A bone graft substitute which combines substantially the high mechanical stability of spherical porous granules without the limitation of reduced intergranular space. The granules have a high porosity whilst maintaining high stability, and can be pushed into a defect without risking significant breakage of the granules and, simultaneously, bone cells can grow into the space between the granules. In an exemplary embodiment of the invention, the surface of the granules comprises indentations, when viewed from the exterior of the granules. An indentation increases the porosity within the implanted mass significantly and thus provides more space between the granules for tissue ingrowth. Due to the indentations on the granules, the granules have an irregular shape and thus an increase in the intergranular space is achieved, while mechanical stability is maintained. A biocompatible polymer, such as a polypeptide, is disposed about at least some of the granules to form a coating thereon.

The present invention relates to porous composite materials and objects such as 3D scaffolds, in particular to bioactive and bioresorbable scaffolds that can be transformed at body temperature.

The present invention relates to porous composite materials and objects such as 3D scaffolds, in particular to bioactive and bioresorbable scaffolds that can be transformed at body temperature.

Scaffolds for use in bone tissue engineering include a skeleton and a host component. Methods of preparation of scaffolds include identification of biodegradation properties for the skeleton and the host component. The skeleton is constructed to form a three-dimensional shape. The skeleton is constructed of a first material and has a first rate of biodegradation. The host component fills the three-dimensional shape formed by the skeleton. The host component is constructed of a second material and has a second rate of biodegradation. The first rate of biodegradation is slower than the second rate of biodegradation.

Scaffolds for use in bone tissue engineering include a skeleton and a host component. Methods of preparation of scaffolds include identification of biodegradation properties for the skeleton and the host component. The skeleton is constructed to form a three-dimensional shape. The skeleton is constructed of a first material and has a first rate of biodegradation. The host component fills the three-dimensional shape formed by the skeleton. The host component is constructed of a second material and has a second rate of biodegradation. The first rate of biodegradation is slower than the second rate of biodegradation.

Scaffolds for use in bone tissue engineering include a skeleton and a host component. Methods of preparation of scaffolds include identification of biodegradation properties for the skeleton and the host component. The skeleton is constructed to form a three-dimensional shape. The skeleton is constructed of a first material and has a first rate of biodegradation. The host component fills the three-dimensional shape formed by the skeleton. The host component is constructed of a second material and has a second rate of biodegradation. The first rate of biodegradation is slower than the second rate of biodegradation.

Systems, methods, components, and materials are disclosed for stereolithographic fabrication of three-dimensional, dense objects. A resin including at least one component of a binder system and dispersed particles can be exposed to an activation light source. The activation light source can cure the at least one component of the binder system to form a green object, which can include the at least one component of the binder system and the particles. A dense object can be formed from the green object by removing the at least one component of the binder system in an extraction process and thermally processing particles to coalesce into the dense object.

Provided is a compression resistant implant configured to fit at or near a bone defect to promote bone growth, the compression resistant implant comprising porous ceramic particles in a biodegradable polymer, and an oxysterol disposed in or on the compression resistant implant. Methods of making and use are further provided.

Provided is a compression resistant implant configured to fit at or near a bone defect to promote bone growth, the compression resistant implant comprising porous ceramic particles in a biodegradable polymer, and an oxysterol disposed in or on the compression resistant implant. Methods of making and use are further provided.

Provided is a compression resistant implant configured to fit at or near a bone defect to promote bone growth, the compression resistant implant comprising porous ceramic particles in a biodegradable polymer, and an oxysterol disposed in or on the compression resistant implant. Methods of making and use are further provided.