The present invention relates to a system for producing artificial osseous tissue comprising: a client computer acquiring an image information of a subject bone tissue from an imaging unit that picks up an image of a subject bone tissue of a patient to generate a 3D image information; a server computer identifying the subject bone tissue based on the image information of the subject bone tissue received from the client computer, generating a 3D image information of at least one therapeutic bone tissue model corresponding to the subject bone tissue, and transmitting the 3D image information of the at least one therapeutic bone tissue model to the client computer; and a machining unit for fabricating an artificial bone tissue based on the 3D image information of the therapeutic bone tissue model determined from the server computer.

The embodiments provide provides devices, instruments, and associated methods for treating joint pain. A joint is evaluated using magnetic resonance imaging to detect any defects in the subchondral bone. For example, using T2-weighted MRI images, bone marrow lesions or edemas can be identified, and using T1-weighted MRI images, associated regions of sclerotic bone adjacent to the bone marrow lesion can be identified. The treatment method may involve introducing a bone void filler material at the site to address the bone marrow lesion or edema, and/or drilling and inserting an implant to address the sclerotic bone, bone marrow lesion or edema, and insufficiency or stress fractures. An access path is mapped to a location in the subchondral region where the insufficiency fracture resides. The access path attempts to preserve an articular surface of the joint. A reinforcing member that stabilizes the insufficiency fracture is then implanted via the access path.

Implants, and processes for installing them, which replace the medial condyle and portions of the patellofemoral channel but preferably not portions of the lateral condyle that articulate relative to the tibia. Processes are provided which allow proper location and orientation of an anterior resection and a distal resection on the femur, which make use of a transition point which can be designated on the bone, for navigating proper positioning of such implants. Proper positioning of the implant relative to the femur for insuring a smooth transition between lateral portions of the implant and the lateral condyle is thus reduced to determining proper medial/lateral location of the implant on the anterior and distal resections. Such implants and processes can allow, among other things, for controlled location and orientation of an implant on the bone which saves lateral compartment bone, which eliminates the need to sacrifice the anterior and posterior cruciate ligaments, and which is adapted for minimally invasive surgery with its attendant benefits.

Disclosed are interosseous cages interposed between two bones. The cage includes at least one body with two bearing faces each bearing face being configured so as to come into contact with the two bones, the body being produced from a first material having a given strength, a through cavity produced in the body opening onto the two faces and an insert defined between two end faces and having a cross section which is at most equal to the cross section of the through cavity, in a manner such that the insert is slid into the cavity, this insert furthermore being configured in a manner such that its end faces are respectively a continuation of the two faces when the insert is in the cavity, the insert being produced from a second material which is stronger than the first material. Application primarily to the production of intervertebral cages.

The present invention relates to a system for producing artificial osseous tissue comprising: a client computer acquiring an image information of a subject bone tissue from an imaging unit that picks up an image of a subject bone tissue of a patient to generate a 3D image information; a server computer identifying the subject bone tissue based on the image information of the subject bone tissue received from the client computer, generating a 3D image information of at least one therapeutic bone tissue model corresponding to the subject bone tissue, and transmitting the 3D image information of the at least one therapeutic bone tissue model to the client computer; and a machining unit for fabricating an artificial bone tissue based on the 3D image information of the therapeutic bone tissue model determined from the server computer.

The present invention relates generally to a prosthetic spinal disc for replacing a damaged disc between two vertebrae of a spine. The present invention also relates to prosthetic spinal disc designs that have interlocking components.

An artificial knee joint includes a tibial component implanted into the proximal end of a tibia, and a bearing component coupled to the tibial component, in which the tibial component includes an interference prevention portion capable of preventing interference with the bearing component when the bearing component is inserted diagonally and the bearing component includes a protrusion coupled to the interference prevention portion.

The present invention relates generally to a prosthetic spinal disc for replacing a damaged disc between two vertebrae of a spine. The present invention also relates to prosthetic spinal disc designs that have interlocking components.

The embodiments provide provides devices, instruments, and associated methods for treating joint pain. A joint is evaluated using magnetic resonance imaging to detect any defects in the subchondral bone. For example, using T2-weighted MRI images, bone marrow lesions or edemas can be identified, and using T1-weighted MRI images, associated regions of sclerotic bone adjacent to the bone marrow lesion can be identified. The treatment method may involve introducing a bone void filler material at the site to address the bone marrow lesion or edema, and/or drilling and inserting an implant to address the sclerotic bone, bone marrow lesion or edema, and insufficiency or stress fractures. An access path is mapped to a location in the subchondral region where the insufficiency fracture resides. The access path attempts to preserve an articular surface of the joint. A reinforcing member that stabilizes the insufficiency fracture is then implanted via the access path.

A knee joint implant that prevents hyperextension includes a femoral component having an anterior surface with reference to the lowermost point of a convex condyle, the anterior surface being configured to have different curvature radii in respective sections thereof, and a bearing component having an anterior surface with reference to the lowermost point of a concave articular surface, the anterior surface being configured to have different curvature radii in respective sections, so that when an extended knee is about to be hyperextended, the convex condyle of the femoral component slides toward the anterior side and is brought into contact with a plurality of points of the concave articular surface of the bearing component, thereby producing resistance so as to suppress hyperextension exceeding a design range due to behavioral habits, a decrease in muscle mass, and the like of the patient.