The present invention relates to shaped, bone fiber-based products and methods to make the same.

A method of producing an osteoinductive bone graft formed of a plurality of electrospun biodegradable fibers is disclosed. The method includes preparing a fibrous scaffold material formed of the plurality of electrospun biodegradable fibers, wherein the plurality of electrospun biodegradable fibers are entangled with each other to form a cotton-wool like structure having inter-fiber spaces forming a microenvironment for cell growth therein, and immersing the fibrous scaffold in a solution containing BMP-2 so that the BMP-2 is bound to the calcium particles exposed on the surface of the fibers. Area of binding site for BMP-2 on calcium particles exposed on a surface of the electrospun biodegradable fibers is adjusted by an amount of the calcium particles contained in the electrospun biodegradable fibers.

Described herein are compositions and method for autologous adipose tissue grafting. In one embodiment, the composition comprises a recombinant partially ordered polypeptide (Fractomer) or “Fractomer” and adipose tissue from a subject. In one aspect, the Fractomer has the general structure of [(GXGVP).sub.n-α-helix].sub.m, where X can be any amino acid except proline and α-helix is any polyalanine based α-helix having about 5 to 50 Alanine residues. In another aspect, the Fractomer has the structure [(GXGVP).sub.n-GX.sup.1(A).sub.25X.sup.1].sub.m; where X is A or V; X.sup.1 is K or D; n is an integer from 10 to 20; and m is an integer from 4 to 8.

Closed disposable seeding systems with improved seeding chambers permitting uniform seeding of a scaffold or graft with patient's cells are provided. The seeding chambers with a variable width along the length of the chamber, or a minimal gap between the scaffold and chamber wall, provide an improvement of the prior seeding chambers of closed disposable seeding systems by providing faster and more efficient and uniform seeding of the grafts and scaffolds. Also described are scaffolds with biomechanical and structural properties permitting spontaneous reversal of stenosis and neotissue formation as the graft degrades yielding a scaffold-free neovessel.

Closed disposable seeding systems with improved seeding chambers permitting uniform seeding of a scaffold or graft with patient's cells are provided. The seeding chambers with a variable width along the length of the chamber, or a minimal gap between the scaffold and chamber wall, provide an improvement of the prior seeding chambers of closed disposable seeding systems by providing faster and more efficient and uniform seeding of the grafts and scaffolds. Also described are scaffolds with biomechanical and structural properties permitting spontaneous reversal of stenosis and neotissue formation as the graft degrades yielding a scaffold-free neovessel.

Provided are compositions that can be employed for generating microporous gel systems. In some embodiments, the compositions include at least one sub-population of soft hydrogel microparticles with a Youngs modulus of less than 50 kPa and at least one sub-population of stiff hydrogel microparticles with a Young's modulus of greater than 90 kPa. Also provided are methods for generating the compositions, methods for treating bone and/or cartilage defects in subject using the disclosed compositions, methods for treating osteoarthritis using the disclosed compositions, and methods for providing orthopedic implants to subjects.

Provided are compositions that can be employed for generating microporous gel systems. In some embodiments, the compositions include at least one sub-population of soft hydrogel microparticles with a Youngs modulus of less than 50 kPa and at least one sub-population of stiff hydrogel microparticles with a Young's modulus of greater than 90 kPa. Also provided are methods for generating the compositions, methods for treating bone and/or cartilage defects in subject using the disclosed compositions, methods for treating osteoarthritis using the disclosed compositions, and methods for providing orthopedic implants to subjects.

The present invention relates to an allogeneic and heterologous adipose tissue-derived extracellular matrix scaffold, and a method for producing the same.

An adipose tissue-derived extracellular matrix scaffold according to the present invention has a composition similar to the human body, a large surface area, and an interconnected porous structure, and thus has high cell affinity and allows cells to survive for long periods.

A scaffold for tissue repair or wound dressing comprising: a material layer; a polymer fibre layer; and an adhesive component between the material layer and the polymer fibre layer, wherein the adhesive component comprises material having a lower melting temperature (Tm) than the material layer and the polymer fibre layer.

A scaffold for tissue repair or wound dressing comprising: a material layer; a polymer fibre layer; and an adhesive component between the material layer and the polymer fibre layer, wherein the adhesive component comprises material having a lower melting temperature (Tm) than the material layer and the polymer fibre layer.