Abstract: The system includes a nail jig which is initially secured by means of fixing nails (38), after production of a stable three-point mounting of plates and legs extending from the nail jig, on the femur (10) in the vicinity of the condyles of the knee joint. The nail jig can then be removed from the femur (10), leaving the fixing nails (38) in the femoral bone. A saw jig (40) with the same basic shape as the nail jig and with identical holes for the fixing nails (28) can be placed on the fixing nails which were left in the femur (10). Precise allocation of boring pairs by both the nail and saw jig enables twist to be transferred to the artificial knee joint system at a ratio of 1:1 according to the predetermined size of the part of the femur to be implanted. In order to compensate for the incline in the frontal resection surface which is attached at a slant, the system is provided with a compensating wedge (46) which is inserted between the striking plate (32) and the lateral condyle (39′).

Abstract: A prophylactic implant is provided for protecting osteoporosis-affected bone segments against fractures, in particular the neck of the femur, the vertebral column and the wrist. According to a proposed solution, the implant comprises a thin-walled hollow reinforcing body (1) having such a large number of passages (2) in its outer wall (3) that the ratio of the total area of the passages (2) to the total surface area is at least 1:2.

Abstract: A knee joint endoprosthesis has an element for the femur (2) which is substantially U-shaped when seen from a medial to a lateral angle, one horizontal, two diagonal and two vertical support surfaces facing the femur for accommodation on the resected femur bone, which is fitted with two runners (24, 25), and an element for the tibia (1) having two slide tracks (4, 5) on which the runners for the femur element can roll, and optionally slide, and a horizontal support surface (6) facing the tibia for accommodation on the resected tibia. The femur element (20) and tibia element (1) are configured without any shanks. At least both diagonal support surfaces of the femur element (2) and the horizontal support surface (6) of the tibia element (20) are fitted with an open-mesh, three-dimensional spatial network structure (7) which is an integral component of the base structures (8, 8′) of the femur element (20) and the tibia element (1).

Abstract: An implant is provided as a bone replacement having an open-meshed, three-dimensional structure which at least partially covers its surface and which is constructed from particles which are connected to a base structure (1) of the implant. The particles have four to eight studs (3) extending radially outward from each other, at least three of which are connected directly to the base structure. At least the ends (7) of the studs (3) projecting out freely from the base structure (1) form undercuts (8) and have a surface which is outwardly rounded off.

Abstract: A femur endoprosthesis for an artificial hip joint is provided with a stem (1) which can be implanted without cement in the upper region of a femur below the greater trochanter. The proximal end (8) of the stem is connectable with an adapter (2) for accommodating an artificial spherical part of a joint (20). The exterior of the stem is at least partially covered with an open-meshed three-dimensional spatial lattice structure (9). A distal end of the stem is bent caudally with a caudally oriented step (31) in the transition area and constructed as a stem end (30), which is also at least partially covered with an open-meshed three-dimensional spatial lattice structure (9).

Abstract: A femur endoprosthesis for an artificial hip joint includes (a) a shell (1) which can be implanted without cement in the upper region of a femur below the greater trochanter, the proximal end (8) of the shell being connectable with an adapter (2) for accommodating an artificial spherical joint part (20), wherein the exterior of the shell is at least partially covered with an open-meshed three-dimensional spatial lattice structure (9), and (b) a draw plate (3) in which a draw-in screw (4) can be fastened, which can be inserted in the interior of the shell through a through bore (5) in its distal end (6), and which can be screwed in with a thread (7) provided therein.

Abstract: A process is disclosed for producing a bone implant which has at least in sections a surface structure with open pores. The positive model for the implant is moulded from a base body made of a modelling material coated at least in sections with a porous coating having a predetermined pore structure. Also disclosed is a bone implant made of metal or plastics with a local distribution of pore sizes and/or densities at the surface of the implant that corresponds to the trabecular structure of the osseous environment in which the implant is implanted.

Abstract: An implant to replace a rear patella part is provided, which comprises a prosthesis part imitating the patella part and a metal attachment part fixed in the prosthesis part, with which the implant can be attached in the natural patella part. In order to produce a gentle and secure attachment for the implant, the attachment part has a convexly curved external contour, which at least in sections has an open-cell and open-pore surface structure.