Abstract: A spinal implant for insertion into and positioning in an intervertebral space is provided. The insert comprises a compressible support configured to change the height of the insert, wherein the insert comprises a first portion having a first surface and a compressible support adjacent to the first surface; and a second portion having a second surface and a second compressible support adjacent to the second surface. A method for fusing two adjacent vertebrae utilizing the spinal implant including the bone insert is also provided.

Abstract: A spinal implant for insertion into and positioning in an intervertebral space is provided. The insert comprises a compressible support configured to change the height of the insert, wherein the insert comprises a first portion having a first surface and a compressible support adjacent to the first surface; and a second portion having a second surface and a second compressible support adjacent to the second surface. A method for fusing two adjacent vertebrae utilizing the spinal implant including the bone insert is also provided.

Abstract: 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 ?m to 800 ?m 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.

Abstract: A method of making porous ceramic granules is provided. The method comprises heating pore-forming agent particles to a temperature above a glass transition temperature for the pore-forming agent particles; contacting the heated pore-forming agent particles with a ceramic material to form a mixture of pore-forming agent particles and ceramic material; heating the mixture to remove the pore-forming agent particles from the mixture to form a porous ceramic material; and micronizing the porous ceramic material to obtain the porous ceramic granules, wherein the porous ceramic granules have an average diameter from about 50 ?m to 800 ?m. The porous ceramic granules are also disclosed.

Abstract: 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 ?m to 800 ?m. 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.

Abstract: A bone implant is provided which includes a plurality of lyophilized porous macroparticles comprising ceramic material and collagen. The plurality of lyophilized porous macroparticles is coated with a mineral coating which comprises nano-size features having a carbonate-substituted, calcium-deficient hydroxyapatite component, the bone implant comprising a plurality of recesses, projections, or a combination thereof. A method of making the bone implant and a method of treating a bone defect with the bone implant are also provided.

Abstract: An implantable composition is provided. The composition comprises porous ceramic granules. The porous ceramic granules comprise hydroxyapatite in an amount of about 8 to about 22 wt. % and beta-tricalcium phosphate in an amount of about 78 to about 92 wt. % based on a total weight of a ceramic granule. The composition includes a collagen carrier, and the porous ceramic granules have an average diameter from about 50 ?m to 800 ?m. Methods of making are also disclosed.

Abstract: A uniformly hydrated composition is provided and methods of making the uniformly hydrated composition. The method comprises providing a plurality of lyophilized porous macroparticles in a chamber, the plurality of lyophilized porous macroparticles each having an average diameter from about 0.1 mm to about 10 mm and comprising ceramic material and polymer; and mixing each of the plurality of lyophilized porous macroparticles with a fluid in the chamber to uniformly hydrate each of the plurality of lyophilized porous macroparticles to form a uniformly hydrated composition. Hydratable compositions are also provided.

Abstract: 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 ?m to 800 ?m. 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.

Abstract: An implantable composition is provided. The composition comprises porous ceramic granules. The porous ceramic granules comprise hydroxyapatite in an amount of about 8 to about 22 wt. % and beta-tricalcium phosphate in an amount of about 78 to about 92 wt. % based on a total weight of a ceramic granule. The composition includes a collagen carrier, and the porous ceramic granules have an average diameter from about 50 ?m to 800 ?m. Methods of making are also disclosed.

Abstract: A method of making porous ceramic granules is provided. The method comprises heating pore-forming agent particles to a temperature above a glass transition temperature for the pore-forming agent particles; contacting the heated pore-forming agent particles with a ceramic material to form a mixture of pore-forming agent particles and ceramic material; heating the mixture to remove the pore-forming agent particles from the mixture to form a porous ceramic material; and micronizing the porous ceramic material to obtain the porous ceramic granules, wherein the porous ceramic granules have an average diameter from about 50 ?m to 800 ?m. The porous ceramic granules are also disclosed.