阅读说明：本技术 牙科假体 (Dental prosthesis ) 是由 R·瓦茨克 C·弗赖 于 2016-03-01 设计创作，主要内容包括：本发明涉及一种牙科假体,由一体式或两部分式的假体坯件制成,所述假体坯件由肉色材料和牙齿色材料(32)构成,所述肉色材料和牙齿色材料特别是分别以塑料为基础。本发明的特征在于所述坯件(10)的牙齿色材料(32),所述牙齿色的材料在坯件状态下具有大于人体牙弓的尺寸。所述牙齿色材料特别是至少为8cm宽。本发明的特征还在于,肉色和牙齿色材料(10和32)紧密地相互连接,可以通过一体的制造、通过粘合或通过聚合实现这种连接,尤其是通过聚合来连接。所述材料之间的边界面在牙弓走势上观察构造成波状的,而沿前庭方向观察构造成放射状的。(The invention relates to a dental prosthesis, which is produced from a one-piece or two-part prosthesis blank, which is composed of a flesh-colored material and a tooth-colored material (32), which are each based, in particular, on plastic. The invention is characterized by a tooth-colored material (32) of the blank (10), which tooth-colored material has a dimension larger than the human dental arch in the blank state. The tooth shade material is in particular at least 8cm wide. The invention is also characterized in that the flesh-colored and tooth-colored materials (10 and 32) are tightly connected to one another, which can be achieved by integral manufacture, by gluing or by polymerization, in particular by polymerization. The boundary surface between the materials is configured as wavy when viewed in the dental arch trend and radially when viewed in the vestibular direction.)

1. Prosthesis blank for producing a dental prosthesis, which consists of a flesh-coloured material and a tooth-coloured material (32), which are each based in particular on plastic, wherein the tooth-coloured material (32) of the blank (10) has a dimension which is greater than that of a human dental arch in the blank state, and wherein the flesh-coloured material and the tooth-coloured material (10 and 32) are connected to one another in a tight manner, characterized in that the boundary surface between the flesh-coloured material and the tooth-coloured material is configured wave-shaped when viewed in the dental arch trend and radial when viewed in the vestibular direction.

2. A prosthesis blank according to claim 1, characterised in that the wave form (14) expands radially from the inside to the outside, that is to say in the vestibular direction, such that the wave troughs (20) and wave crests (18) are arranged in the same angular position viewed on the trend of the dental arch, on the inside and on the outside, that is to say on the radial trend.

3. A prosthesis blank according to one of the preceding claims, characterised in that the tooth colouring material (32) is provided in the shape of an arc to form an arch blank, wherein the width of the arc (16) is between 0.8cm and 4cm, in particular between 1.2cm and 3 cm.

4. A prosthesis blank according to one of the preceding claims, characterized in that the wave form (14) is configured substantially as a sine wave or as a catenary or as a mixture of sine wave and catenary, said wave form having an amplitude and/or period which varies or fluctuates, in particular in trend, wherein in particular it is provided that the configuration of the wave form is configured substantially as a catenary, wherein the suspension points of the chains correspond to the interdental spaces but differ from pure catenary, which are flattened and/or rounded.

5. A prosthesis blank according to any one of the preceding claims, characterised in that the height and/or width of the peaks (18) of the tooth colouring material (32) increases from the inside outwards, that is to say in the vestibular direction, the boundary surfaces between said materials being configured in the manner of a catenary in the progression of the dental arch in correspondence of the natural gingival margin.

6. A prosthesis blank according to one of the preceding claims, characterised in that there is a transition region between the flesh-coloured material and the tooth-coloured material (32), said transition region having a thickness in the sub-millimetre range, in particular having a thickness of less than 100 μm.

7. A prosthesis blank as claimed in any one of the preceding claims, wherein the flesh portion of the prosthesis blank is provided with one to four substantially semicircular undulating arcuate structures for receiving tooth coloring material, wherein each of said undulating arcuate structures simultaneously has a radial character.

8. A prosthesis blank as claimed in one of the preceding claims, characterized in that the flesh-coloured material (10) is configured as a disc, in particular as a disc having a standard diameter of about 98mm, and has on its upper side a pattern of radially extending wavy lines, which pattern constitutes the exact negative shape of a corresponding pattern of tooth-coloured material (32).

9. A prosthesis blank as claimed in one of the preceding claims, characterized in that the tooth color material (32) is configured to fit positively with the flesh color material and in particular can be accommodated at least in a recess in the flesh color material, and the prosthesis blank is composed of at most five parts which consist of the flesh color material and the tooth color material (32) or of a material having a different strength with respect to the flesh color material and the tooth color material, which parts are intended for mutual splicing, or alternatively the tooth color material (32) and the flesh color material (10) are configured as a one-piece prosthesis blank, optionally in combination with materials having different strengths, wherein in particular a material having a higher strength, such as metal, is accommodated in the recess of the flesh color material.

10. A prosthesis blank as claimed in any one of the preceding claims, characterised in that the tooth-coloured material (32) is cast and polymerised in a recess (12) provided with a wave-shaped profile of flesh-coloured material.

11. A prosthesis blank as claimed in any one of the preceding claims, characterized in that the boundary surface has another, in particular not particularly pronounced wavy line in its course, viewed in the vestibular direction.

12. A prosthesis blank as claimed in any one of the preceding claims, wherein the reinforcement has been previously integrated into the blank, for example into a flesh-coloured blank.

13. A prosthesis blank as claimed in one of the preceding claims, characterized in that the tooth-coloured material (10) is constructed in multiple layers, wherein the layer or area, in particular facing the flesh-coloured material, is constructed darker and/or more opaque, and the area facing away from the flesh-coloured material is constructed lighter and/or more translucent, wherein the boundary surface between the layers, in particular facing the flesh-coloured material, is wave/radial but to a lesser extent than the boundary surface between the materials.

14. A prosthesis blank as claimed in any one of the preceding claims, characterised in that the tray or element of tooth colouring material (32) has a progressively increasing height radially outwards in the radial direction, corresponding to a greater tooth height.

15. Method for producing a one-part or multi-part prosthesis blank made of a flesh-colored material and a tooth-colored material (32), in particular each based on plastic, with a boundary surface between the flesh-colored material and the tooth-colored material, which boundary surface is wave-shaped when viewed in the manner of an arch and is radial when viewed in the vestibular direction, wherein the tooth-colored material (32) of the blank (10) has a dimension which is greater than that of a human arch in the blank state, and wherein the flesh-colored material and the tooth-colored material (10 and 32) are connected to one another in a tight manner.

16. The method according to claim 15, wherein the flesh-coloured material and the tooth-coloured material are inseparably connected to one another in one piece in that the materials are pressed against one another while still soft or flowing on the boundary surface, so that, viewed microscopically, the materials interpenetrate one another.

17. Method according to claim 15 or 16, characterized in that one of the materials, for example the denture base, is premodulated in respect of the boundary surface facing the dental arch and this radial wave is used simply as a casting base, and the dental arch is cast here with a corresponding shape and then fully polymerized.

Technical Field

The present invention relates to a dental prosthesis according to the preamble of claim 1 and to a method for manufacturing a dental prosthesis according to the preamble of claim 15.

Background

It has long been known to construct prostheses, and also teeth, from a plurality of layers.

Examples of this are the solutions known from WO 90/13268 a1 and WO 91/07141 a 1.

Based on these older solutions, it has recently also been proposed, with the aid of CAD/CAM technology, to use multilayer plastic elements which are intended to be used for the manufacture of teeth and for the provision of prostheses for teeth and denture plates, in order to provide a prosthesis which is finished. This proposal has not been realized at present because of the different requirements for different materials, that is to say, on the one hand, for the fleshy denture base material and, on the other hand, for the tooth-colored denture base material, and, although it has become known in other respects, it is not possible to manufacture both the tooth and the denture base from PMMA.

In addition, rapid prototyping has recently been proposed, with the aim of providing both the teeth and the denture base from plastic materials or, if necessary, also from other materials. No substantial progress has been made in this development work to date.

On the other hand, the demand for full or partial dental prostheses is increasing in view of the increasing life expectancy, where for the sake of simplicity the term prosthesis encompasses both full and partial dental prostheses. This ever-increasing demand is accompanied by an equally ever-increasing cost pressure, simply due to the foreseeable clearly-increasing demand.

Disclosure of Invention

It is therefore the object of the present invention to provide a prosthesis according to the preamble of claim 1 or a method for producing a dental prosthesis according to the preamble of claim 15, which prosthesis can be produced economically on the one hand and has significantly improved acceptability on the other hand and is also optimized with regard to stock control on the other hand.

Said object is achieved according to the invention by claim 1 or 15. Advantageous developments emerge from the dependent claims.

According to the invention, it is provided that in a dental prosthesis which is produced in one piece or in one piece in one embodiment and in two parts or in two parts in another embodiment, two materials having a special shape are connected to one another. The shape is wavy, as seen in the direction of extension of the gingival arc (Zahnfleischbogen) of the denture, here also referred to as an asymmetrical wave, that is to say, in such a wave, like a catenary, small and narrow arcs alternate with deep and wide arcs.

A particular advantage according to the invention is that the wave form of the prosthesis extends radially from the central point of the prosthesis as seen from the latter. Each trough and each peak thus extend at the same height, but in a modified embodiment they may alternatively extend on a straight line which deviates by a few degrees from the horizontal, for example by 10 ° upwards or downwards.

It is particularly advantageous according to the invention that the teeth of the gingival arc remain connected to one another, but the impression of the appearance of the presence of individual teeth is still obtained on account of the deeper troughs between the teeth, viewed in the vestibular direction. The reason for this is mainly that light incident from the side door, particularly in the incisor area, casts a shadow, so that the interdental space is shielded by at least one adjacent tooth, and thus the multi-tooth arch according to the present invention cannot be distinguished from a single tooth.

In order to produce the two-coloured blank according to the invention, possibly in one piece, possibly also by gluing or by polymerization, the flesh-coloured material and the tooth-coloured material are intimately connected to one another. The one-piece and inseparable production can be achieved, for example, by pressing the materials against one another in a still soft or even flowable state at the boundary surface, so that, viewed microscopically, the materials interpenetrate one another. However, in this production method, the transition region is in the sub-millimeter range, for example, less than 100 μm.

Such transition regions, which are also formed on the same order of magnitude in the case of polymeric joining, can be formed, while the adhesive joints can have a small thickness of, for example, between 40 and 200 μm in the case of adhesion.

Preferably, the blank of flesh-coloured material is at least partially circular-arc-shaped. It has proven to be particularly advantageous to realize this by means of a disk, wherein two artificial dental trays can be arranged without problems, for example in a circular disk with a diameter of 98.5 mm. The tooth shade material of the blank has a size in the blank state which is larger than the human dental arch, that is to say preferably larger than 8 cm.

The consumption of material for manufacturing the tooth shade blank can be optimized in the same way. For a full denture, for example, multiple dental arches may be arranged in a circular tray having the same diameter. Two larger dental arches can be realized, for example, opposite each other in a manner known per se. The dental arch may be implemented substantially as a parabola for mandibular prostheses and as an ellipse for maxillary prostheses.

Advantageously according to the invention, the peaks of the tooth shade material are arranged at the tooth positions and the valleys are arranged at the interdental positions. The appearance corresponding to the natural gingival margin (gingivasum) is thus obtained after the manufacture is complete, for example by co-milling.

In this way, for example, up to six arches can be milled out of a dental-colored disc blank with optimum material utilization, wherein it can be understood that this number can also be increased significantly with the realization of a partial dental prosthesis. It is also possible to arrange a dental arch blank on the upper side of a flesh-colored prosthesis blank and another dental arch blank on the lower side offset by 180 degrees, so that a maxillary prosthesis and a mandibular prosthesis can be manufactured in one process step.

In a further advantageous embodiment, it is provided that a reinforcement is integrated into the flesh-colored artificial denture base. The reinforcement is made of, for example, metal, or any other suitable material having a strength greater than that of the flesh-colored material. The reinforcement can also be integrated in advance, i.e. introduced, in particular inserted, for example, into the flesh-colored blank in advance, or, in the case of the formation of the pocket, subsequently introduced, in particular inserted, into the flesh-colored blank.

According to the invention, it is provided that in a preferred embodiment the tooth-colored blank and the flesh-colored blank are connected to one another in a tight manner, either by polymerization or by gluing, and the necessary milling is carried out in this state. This has the advantage that the milling process can be carried out significantly more quickly. Only cuts need to be made on the fleshy disc-shaped blank. Due to the tight connection between the tooth color and flesh color blanks and due to the form-locking between the blanks achieved with the combined wave and radial shape, it is surprising that the strength of such a connection is sufficient even for the milling process and the forces introduced therein.

Furthermore, this corresponds to a test of the load-bearing capacity of such a connection against the shear forces to be applied later during chewing.

The arch shape of the tooth color material, which considerably exceeds the alternative with individual teeth in terms of the connection strength, functions particularly advantageously here.

It is particularly advantageous that after fixing the flesh-colored and tooth-colored materials to one another, the denture can be completed automatically by milling, in particular in a CAD/CAM unit in the case of a control device. The precise position of the vestibular boundary line of the boundary surface can be determined automatically and/or controlled by the user by means of the control device.

In an advantageous embodiment of the invention, it is provided that the flesh-colored prosthesis blank is provided with one to four substantially semicircular wave-shaped arcs for receiving tooth-colored material. Each of the wave-shaped arc structures simultaneously has a radial characteristic.

In a compact arrangement, at least two prostheses, in particular prostheses of different sizes, can be produced from disks of flesh-coloured material.

In a further embodiment, it is provided that the boundary surface, viewed in the vestibular direction, has a further, in particular not particularly pronounced, wavy line in its course.

The waveform preferably conforms in precise contour to the gum line of the gingival margin of a human mouth. This is particularly the case in the incisor area, while in the molar area more pronounced peaks and valleys can also be provided in order to further improve the form-locking of the connection.

In this respect, the peaks and valleys according to the invention have a dual function.

On the one hand, the positive connection between the dental arch and the denture base significantly improves the strength and in this respect provides an aid for adhesion which can be carried out, for example, instead of polymerization.

On the other hand, a red/white transition can thus be formed without problems, which means that in the finished prosthesis the crest of each tooth color follows the visible edge of the tooth on its tooth neck relative to the gingiva made of a flesh-colored material.

The CAD/CAM device determines the exact profile of the gum line, i.e. of the vestibular boundary line of the boundary surface, viewed from the occlusal direction on the basis of patient-specific data and produces the prosthesis on the basis thereof, whereby the dental prosthesis is produced by the CAD/CAM device. The prosthesis is thereby dimensioned for a specific patient and different arch shapes can also be taken into account, that is to say, for example, shapes which are more rounded or more triangular.

The required patient data is provided as follows:

either an intraoral scan is first performed in a known manner, or an impression is taken and then a 3D scan of the impression is performed in a likewise known manner.

Points of anatomical importance are marked and used as reference points. The data thus obtained are entered into the software of the CAD/CAM device and the CAD/CAM device automatically proposes, by means of its control means, a proposed solution for a prosthesis, the so-called virtual prosthesis. The virtual prosthesis can be modified by the user, i.e. for example by a dental technician, on a CAD/CAM device.

The tendency of the gum line, for example viewed from the occlusal direction, can be easily adjusted from an aesthetic point of view.

The control device may also take into account the size and geometry of the teeth in comparison to the arch blank and its dimensions. When it is verified that the desired dental arch cannot be arranged in the blank, the software issues a corresponding warning signal.

The same applies to denture base blanks, which may also be referred to as gingival blanks. When the size of the artificial tray exceeds the size of the supplied blank in one position, an alarm signal is also issued with an indication that a larger blank should be used.

If the desired shape is determined in a virtual manner, the obtained data is output for further processing. In the case of a subtractive production of the prosthesis, the data are fed to a milling machine of a CAD/CAM device, in which a two-color blank with a wavy/radial boundary surface according to the invention is cut.

In the case of generative production, the data are supplied to a rapid prototyping device in which the shapes of the dental arch blank and the dental prosthesis tray blank with the radial/wave boundary surface according to the invention are virtually stored. The vestibular boundary line of the boundary surface is constructed based on the obtained patient-specific data and the design functions of the CAD/CAM device, and the prosthesis is then made on this basis.

It is essential in any case that the dental arch blank has a precisely negative shape (Negativform) of the surface of the dental implant carrier blank at the boundary surface with the dental implant carrier blank, so that the two radially extending wave lines match each other precisely and can be connected to each other tightly without problems.

It is of course also possible, for example, to even manufacture five individual parts which are then spliced or combined in a suitable manner as required in order to provide the blank disc to the customer.

That is, the customer then mills the tooth material together with the gum material similarly to milling from a single piece of material.

In a further embodiment, it is provided that one of the materials is premodulated, for example, that the denture base is premodulated with respect to the boundary surface facing the dental arch. In this embodiment, this radiation waveform is then used simply as a casting base, and the dental arch is cast in a corresponding shape and then sufficiently polymerized.

In this solution too, precisely predefined wavy lines with desired gingival margin and radial orientation are obtained, which have peaks and troughs widening in the vestibular direction.

The individual tooth shape can be determined from the acquired patient data by the control device, but also the rotation and crown angle (adjustment) of the teeth and likewise the shape of the prosthetic tray can be determined, so that also different designs of the entire prosthesis can be produced.

The radial shape also ensures that, as viewed in the vestibular direction, the height of the teeth and the peaks increases at the same time as the width increases. This also corresponds to an anatomically realistic situation, since in general the size of the teeth grows in all three spatial axes as the width of the teeth increases, so that the teeth in the back (viewed in the lingual/vestibular direction) also widen (viewed in the mesial/distal direction) at the same time and also become higher (viewed from the bite-incisal edge/neck).

When the denture base is present as a blank in the form of a disk, it is then preferable to introduce a semicircular wave arc into the disk. The wavy arc is intended to accommodate an arch, which here means that the arch has a wavy arc matching the wavy arc of a flesh-colored disc.

Surprisingly, this provides a very aesthetically pleasing prosthesis even when the teeth have very different sizes, wherein, for example, for partial dental prostheses, it is also possible to form a small dental arch from the tooth color blank on one side and, thereafter or simultaneously, form a large dental arch, for example, in another position.

Here, a large arch is now mounted on a fleshy artificial tray and another arch is mounted on another artificial tray, which is also fleshy, and fleshy and tooth-colored materials are connected to one another on the boundary layer according to the invention.

This connection can be achieved both by gluing and also by a polymeric connection, and, due to the wave shape, additionally a form-locking connection is also achieved, which in particular resists laterally acting chewing forces.

Masticatory forces are in particular related to shear forces which are known to be possibly higher than 1000N (see for example the monograph "Entwicklung und Anwendunner method zur Kaukraftferssung", Tobias Fink, Charite Berlin, 2007).

In this case, it is particularly advantageous and to an unexpected extent possible to increase the durability of the prosthesis that the form-locking connection of the parts of the prosthesis better withstands the occurring alternating loads.

According to the invention, the teeth of the prosthesis according to the invention are connected to each other by a bridge made of a tooth-coloured material so as to mutually form an arch. Thus, lateral support for shear forces is improved by an order of magnitude compared to a single tooth.

This also applies to partial dental prostheses, which, although applied to a slightly reduced extent, also belong to the prosthesis according to the invention.

While the individually produced and mass-produced teeth are usually accommodated in the tooth cavities of a dental prosthesis produced according to the prior art and are subjected to considerable shear loads during chewing due to the leverage of the chewing forces, which also strongly load the adhesive surfaces, it is provided according to the invention that the shear forces are absorbed in a form-fitting manner by at least two peaks and valleys. Thus, the lever action of the individual teeth concerned is eliminated according to the invention, with a lever ratio of about 2:1, since the dental arch provided, which for a partial prosthesis comprises at least two teeth adjacent to one another, has a width which is significantly greater than the height, so that the lever action is reduced from 2:1 to, for example, 0.5: 1.

Of course, for a complete dental arch, such as is required in full dentures, the leverage associated therewith is reduced, for example, to values between 0.06:1 and 0.1:1, which corresponds to the respectively patient-specifically set height/width ratio of the tooth color material of the prosthesis according to the invention.

According to the invention, the wave shape is designed as a boundary surface between the materials, which imitates the gingival margin. Of course, the gingival margin also varies from patient to patient and it is therefore particularly advantageous according to the invention if, viewed in the vestibular direction, the dimensions, i.e. the width and depth, of the peaks and troughs, viewed radially, can be adapted to the requirements on the outside, i.e. on the vestibular side of the dental arch.

For this purpose, the control device according to the invention for producing the prosthesis according to the invention simply determines the radial position of the dental arch, that is to say also the position viewed in the vestibular/palatal or lingual direction, and produces the desired dental arch, which is determined by CAD, for example in a subtractive method together with a dental tray. This can be done, for example, in a milling machine of a CAD/CAM device, as described above.

The flesh-colored and tooth-colored materials are connected to one another in a tight manner according to the invention, either by adhesive or polymeric connection, but alternatively can be produced in one piece.

For the two-part production, it is advantageous if the two materials can be connected to one another at any time and also in any selected manner.

With a semicircular wave-shaped arc receptacle, the full circular shape of the disk can be optimally utilized. This applies to full dentures, while for partial dentures it is also conceivable to use less than semicircular arc sections, that is to say, for example, 60 ° arc sections or similar, so that a larger number of partial dentures can be produced economically and quickly from a single flesh-colored disk.

It is also possible for a full denture to take into account the Spee curve and the Wilson curve by observing on the gingival arc such that the waveform does not extend exactly horizontally, but slightly falls, for example by 1mm, in the region of the incisor margin corresponding to the natural tooth distribution and thus rises in the region of the molar teeth.

Drawings

Further advantages, details and features result from the following description of several embodiments of the invention with reference to the drawings.

Fig. 1 shows a schematic perspective view of a blank for manufacturing a dental prosthesis, i.e. a disc-shaped flesh-colored blank;

fig. 2 shows a sectional view of the illustration according to fig. 1;

fig. 3 shows a modified embodiment of the blank according to fig. 1;

FIG. 4 shows another modified embodiment of an arch blank for providing a dental prosthesis according to the invention;

FIG. 5 shows a view of a prosthetic tray blank with possible boundary lines drawn for the boundary surfaces that make up the gingival margin;

FIG. 6 shows another modified embodiment of an arch blank according to FIG. 4;

FIG. 7 shows a sectional view of a finished dental prosthesis according to one embodiment;

fig. 8 shows another embodiment of the prosthesis according to fig. 7;

fig. 9a + 9b show another embodiment of a dental prosthesis according to the invention in a manufactured state;

figures 10 and 10a show a schematic view of a blank for providing a prosthesis according to the invention, in which a blank of tooth color is shown; and

fig. 11 shows a schematic view of a blank according to fig. 10, wherein different arch sizes are alternatively drawn.

Detailed Description

Fig. 1 shows a meat-colored blank 10 in a perspective view as a semi-finished product of a dental prosthesis according to the invention in one embodiment. The blank is disc-shaped in basic structure and comprises a flesh-colored material, also referred to as gum material. In the illustration according to fig. 1, the blank has a recess 12 on its upper side, which is designed in a special manner. The recess 12 extends substantially in a semi-circle, i.e. in an arc. One particular point of such an arc is that the underside of the recess 12 has a wave shape which extends distributed in the direction of the arc. Radial structures are provided in the radial direction, i.e. from the center 17 of the arc outwards, i.e. towards the atrium side.

The arc 16 is formed by alternating peaks 18 and valleys 20. These peaks and valleys extend equiangularly so that the same peak is present at the same angular position of the arc 16 or the same valley 20 is also present at the same other angular position which remains unchanged.

As can be seen in fig. 1, the waveform 14 of the arc 16 is slightly different from sinusoidal. In fact, the waveform simulates the gingival margin and for that matter has partly elements of the catenary and partly elements of the sinusoidal shape.

The arcuate recess 12 is defined to receive a blank of dental color material that is cooperatively shaped therewith. On the side of the blank made of the tooth-coloured material facing the blank there is correspondingly a negative shape of the wave form 14 on the bottom of the recess 12. The shape of the tooth shade blank is thus exactly matched to the recess 12, if necessary with an adhesive gap having a thickness of between 50 μm and 150 μm.

Thus, the tooth-colored blank can be adhered into the recess 12 of the blank 10 without problems.

Alternatively, the connection between the two blanks may also be established by polymerization.

By means of this assembly, the blank 10, as a result of the recesses 12 being filled, has overall the shape of a circular disk, wherein, in a manner known per se, a ring-shaped projection 24 is formed around it for mounting in a workpiece holder of a dental milling machine.

It is provided here that the blank 10 is supported in a precisely predetermined position by a positioning device which effects a non-rotatable support. The possibly partially machined blank can be removed for inspection when necessary and can then be replaced in the correct position.

According to the invention, after the two blanks have been joined to one another in a tight manner as described or in any other suitable manner, the milling process specified by CAD/CAM is now carried out. Any design of the prosthesis, that is to say of the artificial tray and the teeth, can be realized with the blank thus produced. The entire dental prosthesis can be manufactured in one process step by milling and the gum line 26 is realized such that the thus provided gum margin does not at first appear distinguishable from the natural gum margin.

Even though the recess 12 is here described as circular arc-shaped, it is understood that the shape thereof may have any other design. As shown in fig. 1, in practice the waveform 14 falls slightly in the vestibular/incisal margin region and rises slightly in the vestibular/molar region, which corresponds to the gingival margin of the human body.

One possible distribution of peaks and valleys can be seen from the cross-sectional view of the blank 10 shown in fig. 2. The asymmetrical distribution of peaks and valleys is formed by the radial shape of the peaks or valleys 18 or 20, as shown in fig. 2.

The arc 16 has an arc width, viewed in the radial direction, which is significantly greater than the extent of the vestibule/tongue or vestibule/palate of the dental prosthesis. Thus, any radial position of the dental arch provided by the CAD may be determined first. The size of the prosthesis, but also of the associated teeth, can thus be adapted to the requirements of the patient's human jaw in a wide range. For smaller dental arches, the same smaller tooth is formed approximately automatically by the radial shape, since the distance between two peaks 18 or two troughs 20 corresponds to the center distance of the tooth (Rasterma β).

It is particularly advantageous according to the invention if the introduced teeth do not separate even after milling, but are present in the form of an arch. The interdental space is preferably configured to be concave and the bridge of material between the individual teeth is offset towards the lingual/palatal side. It is thereby ensured that the visual impression of the dental arch according to the invention is virtually indistinguishable from a group of teeth with a single tooth (Zahnsatz).

This embodiment of the dental arch furthermore allows a significantly increased strength to be achieved.

This makes it possible to use teeth without roots, that is to say teeth which are held in place only by a tight connection to the gum blank 10, sufficient.

In order to achieve a precise relative positioning of the tooth blank with respect to the gum blank, it is advantageous to realize a recess 12 as shown in fig. 1 and 2.

In a modified embodiment, however, the arc 16 extends all the way to the outer periphery of the blank 10, as can be seen in fig. 3. This embodiment is also suitable for forming prosthetic trays suitable for a plurality of different sizes and shapes, wherein this embodiment also enables a slightly enlarged dental arch.

The uniform distribution of the valleys 20 and peaks 18 can be seen in fig. 3. In a further modified embodiment, it is provided that the peaks and troughs are narrower and of lower height in the region of the front molars and correspondingly in the region of the front molars and in particular in the region of the molars, the peaks and troughs are of greater width and greater height. This takes into account the different tooth sizes and tooth widths in the trends of the human dental group.

However, in general, the human dentition is not exactly circular but is slightly set back relative to the circular arc in the region of the incisal edges, that is to say in particular in the region of the teeth I with a nearly planar labial surface. Because of the radial shape of the peaks 18 and valleys 20, a smaller center distance is automatically formed here.

On the other hand, generally, the human upper teeth II are slightly narrower than the upper teeth I. This can also be taken into account by adapting the width of the troughs and crests at the relevant angular positions accordingly, in particular in the case of a maxillary prosthesis.

A further modification of arch blank 32 relative thereto is seen in fig. 4. The radially extending peaks and valleys are shown here in a shape that matches the shape of the denture base blank 10 and fits into the recess 12 of the denture base blank.

In this embodiment, the radiation structure 28 extends towards a midpoint whose height relative to the gum line is significantly reduced. This results in an inclination of the radial structure 28 relative to the horizontal, which is advantageous for certain embodiments and enables a better support of the dental arch in the palatal/lingual area.

Fig. 5 shows the partially machined denture base blank 10, which is correspondingly exposed and makes it possible to see the inclination of the radial lines 28 described in fig. 4. Furthermore, in fig. 5, different boundary lines 27, 29 and 31 are drawn, which make it possible to see the milled boundary relative to the boundary surface 33 of the dental arch blank 32, which can therefore be regarded as a prosthetic gingival margin.

The position of the boundary line can be set patient-specifically by the control device, wherein for jaw structures closer to the triangle, the mesial region corresponding to the arrow 35 protrudes, and furthermore the line trend can be adapted to the requirements over a wide range.

Fig. 6 shows how, if necessary, a dental arch 32 can be formed layer by layer, which is to be supported in a sunk manner in the circular-arc-shaped recess in the partially machined dental prosthesis receiving blank 10.

As can be seen schematically in the figure, the arch blank 32 is made up of 5 layers 35a, 35b, 35c, 35d and 35e which become increasingly darker and opaque towards the boundary surface 33, which corresponds to the dentin of a human tooth. Of course, significantly more or also fewer layers can be used.

The layer transitions 35e to 35d also follow the course of the radial structure, i.e. the course of the peaks and troughs of the boundary surfaces, in a weakening manner, while the shape characteristics of this type are increasingly weakened toward the layer 35 a.

It is understood that the two blanks are produced separately from one another by milling and then joined to one another and joined to one another in a cohesive manner. The flanks of the circular arc-shaped recesses here form identical stops for the dental arch according to the invention in the mesial/distal direction during milling. This makes it possible to achieve a particularly good anchoring of the dental arch, which is important in particular for smaller prostheses.

By milling away the outer side of the denture base blank 10, the gingival margin line between the red and white material, which is particularly advantageous according to the invention, can again be made visible.

Fig. 7 shows how the finished dental prosthesis 30 can be constructed in a sectional view.

It can be seen that the tooth-colored material 32 extends along the denture base 10 thus constructed, in correspondence with the natural arch, according to the gingival margin, but not through the flesh-colored material 10. It can also be seen that in this preferred embodiment, the material 32 is also held in the material 10 in a form-fitting manner in the radial direction.

The finished dental prosthesis 34 can be seen from fig. 8 by means of a wire-frame model. Referring to the rearmost molar teeth 36 which are part of an arch 38 according to the present invention, it can be seen that the arch is intimately engaged in or connected with the gingival material.

Fig. 9a and 9b show a correspondingly produced prosthesis in different viewing directions in perspective.

Fig. 10 and 10a show how the curved tooth shade material 32, still in the form of a blank, is introduced into the recess 12 of the blank 10 and accommodated therein. The shape of the prosthesis 34 after it is also schematically shown in fig. 10 and 10a, respectively.

Fig. 11 shows a sectional view according to fig. 10, wherein the different prostheses 34, 34a, 34b are shown in an alternative dimensioning. It can be seen that the blank 10 leaves sufficient free space down on the occlusal/incisal side, i.e. in the region of the dental arch 32 and in the central region for the largest possible combination of denture base and tooth, where it can be understood that the dimensions of the blank are known as marginal conditions for the control means.