FR2768258A1 - Magnetic iron-containing precious metal alloy - Google Patents

Abstract

A precious metal alloy contains sufficient iron to make it magnetic. Independent claims are also included for (i) a system used for attaching a mobile dental prosthesis to a fixed dental part (such as a root portion or equivalent gum portion), the system comprising a first element (10), which is sealed in the fixed dental part and which consists at least partially of the above alloy, and a mobile second element (15) which consists partially of or incorporates a permanent magnet; (ii) a precious metal alloy capsule (20), especially formed from two soldered cups, for use in the above dental attachment system; and (iii) the use of a precious metal alloy for a capsule (20) in the above system. Preferred Features: The magnetic alloy has the composition 10-25 (preferably 20) wt.% Au, 5-30 (preferably 10) wt.% Ag, 8-15 (preferably 10) wt.% Fe and balance (preferably 60 wt.%) Pd. The capsule consists of an alloy of composition 4-12 (preferably 8) % Au, 30-40 (preferably 37) % Ag, 20-30 (preferably 25) % Pt and 20-45 (preferably 30) % Pd.

Description

 The present invention essentially relates to a perfectly biocompatible magnetic attachment system for mobile dental prosthesis constituted by a magnetic alloy based on precious metals as new products and by a capsule preferably made of an alloy based on precious metals, containing a permanent magnet. .

Prior Art
Magnetic attachment systems for mobile dental prosthesis have been known for a very long time. In principle, they consist in placing opposite a permanent magnet and a ferromagnetic material (permanent magnet or soft ferromagnetic alloy), so as to have a sufficient retention force between a fixed part such as a root part of a tooth or equivalent part of the gum and an associated movable part (partial or complete prosthesis). The choice of magnets has also evolved as a function of the processes for developing and shaping said magnets. Thus, the first magnets used were of the Pt-Co type. For the description of the basic principle, one can refer to the journal The Journal oufue American Dental Association, 1964, 68, pages 206-215, article by Behrman entitled, Magnets Implanted in the
Mandible: Aid to denture retention. These magnets are directly implanted in the jaw, which involves heavy surgical technicality, both from a practical and psychological point of view.

More recently, with the advent of new types of magnets, this area has been the subject of intensive research and the technique of dental attachments in which a magnetic alloy is placed opposite a permanent magnet has developed considerably with dc numerous patent applications. Research has mainly focused on the development of new soft ferromagnetic alloys, combining magnetism and casting ability so as to be able to meet the conditions required for the lost wax technique used in dentistry. The most frequently encountered alloys are palladium-based alloys, the magnetism of which is obtained by the addition of cobalt and / or nickel. By way of example, mention may be made of the Japanese applications for Hitachi Metals J56062937; J56062938 and J56062939 published on May 29, 1981,
J83110633 published November 26, 1981; J56156730 and J56156731, published on December 3, 1981, describing magnetic alloys based on palladium and cobalt or nickel to which are added elements of alloys such as silicon, zinc, gold, molybdenum or zirconium for their deoxidizing properties, increasing the mechanical strength or improving the flowability of the alloy respectively. Depending on their casting ability, ferromagnetic alloys are used on the one hand as a unitary element and fixed in the remaining teeth of the patient, either as bridges of varying length, possibly ceramized placed opposite a magnet secured to the root.

 Again, the document EP-A-225668 = US-A-4735772 by Elephant Edelmetaal published on June 16, 1987 describes palladium-cobalt alloys, with or without nickel, magnetic which can be used with cobalt magnets - rare earth to realize a system of attachment of dental prostheses. The magnetic alloy is cast in a suitable shape, so that it can be joined to the root.

 In all cases, the permanent magnets used opposite the magnetic alloys described above are based on cobalt and rare earth. By way of example, mention may be made of the Japanese application for Hitachi Metals J571 83846 published on November 12, 1982 relating to an attachment system comprising a soft magnetic material positioned facing a surface of magnetic alloy. As permanent magnet, the use of Sm-Co5 or Sm2-Co 17 is recommended.

More recently still, manufacturers have been interested in the good corrosion resistance in a saliva environment of cobalt and rare earth magnets. Indeed, the latter have an annoying tendency to corrode, causing an ionic salting out leading on the one hand to a partial dissolution of the magnet and to a loss of the resulting magnetism and on the other hand to an ionic release in the organism which can induce an allergenic or even toxic effect in the more or less long term. As examples, mention may be made of documents FR-A-2,598,314 of
Rcdcim, published on November 13, 1987 and FR-A-2,689,753 of Segura, published on April 10, 1992, which provide solutions, one by assembly, the other by encapsulation using an envelope of organic matter, the permanent magnet, so as to isolate it from the surrounding salivary medium. These systems, even if they provide a solution to ionic salting out, at least temporarily, are relatively difficult to use and exhibit poor wear resistance over time. The risk of toxicity therefore reappears when the magnet is exposed.

 11 results from the foregoing description of the prior art, that with the appearance of new generations of magnets, the technique of dental attachments in which a magnetic alloy is placed opposite a magnet s' is considerably developed. In all of the previously mentioned inventions, it appears that the magnetic alloys used are essentially based on precious metals, preferably based on palladium, for their good tolerance vis-à-vis the organism. Indeed, the presence of precious metals ensures minimal release of the associated metal ions, in the presence of an electrolyte such as saliva. Furthermore, magnetism is induced by the presence of cobalt and / or nickel, the perfect safety of which remains disputed. It is only to see the work undertaken by the standardization commissions to be convinced of it. The magnets used together are often magnets based on samarium and cobalt or more generally magnets based on rare earth and cobalt. In saliva, this type of magnet corrodes very easily and none of the means of isolation used to date has led to a reliable solution and avoiding the release of toxic products in the body in the long term. Likewise, capsules made of common metals have sometimes been used, such as nickel, chromium or niobium. Here again, however, the constituent elements of the alloy used for encapsulation are capable of causing allergies. Consequently, we are faced with the impossibility of finding a perfectly biocompatible dental attachment system which is easy to implement.

Summary and aims of the invention
The main object of the present invention is to solve a technical problem consisting of a solution making it possible to produce dental attachment systems which are easy to implement and use, perfectly harmless in terms of biocompatibility and without risk of corrosion of the system in mouth.

 The present invention also aims to solve this technical problem according to a solution which has perfect biocompatibility combined with high mechanical characteristics and remains of great ease of use.

 All of these technical problems are solved for the first time by the present invention in a particularly simple manner, both from an industrial point of view, and at the level of the dental technician.

 Thus, according to a first aspect, the present invention provides a global biocompatible attachment system for mobile dental prosthesis to a fixed dental part, such as a root part of a tooth, or equivalent part of the gum, comprising: a first element sealed in the fixed dental part and a second movable element, one of said first and second elements comprising on the one hand a magnetic alloy and on the other hand a permanent magnet, characterized in that the magnetic alloy is based on precious metals containing iron in sufficient quantity to make said alloy magnetic and forms part of or constitutes said first element, and the magnet forms part of or is incorporated into said second element.

 Thus, in the context of the invention, the constituent elements of the system in direct contact with saliva, recognized to be a good electrolyte, are based on precious metals, without any addition of nickel or cobalt, thus making the system perfectly well tolerated by the body.

 According to an advantageous embodiment of this magnetic alloy, it comprises from 10 to 25% of gold and from 5 to 30% of silver, combined with 8 to 15% of iron and is based on palladium which constitutes it so the balance.

 Such a magnetic alloy simultaneously exhibits excellent magnetism, very good hardness and very good deformability.

The deformability is improved by gold, hardness is provided by silver and magnetism is provided by iron. The absence of cobalt and or nickel make it an alloy resistant to corrosion on the scale of potentials commonly encountered in the oral environment and perfectly biocompatible.

 The magnetic alloy according to the invention makes it possible to provide a better compromise between the magnetic qualities and the possibility of developing products by the conventional techniques used in metallurgy.

Currently, the most preferred magnetic alloy is one which comprises:
At: around 20; Ag: about 10; Fe: about 10; Pd: the balance is about 60% by weight.

 The melting interval of this alloy is from 1285 to 1340 "C., the recommended casting temperature being from 1450" C. It is a white alloy with a density of 12.04. Their mechanical characteristics are indicated in step 1 below, with their magnetic characteristics and their electrochemical characteristics ensuring good resistance to corrosion in the oral environment.

 Furthermore, according to another advantageous embodiment of the invention, the second element comprises a capsule made of a precious metal alloy containing a permanent magnet. According to a preferred embodiment, this permanent magnet is of the neodymium / iron / boron type.

 According to an advantageous embodiment of the invention, the above-mentioned capsule is made from two cups welded together in a leaktight manner. This welding can advantageously be carried out by laser and its tightness is checked piece by piece. This capsule is made from a stamped sheet which can have a very small thickness and ideally a thickness of about 0.1 mm.

 According to a preferred embodiment of the invention, the capsule enclosing the permanent magnet comprises at least one alloy based on precious metals so as to ensure minimal release of the constituent elements of the alloy. By way of example, the precious metal capsule comprises at least one alloy based on precious metals and comprising gold or silver or preferably a combination of the two and at least one alloy based on precious metals and comprising platinum or palladium or preferably a combination of the two.

 By way of example, a preferred alloy for constituting the capsule is produced from a combination of four precious metals, gold, silver, platinum and palladium.

According to an advantageous embodiment of the invention, the precious alloy of the capsule has the following composition
gold: approximately 4 to 12%; silver: around 30 to 40%; platinum: about 20 to 30% and palladium: about 20 to 45%.

 It should be noted that, given the relatively similar proportions of silver, platinum or palladium, each of these elements can be used to constitute the balance of the alloy.

A composition currently considered ideal for alloying the capsule includes:
Gold: around 8%; silver: around 37%; platinum: about 25% palladium: about 30%.

 This capsule alloy is biocompatible and is easily transformed in terms of rolling and stamping, which makes it possible to obtain very thin plates of the order of 0.1 μm, which can be subsequently stamped so as to form two half shells which will be welded for example by laser after positioning the magnet inside. The tightness is checked on each finished part. Before packaging, the capsules can advantageously undergo a remagnetization step to overcome the risk of demagnetization which could occur during welding if for example the laser beam caused accidental overheating.

 In the context of the invention, the preferred magnet is of the neodymium / iron / boron type which can, for example, have the following dimensions approximately 4mm in diameter and approximately 2mm in thickness. To our knowledge, this type of magnet has never been used in attachment systems for mobile prostheses. It is an open field magnet system which has the advantage of having magnetic properties superior to those of the cobalt-rare earth magnets previously mentioned. The attachment system of the present invention has the advantage of presenting no risk to the health of the patient due to the perfectly biocompatible nature of the alloy based on precious metals constituting the capsule and of the tightness of the assembly. .

 According to a second aspect, the present invention also covers, as a new product, the aforementioned magnetic alloy based on precious metals as defined above.

 According to a third aspect, the present invention also covers, as a new product, a precious alloy capsule. The invention also covers the use of the aforementioned magnetic alloy and / or capsule for the manufacture of the prosthesis attachment system. mobile dental of the invention.

 The invention also covers a method of manufacturing the magnetic alloy, the capsule based on precious metals, and the mobile dental prosthesis attachment system constituted by the assembly of the two elements as it results from the present description. , including the drawings which form an integral part of the invention.

 It should be noted that in the description and the claims, all the percentages are given by weight, the temperature in degrees Celsius, unless otherwise indicated.

In the drawings
- Figure 1 shows a schematic view of a root part of a permanent tooth or a seat rcmplissant the same function on which is sealed the first element of the attachment system of the present invention made in one piece, again called Richemond tray or screed, made of magnetic alloy according to the present invention;
FIG. 2 is a schematic cross-sectional view of the mobile dental prosthesis to which the second element of the present invention has not yet been fixed in the form of a capsule, formed of two half-cups welded together in a leaktight manner, which is first placed against the magnetic alloy of the yoke in order to obtain its exact position and on which we just check the positioning of the mobile dental prosthesis (Figure 3);
- Figure 4 as well as Figures 5 and 6 show the successive stages of securing the capsule containing the permanent magnet with the plate
Richemond made of magnetic alloy (Figure 4); depositing a binder on the capsule, for example a self-curing resin (Figure 5); and finally the sealing of the mobile prosthesis on the capsule containing the permanent magnet (Figure 6).

 An example of manufacturing the magnetic alloy according to the present invention is now described.

Stage 1 of the invention
Manufacture of a magnetic alloy according to the invention
In accordance with the usual alloy manufacturing practice, a palladium-based magnetic alloy is made having the composition currently
f ro, next favorite
At: 20%
- Ag: 10%
-Fc: 10%
- Pd: the balance, i.e. 60%
The alloy is melted in a zirconia crucible, in order to avoid any reaction between the crucible and the constituent elements of the alloy, namely palladium and iron, and the casting takes place in a flat ingot mold of copper doped with chromium. The ingot obtained is rolled and transformed into studs.

 This alloy has a melting range between 1285 and 1340 "C, its casting temperature is dc 1450" C. It is a white alloy with a density of 12.04.

Its mechanical characteristics are as follows
- hardness: HV5 = 230 in the raw state dc casting;
- yield strength at 0.2%: 550 MPa;
- breaking strength: 700 MPa
- elongation: 14%
The magnetic characteristics of this alloy are as follows
- remanent induction: 47tMr (G) = 1450
- saturation induction: 4ltMs (G) = 4500
- coercive field = 24 Oe
- demagnetizing factor = 0.186
In corrosion, the alloy is unalterable between 0 and 800mV in a saline solution and its abandonment potential is 225mV / DHW at 20 "C.

Stage 2 of the invention
Manufacture of a Richemond plate or screed to constitute a first fixed element of an attachment system for mobile dental prosthesis
The alloy developed in step 1 can be used in the dental laboratory to make a Richemond tray or screed in one piece as follows:
According to the lost wax casting technique, a cylinder is used in which a coating is imperatively free of graphite because of the reactivity of iron and palladium with respect to this element and the whole is preheated to 900 " vs.

 The alloy is poured at 1450 "C when there is a temperature set point on the melting means. It is necessary to avoid overheating or keeping the alloy at high temperature for too long so as to avoid oxidation of the iron which risks creating defects in the casting and / or causing a reduction or even the disappearance of the magnetism of the alloy.

 The mold in which the alloy is cast obviously has the shape of the first fixed prosthetic element, that is to say the shape of a Richemond plateau or screed, for example the shape of the Richemond plateau or screed of reference 10 of Figure 1 and which allows to be sealed in the root part 12 of a tooth, see Figure 1.

 This magnetic alloy thus cast in its form as the first element of the attachment system according to the present invention is directly usable, by deburring and cutting the supply rods. The screed will also undergo a finish as practiced in the dental prosthesis laboratory (sanding and polishing).

Stage 3 of the invention
Manufacture of a capsule intended to constitute a second element of a mobile dental prosthesis attachment system according to the present invention, containing a permanent magnet.

According to the usual metallurgical processes, an alloy is produced having, for example, the following composition
- At 8% - Ag: 37%
- Pt: 25% - Pd: 30%
This alloy based on precious metals is biocompatible and its transformation is easy in terms of rolling and stamping, which makes it possible to obtain very thin plates of 0.10 mm which can be stamped so as to form two half-shells or cups referenced 22, 24 in FIG. 3 and which make it possible to include a permanent magnet before being sealed, for example by laser once the permanent magnet has been positioned inside the two half-shells 22, 24. The assembly comprising the two welded half-shells and the permanent magnet constitutes the second element 20 of the mobile dental prosthesis attachment system according to the present invention.

 You can check the tightness of the capsule on each finished part.

 Before packaging, the capsules 20 undergo a remagnetization step to overcome the risk of demagnetization which could occur during the welding of the two half-shells, if the laser beam caused accidental overheating of the permanent magnet.

 The magnet which is encapsulated is according to the present invention preferably of the neodymium / iron / pig type, having the shape of a disc 4 mm in diameter and 2 mm thick. This one has an open magnetic field.

 The assembly has the advantage of presenting no risk to the health of the patient dc by the perfectly biocompatible nature of the alloy used for the production of the two shells and for the controlled sealing of the assembly.

 In the context of the invention, the use of a permanent magnet of neodymium / iron / boron type has the advantage of providing a product B (magnetic induction) by H (magnetic field) maximum higher than that of the other magnets generally used in other systems such as samarium / cobalt magnets.

 In addition, the fact of enclosing it in a precious metal capsule, unalterable in salivary medium, the tightness of which is checked piece by piece guarantees that no known corrosion phenomenon will occur.

 The re-magnetization cycle of the capsules after laser welding takes place in the case where the welding has damaged the magnetic qualities of the magnet, by heating the magnet beyond its Curie point, located between 250 and 3000C depending on the nuances of neodymium-iron-boron magnets used.

Stage 4 of the invention
Manufacture of the mobile dental prosthesis attachment system
A fabrication of the mobile dental prosthesis attachment system is carried out in collaboration by the dental technician and the dental surgeon, according to the procedure described in the presentation of FIGS. 1 to 6.

 It is observed that in a first step, represented in FIG. 1, the sealing of the Richemond plateau or screed 10 made of magnetic alloy according to the present invention is carried out in the root part 12 of a tooth or equivalent part of the gum or the upper or lower jaw.

 Then, the removable dental prosthesis 15, which itself comprises one or more false teeth 14, has its inner face or lower surface 18 bored with a drill bit 19 and the practitioner checks the correctness of the internal cavity.

 Then, with reference to FIG. 3, the practitioner checks, after positioning the capsule 20 against the Richemond plate 10, the correct positioning of the mobile prosthesis 15.

Then, with reference to FIG. 4, the practitioner deposits the capsule 20 containing the permanent magnet against the Richemond plate 10 and can fix it temporarily using a material well known to him, to the plate of
Richemond, in order to facilitate the adjustment of the capsule in the lower surface of the assistant mobile prosthesis.

 Then, with reference to FIG. 5, the prosthetist deposits a cement on the upper face of the capsule 20 such as a self-curing resin, before bringing as shown in FIG. 6, the mobile dental prosthesis 15, in order to secure the capsule 20 containing the permanent magnet to the mobile dental prosthesis.

 It is thus understood that the invention makes it possible to produce a system for attaching a mobile dental prosthesis to a root piece of a tooth, in a perfectly safe, biocompatible manner and without the risk of creating an allergy.

 Naturally, the invention includes all the means constituting technical equivalents of the means described as well as their various combinations.

Claims (20)

CLAIMS 1. Magnetic alloy based on precious metals, characterized in that it contains sufficient iron to make the alloy magnetic. 2. Magnetic alloy according to claim 1, characterized in that it comprises from 10 to 25% of gold and from 5 to 30% of silver, combined with 8 to 15% of iron and is based on palladium which in constitutes the balance. 3. Alloy according to claim 1 or 2, characterized in that it has the following composition  Au: around 20%; Ag: about 10%; Fe: about 10%; Pd: the balance is about 60% by weight. 4. Use of the magnetic alloy as defined in any one of claims 1 to 3 above for the manufacture of a global dental attachment system between a mobile dental prosthesis and a fixed dental part such as a root part a tooth, or equivalent part of the gum comprising: a first element (10) sealed in the fixed dental part (12) and a second movable element (15), one of said first and second element comprising said magnetic alloy. 5. Global system of dental attachment between a mobile dental prosthesis and a fixed dental part such as a root part of a tooth, or equivalent part of the gum comprising: a first element (10) sealed in the fixed dental part ( 12) and a second movable element (15), one of said first and second element comprising on the one hand a magnetic alloy and on the other hand a permanent magnet, characterized in that the magnetic alloy is based on precious metals containing iron in sufficient quantity to make said alloy magnetic, as defined in one of the aforementioned claims 1 to 3, and forms part or constitutes said first element (10), and the magnet forms part or is incorporated in said second element (15). 6. System according to claim 5, characterized in that the magnetic alloy comprises dc 10 to 25% gold and 5 to 30% silver, combined with 8 to 15% iron and is based on palladium which cn constitutes the balance. 7. System according to one of claims 5 or 6, characterized in that the magnetic alloy has the following composition  Au: about 20%, Ag: about 10%; Fe: about 10%; Pd: the balance, about 60% by weight.  System according to one of Claims 5 to 7, characterized in that the second element (15) comprises a capsule (20) made of a precious metal alloy containing a permanent magnet. 9. System according to claim 8, characterized in that the aforementioned capsule is made from two cups welded together in a leaktight manner and having a very small thickness, ideally a thickness of about 0.1 mm. 10. System according to claim 8 or 9, characterized in that the precious metal capsule comprises at least one precious alloy based on gold or silver or dc preferably a combination of the two and at least one precious alloy with based on platinum or palladium or preferably a combination of the two. 11. System according to one of claims 8 to 10, characterized in that the capsule is made of a metal alloy combining four precious metals gold / silver / platinum / palladium. 12. System according to one of claims 8 to 11, characterized in that the alloy of the capsule has the following composition: gold: approximately 4 to 12% silver: approximately 30 to 40%, platinum: approximately 20 to 30% ; palladium: about 20 to 45%. 13. System according to one of claims 8 to 12, characterized in that the metal alloy of the capsule has the composition: gold: approximately 8% silver: approximately 37%; platinum: about 25%; palladium: about 30%. 14. System according to one of claims 8 to 13, characterized in that the permanent magnet is of neodymium / iron / boron type. 15. Capsule (20) cn alloy of precious metals, in particular produced from two welded cups, as means specially designed for the implementation of the overall dental attachment system as defined in any one of claims 8 to 14. 16. Capsule according to claim 15, characterized in that it comprises at least one precious alloy based on gold or silver or preferably on a combination of the two ct at least one precious alloy based on platinum or palladium or preferably a combination of the two.  1 7. Capsule according to claim 15 or 16, characterized in that the capsule is made of an alloy combining four precious metals gold / silver / platinum / palladium. 18. Capsule according to one of claims 15 to 17, characterized in that the metal alloy of the capsule has the following composition: gold: approximately 4 to 12%; silver: around 30 to 40%; platinum: about 20 to 30%; palladium about 20 to 45%. 19. Capsule according to one of claims 16 to 18, characterized in that the capsule has the composition gold: approximately 8%; silver: approximately 37% platinum: approximately 25 0% palladium: approximately 30%. 20. Capsule according to one of claims 15 to 19, characterized in that it contains a permanent magnet, preferably of neodymium / iron / boron type. 21. Use of an alloy based on precious metals to constitute a capsule (20) of a mobile dental prosthesis attachment system, containing a permanent magnet, as defined in any one of claims 8 to 14. 22. Use according to claim 21, characterized in that the alloy based on precious metals constituting the capsule comprises at least one precious alloy based on gold or silver or preferably a combination of the two, and at least a precious alloy based on platinum or palladium or preferably a combination of the two, more preferably this alloy combining the four precious metals gold / silver / platinum / palladium. 23. Use according to one of claims 21 or 22, characterized in that the alloy of the capsule has the composition: gold: approximately 4 to 12 / O, better approximately 8%; silver: about 30 to 40%, better about 37%; platinum: about 20 to 30% better about 25%; palladium: about 20 to 45%, better about 30%.