The invention relates to a single tooth implant for a fixed dental prosthesis having the features of patent claim 1.
In the case of a single tooth implant, as is known from DE 40 28 855 C2 and also forms the subject matter of DE 195 09 762.9-32, prevention against rotation is achieved by the main body form-fitting elements at the base of the annular recess of the main body and the spacer socket form-fitting elements, which are complementary thereto, are provided on the cervical end edge of the centring union of the spacer socket. From a production engineering point of view such form-fitting elements are relatively difficult to produce, wherein in some applications it is also particularly advantageous that the full depth of the annular recess or the centring union is not available for centring, fixing and securing the spacer socket relative to the main body.
In another dental implant also, as is provided in DE 37 35 378, similar difficulties occur, based on the fact that the form-fitting elements of the main body are located a distance away from its coronal front edge inside a blind hole of the main body.
DE 41 27 839 A1 discloses an implant main body, the central annular recess of which comprises a form-fitting element which connects directly to the coronal front edge of the main body, wherein the form-fitting element is groove-shaped and the retaining part to be inserted in the main body is designed with a shape complementary thereto. A separate implant abutment or retaining screw is not provided in this case.
DE 195 34 979 C1 discloses a single tooth implant in which the form-fitting elements of the main body are arranged in direct connection to its coronal front edge with corresponding arrangement and design of the complementary abutment form-fitting elements. The fact that the entire depth of the annular recess of the main body is available for centring and guiding the abutment is designed to produce a significantly improved stability of the connection between the spacer socket and the main body while providing a greater design tolerance in the type of division and of the shape of the form-fitting elements.
Common to all of these types of dental implants is the fact that in the coronal area of the main body, as a result of the lateral forces exerted on the crown, considerable stress is generated on the jaw bone on the opposite side of the main body to that on which the forces are applied and so, due to the possible excess load on the bone adjacent to the implant, pressure atrophy and disintegration can occur. In principle—as is also the case for the dental implant—any force exerted on a natural tooth that is elastically suspended in a bony alveole leads to a displacement of the tooth but also to an elastic deformation of the tooth in the longitudinal axis. This displacement and elastic deformation protects against excess strain on the alveolar bone. This physiological tooth mobility differs from the known loosening of teeth in the form of pathological tooth mobility, which can also occur similarly to the processes in connection with the implant main body.
In the prior art in accordance with DE 38 39 724, an enossal single tooth implant having an intermediate element is described, which is intended to perform isolation and damping functions. The intermediate element there, however, fulfils a function which is not satisfactory in all respects, because the lateral forces exerted during chewing are not adequately diverted via the dental implant and implant abutment, and the intermediate element is subject to increased deformation and wear. This allows inflammation sites to form on the implant and to cause bacteria colonisation, which as a result of toxin secretion can cause damage to the soft tissue and therefore the disintegration of the implant.
The inventors have recognized that it is necessary to prevent or at least reduce such a disintegration of the main body due to the lateral forces. The object of the invention is therefore to provide a dental implant in which the development of disintegration due to a combination of mechanical and bacterial stress is prevented, while at the same time supporting the engraftment process, which can take several months from completion of the reconstruction process up to the full strength of the implant in the jaw.
In accordance with the invention this object is achieved in a generic enossal single tooth implant by the combination of the features of the patent claim 1. Advantageous embodiments of the invention are the subject matter of the dependent claims.
The present invention relates to an enossal single tooth implant for a fixed dental prosthesis, having
In addition, at the coronal end of the end sections of the abutment and the main body a sealing element may be arranged between the abutment and the main body.
By means of the damping element, any physiological interaction in particular during the chewing action can be compensated by loading and relieving, and any disruptive effect on the connective tissue around the implant can be reduced.
The single tooth implant according to the invention therefore comprises a main body, an abutment that can be inserted into the main body and a retaining screw penetrating the main body and the abutment, which fixes the position of the abutment relative to the main body and can be screwed into a threaded section provided at the apical end of the main body.
The body has an annular recess into which the abutment can be inserted. The annular recess therefore comprises a guide section at the apical end of the annular recess, a form-fitting section and a coronal end section, to which the corresponding sections of the abutments are matched in terms of size. The coronal end section in the main body, to which the corresponding section in the abutment is matched, can be designed cylindrical or conical. In the form-fitting section form-fitting elements are arranged, which prevent the relative movement of the abutment and main body in the circumferential direction.
In the region of the coronal end section the abutment and main body are radially spaced apart from each other such that an annular gap is formed for accommodating a damping element. The annular gap is produced due to the different radial diameters of the main body and the abutment in the same plane and is dimensioned such that a damping element is arranged between the abutment and the main body in the manner of a ring or a sleeve, or else in the form of a corrugated sleeve, preferably made of metal such as stainless steel or titanium, in the following called simply a damping element, which can damp forces acting laterally on the single tooth implant, for example via the crown during chewing actions, and at the same time, depending on the material, acting as a sealing element.
This allows the forces acting to be deflected, firstly via the abutment onto the apically placed section or sections of the main body. In particular in the case where the damping element is designed in the form of a corrugated sleeve, a seal, for example an O-ring, can be provided coronally to the corrugated sleeve in a groove on the abutment for sealing between the main body and the abutment. This means that no liquid, such as saliva, can penetrate into the annular gap between the main body and the abutment. The damping element can also be arranged, as for example in the design as a corrugated sleeve, in a recessed (incised) groove section on the abutment, to prevent the damping element from slipping off the abutment when it is pulled out of the main body. In any case, even in this embodiment in the area of the coronal end section the abutment and the main body can be radially spaced apart from each other such that due to the radial spacing of main body and abutment the damping element can still fulfil the damping function. The radial spacing of the main body and abutment in the form of the annular gap according to the invention is not to be equated with a clearance fit, but is much larger than such a clearance fit designed for the component dimensions, so that the damping element can be arranged in the annular gap.
In a further embodiment of the single tooth implant according to the invention for a fixed dental prosthesis, the form-fitting sections of the abutment and main body are designed such that after insertion of the abutment into the main body, an annular gap, preferably extending over the entire axial length of the form-fitting sections, is also formed in the form-fitting section between the abutment and main body, which is designed for receiving a damping element or provides clearance for the mobility of the abutment in the form-fitting region.
In the single tooth implant for a fixed dental prosthesis, the form-fitting section and the coronal end section on the main body can be equiradial to each other in the transition region and the form-fitting section and the coronal end section on the main body can also be equiradial to each other in the transition area.
For example, in the case of a conical end section in the main body, the cone angle in the coronal end section of the abutment can be less than in the main body, so that an axially coronally wedge-shaped extending circumferential annular gap is formed between the main body and abutment. The cone angle is defined as the angle between the longitudinal axis of the implant and the outer surface of the cone.
The damping element is arranged in the annular gap and can be secured relative to the abutment using one or more fixing elements, such as a circumferential collar, groove, peaks or surface wrinkles to prevent slippage when the abutment is inserted into or extracted from the main body. Before the insertion, the sleeve or the ring is pushed over the abutment and secured thereon against displacement via the fixing element or elements.
The damping element in the form of a ring or preferably a sleeve, can be made of PTFE, PVAC or similar polymers or copolymers, which have both a sufficient modulus of elasticity, and also a sufficient mechanical strength to meet the requirements on a permanent basis. Depending on the material used, the damping element can additionally exercise a sealing function. The damping element can also be advantageously provided by spraying a polymer onto at least one component of the main body and particularly the abutment.
Such a damping element, for example as a sleeve, which preferably extends over the entire axial length of the annular gap between the abutment and main body in the coronal end section, can also be made from porous, such as foam-based, material or solid material, wherein as a solid material the embodiment in particular comprises a profiling or a cross-section profile with elevations and/or indentations, which when pressure is applied enable the adaptation to the annular gap with variable cross-section. Thus during insertion of the abutment into the main body, it is possible to adapt the adjacent areas of the damping element to the inner surface of the main body and the outer surface of the abutment. It is also possible to design the damping element in the form of a corrugated (hose)sleeve, which is preferably fabricated from metal as specified above, and which under the action of lateral forces on the crown is compressed on the opposite side to that on which the forces act, and as the force subsides as a result of the return forces is reset back into the starting position. In addition, a seal such as an O-ring can be arranged at the coronal end of the annular gap, as mentioned. Preferably, such a corrugated sleeve is secured against displacement on one side of the abutment via a bead or collar.
After the implantation of an implant according to the invention and adaptation of the crown, as a result of lateral or lateral-axial forces acting on the abutment via the crown during the chewing action, an axial flexing of the abutment can occur, which are in turn laterally damped by the damping element and can be diverted onto the apical sections of the main body arranged in the jaw. Thus the coronal sections, and in particular the area of the coronal alveolar wall, are relieved of the action of the force.
This protects against bone loss and a transformation of the bone into a connective tissue encapsulation around the implant in the jaw.
The guide section and the form-fitting section can also be designed as a single form-fitting guide section, which at the same time fulfils the functions of guiding the abutment in the main body and providing a form-fitting connection between the abutment and the main body to prevent rotation. In particular, this is possible if the form-fitting guide section is designed as a cylindrical section with axial grooves on one component and with cams which engage in the grooves on the other component. In this case the design of the main body with axial cams that engage in axial grooves on the abutment is preferred.
The guide section on the main body and abutment are each designed in the manner of a clearance fit with one another. This enables a reliable guiding of the abutment in the main body. In the case that the guide section and the form-fitting section are designed as two distinct sections, when inserting the abutment the guide section engages before the form-fitting section is brought into engagement.
In the case of such a clearance fit the maximum radial dimension of the guide section of the abutment is smaller than the minimum radial dimension of the guide section of the main body. The tolerance ranges are selected such that the maximum clearance, i.e. the maximum radial distance between the minimum dimension of the guide section of the abutment and the maximum dimension of the guide section of the main body, obtains a value sufficient for the insertion resistance and guiding.
According to the invention, it is also possible to design the apically arranged guide section on the main body as a hollow cylinder and the coronal form-fitting section thereto and the end section in a continuously conical form, and on the abutment to design the apically arranged guide section with a clearance fit relative to the guide section of the main body, the form-fitting section being conical with the same cone angle as in the form-fitting section on the main body and the coronal end section being conical with a smaller cone angle compared to the form-fitting section.
In a particular embodiment of the enossal single tooth implant according to the invention, in particular with a conical form-fitting section arranged between the apical guide section and the coronal end section, the apical guide sections of the abutment and main body are designed such that after insertion of the abutment into the body a conical or cylindrical annular gap, preferably extending over the entire axial length of the apical guide section, is formed between the abutment and main body for receiving an apical damping element, for example in the form of an elastic sleeve or a compensator, e.g. made of stainless steel as described above. The apical damping element arranged in the annular gap can be formed of the same material as the damping element in the coronal end section, but preferably has a higher material hardness/lower elasticity and is also used for guiding the guide section of the abutments in the guide section of the main body. In this design of the enossal single tooth implant according to the invention with an apical damping element, in the event of a lateral force acting on crown placed on the abutment a damped “pendulum-like” (rod-like) movement of the abutment can take place above and below the conical form-fitting section in the annular recess of the main body. The pivot point of the abutment is in the region of the form-fitting section or apically below it. In a cylindrical design of the form-fitting section the movement can take place over the entire length of the cylindrical sections (guidance section, form-fitting section and end section) and the pivot point of the abutment lies in the apical region of the guide section. In these embodiments there is sufficient clearance available in the form-fitting section to enable an oscillatory motion about the respective pivot points, as indicated above. Advantageously, this embodiment of the enossal single tooth implant according to the invention interacts with an apical damping element and with a coronal damping element with the preferably swivel-ring-shaped collar on the abutment, described in the next section, which can be supported on the front edge of the main body, thus enabling a supported pendulum-like motion of the abutment.
Preferably, the enossal single tooth implant according to the invention for a fixed dental prosthesis has an abutment with a collar facing the main body, which is arranged above the coronal end section of the abutment and is conical or swivel-ring-shaped and can be supported on the spherical-segment-ring-like front edge of the main body. This means that, under the action of lateral forces and an axial flexing of the abutment, the abutment can be supported on the main body in an inclined position and after the force is removed is able to “spring back” into the normal position.
In order to enable the main body to be securely screwed into the jaw of the patient, and in the process to allow sufficient torque to be applied to the main body without the form-fitting elements being damaged even when the diameter or angle of the bore in the jaw is not exactly matched, it is possible to provide in the form-fitting section, the guide section or a single form-fitting guide section of the main body, in addition to the form-fitting elements, form-fitting screw-in elements, in the following abbreviated to screw-in elements, which after insertion of the screwing-in tool, such as a screw bit with customized tool head, produce the form fit between the screw-in element on the main body and the screw-in element on the screwing-in tool, for example in the manner of a male-part and female-part connection, and so enable the main body to be screwed into the jaw.
After screwing the main body into the jaw and withdrawing the screwing-in tool, the abutment can be inserted in the main body so that it is circumferentially alignable, enabling the form-fitting elements on the main body and abutment to be brought into engagement with each other and in the process, fix the positions of the main body and abutment relative to each other. Then the main body and abutment are fixed in position relative to each other via the retaining screw. A form-fit between the screw-in elements on the main body and the form-fitting elements on the abutment is preferably not provided according to the invention.
This therefore allows the main body, as a result of the design of the main body according to the invention with the screw-in elements, using a tool which engages with the screw-in elements, to be screwed into the jaw bone with increased torque compared to the designs from the prior art. Although the screw-in elements can be provided in each of the two sections (centring/guide section at the apical end of the annular recess and the form-fitting section), the screw-in elements are preferably arranged in the cylindrical or preferably conical form-fitting section between the apical guide section and the coronal end section. A form fit or force fit between the screw-in elements on the main body and the form-fitting elements on the abutment is preferably not provided according to the invention.
A conical form-fitting section increases the diameter of the guide section to the diameter of the end section and is formed on the main body in the shape of a hollow frustum, which mates with a frustum on the abutment. In principle, the form-fitting section on the main body can also be designed as a hollow cylinder, wherein in that case the at least one form-fitting element and the at least one screw-in element can lie on parallel radial planes, but the design of the form-fitting section as a hollow frustum on the main body is preferred.
In the region of the form-fitting section, which as indicated can be cylindrical or conical, the screw-in elements on the main body can be arranged in the circumferential direction preferably between the form-fitting elements on the main body, which can be brought into engagement with the form-fitting elements on the abutment, and are preferably interleaved.
With regard to the screw-in elements, in principle it is possible to arrange the male part(s) on the main body and the female part(s) on the screwing-in tool or vice versa, wherein the design with the arrangement of the male part(s) on the screwing-in tool and the female part(s) on the body is preferred.
The screw-in elements can each be designed in the form of a recess on the body and a nose or projection on the screwing-in tool that engages in the recess. Of these, the design of at least one, in particular two, three or four, recess(s) in the form-fitting section on the main body is preferred.
The screw-in elements can each be designed in particular in the form of two or more, preferably three or four to six, coaxial plane surfaces, preferably arranged evenly spaced circumferentially in the annular recess on the main body, and the tool in the form of a screwing-in tool with a three-sided, four-sided or multi-sided head.
In the form-fitting section therefore, recesses and main-body-abutment form-fitting elements, the latter as anti-rotation protection, can be arranged so that in the form-fitting region screw-in elements and main-body-abutment form-fitting elements are preferably arranged alternately around the circumference.
For example, on the main body two, three or four recesses are provided as screw-in elements and in each case one main-body form-fitting element is provided between two adjacent screw-in elements. On the abutment, form-fitting elements corresponding to the main body form-fitting elements are preferably provided in sufficient number to allow an alignment of the abutment. In the case of two, three or four main body form-fitting elements on the main body, for example, two, three, four, six, eight, nine or more matching form-fitting elements can be provided on the abutment.
According to the invention the form-fitting section of the main body and the form-fitting section of the abutment are matched to each other in terms of their shape, so that the abutment can be inserted into the recess of the main body, so that the respective form-fitting elements can be brought into engagement with one another and thus prevent any movement in the circumferential direction. The respective form-fitting sections can be designed as hollow frustum-shaped or hollow cylindrical regions of the annular recess or bore, or else with sections having different diameters, in the main body, and in each case an external cylindrical section or sections of the abutment corresponding thereto.
The design according to the invention of the enossal single tooth implant allows the use of different materials and material combination, which can be selected from the group of metals, the metallic alloys, ceramic materials and combinations thereof.
The implant preferably consists of a material selected from the group of metals, the metallic alloys, ceramic materials and combinations thereof. The implant material used preferably consists of metallic materials such as pure titanium or metallic titanium alloys, chrome/nickel/aluminium/vanadium/cobalt alloys (e.g. TiAIV4, TiAlFe2,5), stainless steels (e.g., V2A, V4A, chromium-nickel 316L), ceramic materials such as hydroxyl apatite, aluminium oxide, zirconium oxide or a combination thereof, in which the metallic material is present as a composite material with ceramic material.
The following description of the elements of the invention applies to all embodiments, unless stated to the contrary.
The guide section in the base body adjoins the threaded section for the retaining screw, which is arranged in the apical end of the main body. In a coronal direction relative to it, the form-fitting section is arranged, in which at least one, in particular two, three or four screw-in elements and at least one, in particular two, three or four or more main-body-abutment form-fitting elements are provided. Also in the coronal direction relative thereto the end section is arranged, in which a sealing element can be provided between the main body and the abutment. The sealing element can be designed in the form of an elastic seal which is arranged in a groove in either of the main body or the abutment.
The axial lengths of guide section, form-fitting section and end section can be dimensioned such that the apical guide section and coronal end section are each longer than the form-fitting section.
In accordance with the invention the preferably cylindrical guide section provided axially and apically to the form-fitting section allows a reliable and stable fixation of the abutment in the main body by the retaining screw, since abutment and main body are mounted via the guide section with a clearance fit in the manner of a pipe-in-pipe fitting. The radial internal diameters of the guide section in the main body and the outer diameter of the abutment are chosen such that the wall thickness in the main body is sufficient to prevent plastic deformation of the main body walls under the action of lateral or angular stress on the implant during a chewing action. This also applies in a corresponding way to the embodiment of the enossal single tooth implant according to the invention with an additional damping element in the region of the guide sections of the main body and abutment, as is described below.
In one embodiment according to the invention, the form-fitting section of the main body can be designed in particular as a hollow frustum or a partial form thereof. In this case, the form-fitting section of the abutment is designed as a solid frustum corresponding to the hollow frustum.
In this embodiment the form-fitting section of the main body is designed as a hollow frustum with one circular surface having a smaller diameter (top surface) and with one circular surface having a larger diameter (base surface), wherein the longitudinal axis of the hollow frustum is arranged coaxially to the longitudinal axis of the main body, the circular surfaces adjoin the hollow frustum and the circular surface with the larger diameter is facing the coronal end of the main body.
As a result of the design of the main body according to the invention with the screw-in elements, by means of a tool that engages with the screw-in elements the main body can be screwed into the jaw bone with increased torque compared to the designs from the prior art, and after insertion into the main body the abutment is reliably secured against rotation by means of the form-fitting elements with mutually complementary shapes.
According to the invention, the mutually complementary form-fitting elements on the main body and abutment are each designed in the form of a male-part to female-part connection, wherein the male part(s) is/are preferably arranged on the main body. On the basis of the arrangement thus selected, due to the avoidance of any reduction in the wall thickness of the main body, a precise force transmission is possible even with ceramic materials, which enables the use of a fully or partially ceramic main body and/or abutment, in addition to the known metals and alloyed materials. But it is also possible for the male part(s) to be arranged on the form-fitting section of the abutment and the corresponding female parts to be arranged on the main body.
In accordance with the invention, each male-part form-fitting element can have the form of a spring bar which extends parallel to the longitudinal axis of the main body, and in each case engages in a corresponding female part on the other component (abutment) secured against rotation. The form-fitting elements can be cut from the components of the main body and the abutment by mechanical machining methods, such as milling, drilling etc.
The form-fitting section can be designed cylindrically or preferably conically. In the case of a cylindrical design the form-fitting section on the abutment is designed in the form of a cylindrical section, which with its outer diameter is matched in length and diameter to the hollow cylindrical bore on the main body.
If the form-fitting sections are designed as a hollow frustum on the main body and a frustum on the abutment, the at least one spring bar is designed such that the spring bar, depending on whether it is arranged on the main body or abutment, is radially convex about the longitudinal axis of the main body or abutment and axially tapers towards it in a wedge shape in the direction of the larger diameter of the frustum or hollow frustum, without increasing the diameter of the larger circular surface which closes off the frustum. The maximum radial height of the spring bar therefore corresponds to the difference in the radii of the circular surfaces closing off the frustum or hollow frustum, minus any clearance.
According to the invention, the spring bar can be advantageously designed in the form of a nose which is milled out of the main body, or of a pin which is held in a blind hole (retaining hole), wherein the blind hole can be provided coaxially to the longitudinal axis of the main body in the conical region of the hollow frustum or frustum, depending on the relative position of the male or female part in the body or the abutment, up to the region parallel to the threaded section. As a result of the conical surface on the hollow cone, or frustum, each pin is at least partially guided in a groove with a decreasing cross section towards the end opposite to the retaining hole, which results in a kind of wedge shape of the spring bar. In order to make the wall thickness in the form-fitting section as thick as possible, depending on the relative position of the male or female part in the main body or the abutment, the blind hole for receiving the pin or groove is arranged such that the outline of the hole touches the outline of the circular surface tangentially at the apical end, or the hole is arranged partially within the circular surface at the apical end.
The pins can each have a preferably circular, or regularly or irregularly polygonal cross-section, of which one cross-section segment protrudes from the groove in the conical wall radially to the direction of the longitudinal central axis, depending on the relative position of the male or female part, of the main body or the abutment, and can form the spring bar beyond the maximum axial length of the form-fitting section. In the simplest form a pin can have a cylindrical shape and be produced, for example, in a wire drawing machine. It is thus possible to produce the pin from a material with higher strength than the material for the abutment or main body, so that the force can be transmitted accurately via the form-fitting elements or screw-in tool.
In order to secure the pin axially, each pin can be fitted/plugged into the blind hole using a press fit.
To facilitate the ability to insert the abutment in different positions around the circumference, the form-fitting elements relative to the circumference of the abutment and main body can have an angular division, which allows an insertion of the abutment into the main body in different positions, such as a 15, 30, 45, 60, 90, 120, or 180 degree division. Also, the number of the female-part form-fitting elements can be greater than or equal to, for example, depending on the division, two or three times the number of those of the male-part form-fitting element. The preferred combination is of one form-fitting element, such as a pin, on the main body with one to six form-fitting elements such as grooves on the abutment, or accordingly two form-fitting elements on the main body and two, four or six form-fitting elements on the abutment, three form-fitting elements on the main body and three or six form-fitting elements on the abutment, or four form-fitting elements on the main body and four or eight form-fitting elements on the abutment, wherein the form-fitting elements in each case are regularly spaced over the circumference.
In one embodiment according to the invention, the abutment can comprise a bearing collar for the noses or pins of the main body in the form-fitting section. When inserting the abutment into the main body the noses or pins can rest with their respective coronal end at least partly on the bearing collar, the maximum width of which may correspond to the diameter but in particular to the radius of a pin, and when the abutment is rotated for the radial alignment of the abutment in accordance with the requirements of the implant dentist, said noses or pins snap into the form-fitting grooves.
For the implant abutment(s)/retaining screw, a female thread can be provided apically in the blind hole from the conical form-fitting and centring section of the main body, wherein the retaining screw can also completely traverse the abutment.
In addition, the invention also relates to a main body and an abutment as individual components of the implant according to the invention, which are designed completely in accordance with the embodiment details for the implant.
Another aspect of the present invention is that in addition to a simplified mechanical machining of the components of main body and abutment, which are each manufactured with corresponding form-fitting elements in the form of the above described tongue and groove connection in a centring and guide region, a balanced mechanical stability can be achieved in the mounting of the implant in the jaw and in its use during the chewing process, while at the same time preventing the loosening of the implant, which in the systems known in the prior art is not the case. At the same time, compared to the known solutions from the prior art the machining of the blanks of the main body and the abutment is significantly simplified and more cost-effective.
In the following, exemplary embodiments of the single tooth implant according to the invention and its components are described in detail by reference to the schematic drawings. These show:
As
The annular recess 16 comprises a guide section 18, which joins coronally to the female thread 14. The guide section 18 of the annular recess 16 connects in the coronal direction to a form-fitting section 20, which has an inside diameter that increases in the coronal direction compared to the guide section 18, and comprises a cylindrical inner wall having form-fitting elements, not shown in the embodiment according to
In the form-fitting section 20 the main body 10 is connected in the coronal direction to an end section 22, cylindrical in this embodiment, having a coronal front edge 24. The end section 22 has an inner wall corresponding to the outer diameter of the end section 58 of the abutment 50 in accordance with
In the form-fitting section 20, three or more recesses or internal triangular faces, not shown in
The main body 10 and the abutment 50 shown in
Even though the use of cylindrical pins is advantageous from a manufacturing point of view, it is also possible to use pins with a regular or irregular polygonal cross-section and a retaining groove hole with an appropriately matched cross-section and matched form-fitting groove.
During insertion of the abutment 50 shown in
By means of the retaining screw, not shown in
Depending on the division or sub-division ratio of the main body 10 or the abutment 50, the abutment 50 can be inserted in the main body 10 in different rotary positions, for example in a DEG division of 30°, 45°, 60°, 90°, 120° or 180°, which provides the treating dentist with a number of configuration options. The number of preferred abutment form-fitting elements used is greater than that of the main body form-fitting elements. Thus configurations of two pins as form-fitting elements in the main body 10 and two, four, six, eight, ten or twelve form-fitting grooves as form-fitting elements on the abutment 50, or in particular of three pins in the main body 10 and three, six, nine or twelve form-fitting grooves on the abutment 50, are advantageous. In the context of the invention, instead of an abutment for a single tooth implant a prosthetic structure element is also encompassed, which can be blocked, for example, with another prosthetic structure element in an adjacent main body in the jaw or can bridge an interdental gap to another prosthetic structure element in the jaw by means of a bridge element, as long as the design according to the invention makes use of at least one damping element as described above.
The embodiment of the implant according to the invention shown in
The embodiment of the implant according to the invention shown in
The embodiment of the implant according to the invention shown in
In the detail view of the embodiment of the implant according to the invention shown in
The schematic sectional view of an implant according to the invention shown in
The embodiment of the implant according to the invention shown in
Allen key. In addition, if desired, in this embodiment, radially at least partially overlapping, the front edge 24 of the main body 10 and the collar 52 of the abutment can overlap, wherein said collar is arranged above the coronal end section 58 of the abutment 50 and is conical or swivel-ring-shaped and can be supported on the spherical-segment-ring-like front edge 24 of the main body. This means that, under the action of lateral forces, the abutment can be supported on the main body in an inclined position and after the force is removed, is able to spring back into the normal position in a rod-like manner.
The embodiment of the implant according to the invention shown in
Number | Date | Country | Kind |
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10 2014 116 212.9 | Nov 2014 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/DE2015/100472 | 11/5/2015 | WO | 00 |