Abstract: A dental implant includes an insert element of a titanium-based material inserted and soldered into a blind hole in an anchoring element of a ceramic. The insert element has spacer members to center it in the blind hole, with a uniform circumferential gap space relative to the anchoring element. A portion of the insert element protrudes outwardly beyond an end face of the anchoring element. The blind hole is partly filled with a glass solder, and the insert element is inserted into the blind hole, whereby some of the glass solder is displaced out of the gap space onto the end face of the anchoring element and the protruding portion of the insert element. A thermal soldering process secures the insert element into the anchoring element. The protruding portion of the insert element and remaining excess solder are removed to form a planar surface.

Abstract: An orthopedic implant in the form of a femoral component of a knee endoprosthesis has sliding tribological surfaces formed by inserts of a ceramic material based on zirconium dioxide or aluminum oxide, which are inserted and transition flushly into a metallic base body. The inserts are connected to the base body by a silicate ceramic solder, which is solidified or hardened in a ceramic firing, and by a silicate glass solder. Discharge channels in the metallic base body help to produce a homogeneous glass solder layer and to avoid an excessively intense heat treatment of the solder connection, which could lead to fractures in the titanium oxide layer of the base body. Because a coating of a softer glass solder may be additionally provided on the sliding tribological surfaces of the inserts, the abrasive wear is further reduced and the service life is further increased.

Abstract: A dental implant includes an insert element of a titanium-based material inserted and soldered into a blind hole in an anchoring element of a ceramic material. An outer surface of the insert element has spacer members to center the insert element in the blind hole, with a uniform circumferential gap space relative to the anchoring element. The insert element is longer than the blind hole, so that a portion of the insert element protrudes outwardly beyond an end face of the anchoring element. The blind hole is partly filled with a glass solder suspension, and the insert element is inserted into the blind hole, whereby an excess amount of the glass solder is displaced out of the gap space onto the end face of the anchoring element and the protruding portion of the insert element. A thermal soldering process secures the insert element into the anchoring element. The protruding portion of the insert element and remaining excess solder is removed to form a planar surface.

Abstract: An orthopedic implant in the form of a hip joint endoprosthesis includes a ceramic head set onto an anchoring shaft, which is configured and adapted to be inserted and anchored into a bone. The head has an inner blind recess. The anchoring shaft has a tenon. A metallic sleeve having an approximately central through-bore is soldered into the recess of the head. The tenon of the anchoring shaft is inserted and secured in the bore of the sleeve. The head is made of a ceramic based on zirconium dioxide, aluminum oxide or a mixed ceramic, while the sleeve is made of a high strength titanium material. A connection between the head and the sleeve is produced by a silicate ceramic solder that solidifies or hardens in a ceramic firing, and by a subsequently applied glass solder, of which the excess can exit from the recess via the through-bore into a hollow space existing between the sleeve and the tenon.

Abstract: An orthopedic implant in the form of a femoral component of a knee endoprosthesis has sliding tribological surfaces formed by inserts of a ceramic material based on zirconium dioxide or aluminum oxide, which are inserted and transition flushly into a metallic base body. The inserts are connected to the base body by a silicate ceramic solder, which is solidified or hardened in a ceramic firing, and by a silicate glass solder. Discharge channels in the metallic base body help to produce a homogeneous glass solder layer and to avoid an excessively intense heat treatment of the solder connection, which could lead to fractures in the titanium oxide layer of the base body. Because a coating of a softer glass solder may be additionally provided on the sliding tribological surfaces of the inserts, the abrasive wear is further reduced and the service life is further increased.

Abstract: An orthopedic implant in the form of a hip joint endoprosthesis consists of a head, which is set onto an anchoring shaft, which itself is insertable into a bone and anchorable therein. The head comprises an inner blind-hole-type recess, and the anchoring shaft is provided with a tenon for inserting into this recess. A sleeve provided with an approximately central through-bore is soldered into the recess of the head, via which sleeve the head is setable or mountable on the tenon. The head consists of a ceramic based on zirconium dioxide, aluminum oxide or a mixed ceramic, while the sleeve consists of a high strength titanium material. The connection between the head and the sleeve is produced by a silicate ceramic solder that solidifies or hardens in a ceramic firing, as well as by a subsequently applied glass solder, of which the excess can exit via the through-bore into a hollow space existing between the sleeve and the tenon.

Abstract: For an orthopaedic implant, an insert body of a non-metallic material is arranged in a socket of an originally metallic material. The insert body consists of a ceramic based on zirconium dioxide, aluminum oxide or a mixed oxide ceramic, whereas the socket is preferably produced of pure titanium or a titanium alloy, for example Ti-6Al-4V, provided with a plurality of small holes and preferably embodied as a mesh or net structure. The titanium net structure is firstly imparted with ceramic properties with the aid of a silicate glass solder solidified or hardened in a ceramic firing, the subsequent connecting or joining between the ceramic insert body and the now also “ceramic” titanium socket is achieved by means of a glass solder which is based on silicon dioxide (SiO2) and which connects or joins the two components with one another.