This application claims the benefit of German Patent Application No. DE 10 2010 037 160.2, filed Aug. 25, 2010, which is incorporated herein by reference as if fully set forth.
The present invention relates to a method for the production of dentures, in which for the production of veneers on a support frame, several layers of at least one material mixture are applied to a spatially curved exterior surface of a support frame, in an automated, particularly a computer-controlled fashion according to a digital model of the dentures, with the layers of the material mixture being applied as layers arranged in a spatially curved manner.
Furthermore, the invention also relates to a layering device for implementing the method.
For the production of dentures it is not only important to optimally embody the tooth or parts of the tooth with regards to strength and shape but also to adjust the exterior appearance of the denture and/or its coloring to the still existing teeth in the mouth of the patient, to the extent possible. For this purpose it is known in prior art to manually model the veneer of the denture on a support frame. This is very laborious and expensive. In prior art several automated production methods are known. For example, U.S. Pat. No. 4,937,928 discloses a generic method for the production of dentures. Here, using a CAD/CAM-system the denture is constructed layer for layer by individual ceramic layers being applied on a metallic support frame and each layer is sintered after its application and mechanically post-processed before the next layer is applied. This automated method as shown in prior art is still very expensive, because sintering as well as post-processing occurs after the application of each layer.
In addition to the above-mentioned generic methods, non-generic methods are known in prior art. They are based on first mathematically dissecting the dentures to be produced into horizontal sections and to successively construct these horizontal sections by an appropriate horizontal layering. In these generic methods the layers of the material mixture are therefore applied in horizontal layers and not as layers arranged spatially curved. Such a method is disclosed, e.g., in U.S. Pat. No. 7,686,989 B2.
The objective according to the invention is therefore to provide an alternative generic method, which allows the production of dentures in a more efficient and thus more cost-effective manner.
For this purpose it is provided according to the invention that several layers of the material mixture are applied immediately after each other.
In other words, it is therefore provided that several or at least two layers of the material mixture are applied immediately after each other without any other processing steps being performed therebetween. In particular, after each individual layer no intermediate sintering or mechanical processing is provided. This leads to a considerably more effective and faster production of the dentures. Here, it is not mandatory for all layers to be constructed without any intermediate processing. It is sufficient that between other, potentially necessary processing steps, two or more layers of the material mixture are applied directly following each other. Here, the first layer is directly applied on the support frame and/or its exterior surface as a layer arranged spatially curved. In the subsequent layers, arranged spatially curved, a direct application occurs onto the support frame, because these layers are applied onto layers already existing on the support frame. The applied layers are then positioned directly following each other, also with regards to their spatial positioning.
For reasons of completeness it is pointed out that the term dentures shall be understood as both the replacement of a part of a tooth and the replacement of an entire tooth as well as the replacement of several teeth, e.g., in the form of a bridge and/or several parts of teeth. Within the scope of the invention it is preferably provided that the support frame is a component of the finished denture and thus implanted and/or integrated therewith in the mouth of the patient.
Preferred embodiments of the invention provide that the curing of the already applied layers of the material mixture occurs only after the application of several layers of the material mixture in a separate processing step, preferably after the application of all layers of the veneer. Sintering or light-curing may be performed in a separate processing step, for example. Particularly preferred it is provided that a mixture comprising at least one liquid component, preferably in the form of a binder and at least one powdered component, preferably in the form of a ceramic powder or a plastic powder is applied as the material mixture. Here, one variant comprises that a suspension is applied as the material mixture, preferably premixed or only mixed directly prior to or during application. In other variants of the method according to the invention it may also be provided, though, that the layers of the material mixture are each applied in at least two separate processing steps, in which preferably first a liquid component is applied, preferably in the form of a binder, and preferably subsequently in another processing step at least one powdered component, preferably in the form of a ceramic powder or a plastic powder.
The method according to the invention may be implemented using most different material mixtures. A first group of variants provides here to use ceramic materials. Here, both of the above-mentioned variants are possible. The ceramic materials can here therefore be already applied as a suspension in order to form the layers. However, it is just as well possible to apply preferably first at least one liquid component, preferably in the form of a binder, and preferably subsequently the ceramic material in the form of a ceramic powder. Here, various binders may be used as the liquid component. Particularly preferred it is provided here that the binder comprises an adhesive component, preferably based on protein. The binders may have a composition, for example, having an adhesive portion, such as protein, gelatin, glue, and the like, ranging from 2 to 80 percent by volume. Further, the liquid components and/or the binder may include a volatile component, preferably alcohol, at a portion of 5 to 50% by volume. This may support rapid drying. Further, in order to fulfill a diluting function it is possible for the liquid component and/or the binder to comprise distilled water from 20 to 40 percent by volume. Furthermore, wetting adjuvants and thickening agents, such as cellulose, may be present in the liquid component. The adhesive effect of this liquid component is of primary importance. However, it is also beneficial for a liquid component to be selected, which burns without any residue during the ceramic burn and/or sintering. Beneficially, the liquid component should be fast drying and self-drying in order to ensure a timely application of several subsequent layers one after the other. The ceramic powder is selected with a suitable particle size, distribution of the particle sizes, and particle shapes. Here, materials and/or glass is selected which even in very thin layers provides the desired color effect and/or translucency. This may be further improved in combinations with particular support frames, such as anatomically colored, reduced support frames. Ceramic materials with a good wetting ability are advantageous.
As an alternative for the use of ceramic materials, plastics may also be used as the material mixture for the method according to the invention. Here, too, both the application of previously mixed suspensions as well as the successive application of liquid components and powdered components is possible. Various polymers may be used. Their curing may occur chemically but also in separate processing steps, e.g., by way of light curing. Both the material mixtures composed on a ceramic basis as well as a plastic basis may be differently dyed in order to produce various shades of color. Here, the liquid or the powdered components or the entire suspension may be dyed. Additionally, color effects may also be created via appropriately dyed surfaces of the support frame. The same applies for the translucent features of the materials used.
Generally, a natural tooth to be replaced is differently colored in different sections, therefore it should also be possible to realize that effect in the denture to be produced. In order to allow implementation of that effect in the artificially produced denture it is advantageous if at least one first material mixture is applied in a first partial area or in first partial areas of the veneer to be produced and at least one other preferably differently dyed material mixture or several other, preferably differently dyed material mixtures is and/or are applied in other partial areas of the veneer to be produced. In the context of this application, veneer is intended to refer to the built up layers used to form part of the denture, regardless of whether it is for application to a front face of a tooth, the back face, the side face, or combinations of some or all faces of one or more teeth, and is not limited to cosmetic “dental veneers” that are applied only to the front face of a tooth.
In preparation of the above-mentioned steps of the method according to the invention and its preferred embodiments, the patient's situation is beneficially available as a virtual model. Here, both the color as well as the geometric information may be obtained by an intraoral or extraoral scanning of actually existing teeth, models, or molds, i.e. negative models. The color information may also be obtained by different means, of course, e.g., by comparison with still existing neighboring teeth. Then it is beneficially provided to construct the denture as an anatomic form, e.g., by using CAD software. Subsequently, by way of calculation the entire denture to be produced can be dissected on a digital level into a support frame and a veneer. With regards to the support frame, standard forms may be used or, as explained in greater detail in the following and known per se in prior art, it may be produced in advance. The support frame advantageously forms a minimized anatomic tooth shape, which can be created, e.g., from a standard tooth shape saved in suitable software. As a next step, it may be provided to divide the veneer by way of calculation into different color zones and/or differently dyed partial areas. This may e.g., occur based on diagrams of color schemes saved in a library. The classification of the different color zones and/or differently dyed partial areas may also occur based on previous color analyses of still existing teeth of the patient. When producing the denture by applying layers onto the spatially curved support frame, the color zones and/or partial areas may be selected freely. For example, it is beneficially provided initially to produce the first partial area by constructing several layers in order to subsequently produce differently dyed partial areas using the appropriate layered construction. Here, the production of one partial area after another may occur until the veneer is produced in its final form. The shrinkage or expansion factor to be expected depending on the material mixture used is advantageously considered for the calculation of the geometry of the denture to be produced. For example, when ceramic materials are used, e.g., the shrinkage during sintering may be considered. Further, it is beneficial at the monitor to provide a real color demonstration of the tooth to be veneered for controlling purposes. Further, when producing dentures based on a digital model, e.g., constructed by way of CAD, advantageously coordinates and/or zero-point systems may be applied, which allow an appropriate transfer of the geometric information from the digital model to the denture actually to be produced. This always ensures the positioning and repositioning of the support frame in the coordinate system of the respective processing step. The data sets for producing the veneers are advantageously constructed via CAD.
It is also possible to construct the support frame via CAD. The production of the support frame can also occur according to any variants known in prior art. In any case, a portion of the denture is considered the support frame, upon which the layers of the veneer are applied in order to complete the denture. When inserting the denture into the set of the patient's teeth, the support frame then represents the part which directly contacts the tooth stump of the patient. The support frame is therefore the part of the denture, via which the fastening occurs in the mouth of the patient.
The materials for producing the support frame may vary. Here, examples are ceramic materials, such as zirconium dioxide, lithium disilicate, glass ceramics, sintered ceramics, etc. However, they may also represent metallic support frames made from non-precious metals or precious metals, titanium, or metal alloys. Further, support frames may also be used comprising plastics, for example polymers. The support frames may be produced, as generally known, via casting, laser sintering, cutting, polishing, printing, stereo-lithography, etc.
A support frame receiver may also be produced, which serves to fasten to the layering device to be discussed in the following. On the one hand, the support frame receiver may be fastened and/or formed directly at the support frame. In this case, it is also created during the production process of the support frame. The geometry of the support frame receiver may be saved, e.g., in a suitable software. Alternatively, the support frame receiver may be produced as a model, which can be fastened in a form-fitting manner at the support frame e.g., in an interior hollow space of said support frame. The surface of the support frame, upon which the layers of the veneer are applied, can be pretreated and/or conditioned by way of blasting, cleaning, dissolving etc. The support frame may comprise an interior hollow space, which serves for fastening on to the tooth stump. This hollow space and/or the contact surface provided for fastening at the tooth stump is advantageously covered when applying the layers of the veneer. As already mentioned, the surface of the support frame may contribute to the coloring of the denture by applying appropriate dyes, opaquers, and/or liners. Here, the above-mentioned colors, intensive dyes, opaquers, and liners may be applied over the entire exterior surface of the support frame or only in individual partial sections. The application can occur in a spraying method, punctually, or over an extended area, for example via air-brush coating. Alternatively, the application can occur via nozzles or paint brushes. When the support frame is produced from a ceramic material a first sintering burn of the support frame may occur before the layers of the veneer are applied.
In order to implement the method according to the invention a layering device may be used which is characterized in the layering device comprising at least one support frame receiver, at which the support frame can be fastened, and at least one positioning device for positioning the support frame receiver in the space and at least one applying device, preferably several separate applying devices to apply the material mixture and at least one computer-supported control device, with the positioning device and/or the applying device(s) being addressed by the control device, preferably mobile in space. Advantageously this layering device includes a vibration device to vibrate the denture and/or the support frame receiver. In order to allow applying very quickly different, particularly differently dyed material mixtures onto the support frame, preferred embodiments of the layering device provide that they comprise a magazine for providing different, preferably differently dyed material mixtures and/or components of material mixtures. In order to allow drying different layers as quickly as possible the layering device may comprise at least one drying device for drying the material mixture. In order to allow performing minor corrections of the shape the layering device may further comprise at least one mechanic shaping device for post-processing the shape of the applied layers of the material mixture. Possible shaping devices are boring, cutting, or other shaping tools, such as blades.
Additional features and details of preferred embodiments of the invention are discernible from the following description of the figures. Shown are:
In order to ensure the homogeneity of the veneer 1 it is beneficial when the material mixture applied is set to vibrate, preferably by vibrating the support frame 2. This leads to compacting the already applied material mixture. This way, the vibration reduces shrinkage and avoids cracking during the curing process and particularly the sintering of the applied material mixture. The vibration is beneficially introduced, as already mentioned, via the support frame 2. The vibration device 16 is shown schematically in
The layering device 10 shown schematically in
Number | Date | Country | Kind |
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102010 037 160.2 | Aug 2010 | DE | national |