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.

This invention provides methods for optimal implantation of a solid substrate for promoting cell or tissue growth or restored function in an osteochondral, bone or cartilage tissue in a subject in need thereof. The methods include selecting and preparing a solid substrate for promoting cell or tissue growth or restored function for implantation, which solid substrate has a length and width or that promotes a tight fit within the boundaries of the implantation site and is further characterized by a height sufficient such that when a first terminus of said solid substrate is implanted within a bone in a site for implantation, a second terminus of said solid substrate is at a height at least 2 mm less than an articular cartilage layer surface or is proximal to a tide mark region in said implantation site and optionally applying a biocompatible polymer layer to an apical surface of said implant, which layer does not exceed the articular cartilage layer surface in height. Tools for implementation of optimal positioning are described including a unique tool (5-120) for trimming cartilage at the implantation site.

This invention provides methods for optimal implantation of a solid substrate for promoting cell or tissue growth or restored function in an osteochondral, bone or cartilage tissue in a subject in need thereof. The methods include selecting and preparing a solid substrate for promoting cell or tissue growth or restored function for implantation, which solid substrate has a length and width or that promotes a tight fit within the boundaries of the implantation site and is further characterized by a height sufficient such that when a first terminus of said solid substrate is implanted within a bone in a site for implantation, a second terminus of said solid substrate is at a height at least 2 mm less than an articular cartilage layer surface or is proximal to a tide mark region in said implantation site and optionally applying a biocompatible polymer layer to an apical surface of said implant, which layer does not exceed the articular cartilage layer surface in height. Tools for implementation of optimal positioning are described including a unique tool (5-120) for trimming cartilage at the implantation site.

The invention related to an implant comprising a scaffold comprising at least one first area characterized by micropores and at least one second area characterized by macropores, wherein said at least one second area is defined by being expected to be exposed to higher pressures and/or forces when compared with said at least one first area, and methods thereof.

A method of repairing a chondral or osteochondral defect using an implant composition made of a plurality of demineralized bone fibers formed into a contiguous shape having a peg portion and a sheet portion to facilitate cartilage repair.

Bone and joint surface reconstruction methods are disclosed for the therapeutic amelioration of joint defects caused by various conditions, injuries, and diseases to help eliminate or reduce pain and return the joint to its proper bio-mechanical function without the need to replace fully or partially the anatomical joint. The joint may specifically include mammalian joints such as the femorotibial joint, for example. The methods disclosed herein leverage the significant role the subchondral bone plays in the health status of the afflicted joint.

Provided is an implant configured for implantation in a bone segment, the implant including a first part that includes a hydrogel portion and a porous material portion, and a second part that includes an annular rim and a bottom that at least partially define a cavity configured to receive the porous material portion of the first part, and a barb extending from the bottom of the second part in a direction away from the cavity.