A composition for bone regeneration includes substantially spherical granules. Each of the spherical granules include an outer shell including magnesium phosphate and nano-sized silica and a bioactive core encapsulated by the outer shell. The granules include macro-pores and micro-pores. The macro-pores are intergranular spaces between adjacent granules, and the micro-pores are intragranular nanopores formed on the outer shell of each of the granules. A method of producing the substantially spherical granules, includes providing a mixture of a biological active powder, magnesium phosphate, and an initiator with a colloidal silica solution; rotating the mixture with dual asymmetric centrifugation for a predetermined amount of time; and drying the resulting material.

A biocompatible structure includes a scaffold obtained from a 3D structure. The 3D structure includes base layered structures, each of which includes at least a first layer and a second layer surrounded by the first layer. The first layer includes at least one of first, second and third media. The second layer includes at least another of the first, second and third media. The first medium comprises bone particles. The second medium comprises a polymer dissolvable in a first solvent. The third medium comprises solid particulates dissolvable in a second solvent different than the first solvent. The 3D structure is treated with the second solvent to dissolve the solid particulates so as to form pores at positions of the solid particulates therein, thereby resulting in the scaffold having a porosity adjustable by sizes of the solid particulates and concentration of the solid particulates in the 3D structure.

A device and method for producing a bone cement paste from a monomer liquid and a cement powder, wherein the device comprises a cartridge with a cylindrical interior chamber for mixing the parent components, whereby the interior chamber of the cartridge is closed on the front side up to a delivery opening for expelling the bone cement paste from the interior chamber, a delivery plunger which is arranged in the interior chamber of the cartridge and which is supported in a linearly movable manner in the direction of the delivery opening, the cement powder, which is arranged in the interior chamber of the cartridge between the delivery opening and the delivery plunger, a monomer receptacle with an interior chamber in which a monomer liquid container containing the monomer liquid is contained, whereby in the monomer receptacle, a conveying plunger is arranged movable in the longitudinal direction of the monomer receptacle, a compressed gas connection, whereby the conveying plunger is arranged between the monomer liquid container and the compressed gas connection or the compressed gas line in the monomer receptacle.

The present invention relates to a medical implant for cartilage and/or bone repair at an articulating surface of a joint. The implant comprises a contoured implant body and at least one extending post. The implant body has an articulating surface configured to face the articulating part of the joint and a bone contact surface configured to face the bone structure of a joint, where the said articulating and bone contact surfaces face mutually opposite directions and said bone contact surface is provided with the extending post. A cartilage contact surface connects the articulating and the bone contact surfaces and is configured to contact the cartilage surrounding the implant body in a joint. The articulating surface has a layer that consists of titanium nitride (TiN) as the wear-resistant material. The cartilage contact surface has a coating that substantially consists of a material having chondrointegration properties.

Medical devices, substrates and biologic therapies for bone repair and guided tissue regeneration are disclosed. More particularly, bone graft substitutes and bone void fillers which comprise a porous collagen matrix and calcium deficient hydroxyapatite ceramic granules for delivery of osteoinductive or other therapeutic agents are disclosed.

A bone regeneration material has a cotton-wool like structure formed of a plurality of electrospun fibers that contain bound BMP-2 through β-TCP binding peptide. The electrospun biodegradable fiber contains 25-65 vol % of β-TCP particles distributed in the fiber such that a portion of the β-TCP particles is exposed on a surface of the electrospun fiber and the remaining portion of the β-TCP particles is buried in the fiber. β-TCP binding peptides that are fused with BMP-2 are bound to the β-TCP particles so that BMP-2 is tethered to β-TCP particles on the surface of the fibers. Upon implantation of the bone regeneration material in a bone defect site of a human body, BMP-2 that are tethered to β-TCP particles on the surface of the bone regeneration material promotes proliferation and differentiation of cells at the bone defect site.

Provided herein are scaffold biomaterials including a decellularized plant or fungal tissue from which cellular materials and nucleic acids of the tissue are removed, the decellularized plant or fungal tissue having a 3-dimensional porous structure; wherein the decellularized plant or fungal tissue may optionally be at least partially coated or mineralized, wherein the scaffold biomaterial may optionally further include a protein-based hydrogel and/or a polysaccharide-based hydrogel, or both. Also provided herein are methods and uses of such scaffold biomaterials, including methods of manufacture as well as methods and uses for bone tissue engineering, for example.

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.

A method for controlling generation of biologically desirable voids in a composition placed in proximity to bone or other tissue in a patient by selecting at least one water-soluble inorganic material having a desired particle size and solubility, and mixing the water-soluble inorganic material with at least one poorly-water-soluble or biodegradable matrix material. The matrix material, after it is mixed with the water-soluble inorganic material, is placed into the patient in proximity to tissue so that the water-soluble inorganic material dissolves at a predetermined rate to generate biologically desirable voids in the matrix material into which bone or other tissue can then grow.

Implantable bone compositions are provided. The implantable compositions comprise hydratable bone putties. The hydratable bone putties comprise porous ceramic granules having an average diameter from about 50 μm to 800 μm and the composition has a texture value above about 1000. The porous ceramic granules comprise hydroxyapatite and beta-tricalcium phosphate. The implantable bone compositions further include collagen carriers. In some embodiments, the hydratable bone putty can be hydrated to form a non-settable flowable cohesive cement or gel. Methods of making and using the implantable compositions are also provided.