A method for reattaching a detached tissue to a hard tissue includes operation in which a suture anchor having a first stitch and a second stitch is provided, wherein the first stitch is divided into a first strand and a second strand, and the second stitch is divided into a third strand and a fourth strand. The suture anchor is fixed on a hard tissue. The first strand, the second strand, the third strand and the fourth strand pass through a detached tissue. A bioinductive patch is provided, wherein the bioinductive patch includes a patch body and a button. The first strand and the third strand pass through the patch body and a first suture hole of the button, and the second strand and the fourth strand pass through the patch body and a second suture hole of the button. The second strand and the third strand are knotted to form a first strand node, and the first strand node presses the bioinductive patch and the detached tissue tightly onto the hard tissue.

A cartilage repair implant, an auxiliary surgical tool kit and a cartilage repair system are provided. The cartilage repair implant includes a body and a plurality of pins. The body is a porous structure and is configured to carry cartilage repair material. The pins are fixed to the body for being inserted into a patient's bone. The auxiliary surgical tool kit includes a positioning sleeve and a click tool. The positioning sleeve has a through passage. A first alignment structure is disposed on the sidewall of the through passage. The click tool includes an outer tube and a push rod. A second alignment structure mutually aligned with the first alignment structure is disposed on the outer wall of the outer tube. The outer tube is configured to pass through the through passage. The push rod is slidably disposed in the outer tube. One end of the outer tube has a shaping blade for slicing a to-be-implanted region on an affected area of the patient. In which the shape of the to-be-implanted region is corresponding to the shape of the body.

A bone implant adapted to be implanted in a bone structure having a bone tissue, a cartilage tissue, and being formed with a hole is provided. The bone implant includes a scaffold disposed in the hole for connecting with the bone tissue, a connecting layer disposed on the scaffold, and a porous surface layer. The connecting layer includes a bottom portion connected to the scaffold and an extension portion extending from the bottom portion and formed with a plurality of receiving chambers. The porous surface layer is connected to the extension portion and includes a plurality of filler portions respectively filling the receiving chambers, and a tissue-connecting portion configured for connecting with the cartilage tissue.

A method for repairing a cartilage defect according to an exemplary aspect of the present disclosure includes, among other things, preparing a cartilage defect for implantation of a cartilage graft and attaching the cartilage graft via a transosseus tunnel.

A joint implant device is presented. In embodiments, the device may include a central cylindrical anchor with a sharp distal end and a substantially flat proximal portion. In embodiments, the anchor may be provided with at least one longitudinally extending microtube, to convey at least one of blood and nutrients from the distal end to a proximal end. In embodiments, there may be a plurality of microtubes, each having an intake in the distal end and multiple outflows in the proximal portion. In some embodiments the device may include an eyelet through which a suture may be provided for additional fixation into a joint.

A system for harvesting bone material from a bone may include a rotary cutter defining a rotary cutter longitudinal axis extending between a rotary cutter proximal end and a rotary cutter distal end. The rotary cutter may have a drive shaft configured to receive input torque, and an osteochondral cutter configured to cut the tissue and receive the tissue material in response to rotation of the osteochondral cutter under pressure against the tissue. The system may further include a bone port defining a bone port longitudinal axis extending between a bone port proximal end and a bone port distal end. The bone port may have a bone port cannulation sized to closely fit over the osteochondral cutter. At least one of the bone port proximal end and the bone port distal end may be securable to the tissue. A stratiform tissue graft may be delivered through the bone port.

The present invention relates to a lattice support structure for one or more degenerated portions of subchondral bone of a bone epiphysis part of a human or animal joint, and to a related kit of parts and to a template assembly for the assembly thereof.

The lattice structure comprises at least one rod-shaped and substantially rectilinear rigid primary element configured to be housed within said bone epiphysis extending at least partially through said degenerated portion of subchondral bone along a respective primary extension direction; and a plurality of thread-like substantially rectilinear secondary elements configured to be housed within said bone epiphysis extending at least partially through said degenerated portion of subchondral bone along respective secondary extension directions, comprising first secondary elements configured to extend along respective first secondary extension directions and second secondary elements configured to extend along respective second secondary extension directions (Yd, Ye, Yf), the first and second secondary extension directions being oblique to one another, wherein the at least one primary element has a first transversal dimension greater than a second transversal dimension of said secondary elements.

The at least one primary element and the secondary elements are further configured to reach and cross at least partially, at respective opposite ends, cortical bone portions of said bone epiphysis.

A multicomponent implant system includes a multicomponent implant comprising a base plate and a load plate. The base plate includes a bone facing surface and a base plate interface surface. The load plate includes a load plate interface surface and a load bearing surface, the load bearing surface being substantially parallel to the load plate interface surface and having a contour substantially corresponding to a contour of a removed portion of the articular surface. Both the load plate interface surface and base plate interface surface have a contour substantially corresponding to the contour of the load bearing surface. The load plate is configured to be advanced in an arcuate direction to slidably couple the load plate to the base plate after the base plate has been secured within the first excision site by an anchor.

A cartilage repair implant, an auxiliary surgical tool kit and a cartilage repair system are provided. The cartilage repair implant includes a body and a plurality of pins. The body is a porous structure and is configured to carry cartilage repair material. The pins are fixed to the body for being inserted into a patient's bone. The auxiliary surgical tool kit includes a positioning sleeve and a click tool. The positioning sleeve has a through passage. A first alignment structure is disposed on the sidewall of the through passage. The click tool includes an outer tube and a push rod. A second alignment structure mutually aligned with the first alignment structure is disposed on the outer wall of the outer tube. The outer tube is configured to pass through the through passage. The push rod is slidably disposed in the outer tube. One end of the outer tube has a shaping blade for slicing a to-be-implanted region on an affected area of the patient. In which the shape of the to-be-implanted region is corresponding to the shape of the body.

A method for reattaching a detached tissue to a hard tissue includes operation in which a suture anchor having a first stitch and a second stitch is provided, wherein the first stitch is divided into a first strand and a second strand, and the second stitch is divided into a third strand and a fourth strand. The suture anchor is fixed on a hard tissue. The first strand, the second strand, the third strand and the fourth strand pass through a detached tissue. A bioinductive patch is provided, wherein the bioinductive patch includes a patch body and a button. The first strand and the third strand pass through the patch body and a first suture hole of the button, and the second strand and the fourth strand pass through the patch body and a second suture hole of the button. The second strand and the third strand are knotted to form a first strand node, and the first strand node presses the bioinductive patch and the detached tissue tightly onto the hard tissue.