includes, and - the telescopic prosthesis is also based on the 3D recording of the palate area or the sublingual space is made. A method according to claim 1, characterized in that the telescopic prosthesis is produced solely on the basis of the data set without additionally using a mold impression of the upper and / or lower half of the denture. Method according to one of the preceding claims, characterized in that the step for the preparation of the telescopic prosthesis following steps comprises: - producing one or more inner telescopes of the telescopic prosthesis for permanent attachment to corresponding one or more tooth stumps in the dentition, - producing one or more outer telescopes of the telescopic prosthesis in the form of cap-shaped adhesive elements which are adapted to the shape of the inner telescopes and adapted to releasably adhere thereto, and - producing a connecting element of the telescopic prosthesis for releasable attachment to the inner telescopes, which connects the two quadrants of the upper or lower half-teeth and forms a carrier for artificial teeth. Method according to the preceding claim, characterized in that the inner telescopes are manufactured on the basis of the data set, in particular milled. A method according to claim 3 or 4, characterized in that the inner telescopes ceramic, in particular zirconium, or steel or titanium and / or the outer telescopes of gold, preferably with a thickness of 0.25 to 0.3 mm. Method according to one of claims 3-5, characterized in that the outer telescopes are galvanized onto the inner telescopes, wherein the inner telescopes have been previously coated with an electrically conductive paint, and the finished outer telescopes detached from the inner telescopes and fixedly connected to the connecting element, preferably glued, be.  Method according to one of claims 3-6, further comprising the following steps: - Establishing a dentition model based on the data set, and - Adapting the inner telescopes to the denture model. Method according to the preceding claim, characterized in that the inner and outer telescopes are manufactured parallel to the denture model, preferably solely on the basis of the data set. Method according to one of claims 7-8, characterized in that the connecting element is produced directly on the basis of the data set or on the basis of the finished denture model, in particular cast. Method according to one of claims 7-9, characterized in that the denture model in the case of the upper half of the dentition is made together with the palate area and in the case of the lower half dentition including sublingual space, and the connecting element is adapted to the palate area or the sublingual space of the denture model. Method according to one of claims 3-10, characterized in that the inner telescopes, preferably including the outer telescopes sitting thereon, tried on the denture model or the real dentition and optionally adjusted, then a further 3D image of the inner telescopes in the denture model or in the real dentition is provided and integrated into the existing record, and the connection element is made on the basis of the thus modified data record. A method according to any one of claims 3-11, characterized in that the inner telescopes are digitally designed and these digital designs are integrated directly into the data set before the connection element is manufactured on the basis of the thus modified data set. Method according to one of claims 3-12, characterized in that the connecting element comprises at least one dental prosthesis, which replaces a part of the teeth of one or both quadrants, and / or in the case of the upper half of the teeth has a plate adjacent to the palate, and in the case of lower half of the teeth has an applied on the inside and below the row of teeth temple. Method according to one of claims 7-13, characterized in that the denture model is prepared so that the tooth stumps on which the inner telescopes are to be attached, are removable from the denture model, and these tooth stumps for the adaptation of the inner and / or outer telescopes be taken out of the denture model.

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