Provided in this disclosure are various composite grafts having a trabecular synthetic scaffold with voids defined in at least a portion of the scaffold and a biological component positioned in at least some of the voids of the scaffold. The grafts may be osteogenic, chondrogenic, osteochondrogenic, or vulnerary in nature. Also provided are methods of using the composite grafts to treat a tissue defect in a subject. Methods of manufacturing are also provided. Grafts are manufactured by additive manufacturing. Agitation may be used to combine composite grafts with additional biological component.

The present invention is drawn to a 3-dimensional cell-produced scaffold construct comprising cells and the extracellular matrix that has been produced and arranged by these cells.

Compositions and methods for glass composites suitable for tissue augmentation, biomedical, and cosmetic applications are provided. The glass microsphere component of the composites are biologically inert, non-reactive and act as a nearly permanent tissue filler. One embodiment provides a tissue augmentation composite containing an effective amount of solid glass microspheres, hollow glass microspheres, porous wall hollow glass microspheres, or combinations thereof with a suitable biocompatible matrix to serve as a bulking agent when injected into a patient. The compositions can be used for soft or hard tissue augmentation as well as delivery of cargos on demand.

A tendon repair implant for treatment of a partial thickness tear in the supraspinatus tendon of the shoulder is provided. The implant may incorporate features of rapid deployment and fixation by arthroscopic means that compliment current procedures; tensile properties that result in desired sharing of anatomical load between the implant and native tendon during rehabilitation; selected porosity and longitudinal pathways for tissue in-growth; sufficient cyclic straining of the implant in the longitudinal direction to promote remodeling of new tissue to tendon-like tissue; and, may include a bioresorbable construction to provide transfer of additional load to new tendon-like tissue and native tendon over time.

Methods are disclosed for forming tissue engineered, tubular gut-sphincter complexes from intestinal circular smooth muscle cells, sphincteric smooth muscle cells and enteric neural progenitor cells. The intestinal smooth muscle cells and neural progenitor cells can be seeded on a mold with a surface texture that induces longitudinal alignment of the intestinal smooth muscle cells and co-cultured until an innervated aligned smooth muscle sheet is obtained. The innervated smooth muscle sheet can then be wrapped around a tubular scaffold to form an intestinal tissue construct. Additionally, the sphincteric smooth muscle cells and additional enteric neural progenitor cells can be mixed in a biocompatiable gel solution, and the gel and admixed cells applied to a mold having a central post such that the sphinteric smooth muscle and neural progenitor cells can be cultured to form an innervated sphincter construct around the mold post. This innervated sphincter construct can also be transferred to the tubular scaffold such that the intestinal tissue construct and sphincter construct contact each other, and the resulting combined sphincter and intestinal tissue constructs can be further cultured about the scaffold until a unified tubular gut-sphincter complex is obtained.

In general, the present invention is related to biopolymer and biocomposite materials and structures, and methods of making and using the same. In some embodiments, the present invention is directed to oriented collagen based biocomposite materials and structures, and methods of making.

A biphasic scaffold and devices and methods for making the scaffold are disclosed. An example scaffold may include (a) a first plurality of randomly-oriented nanofibers defining a first tab region, (b) a second plurality of randomly-oriented nanofibers defining a second tab region, and (c) a plurality of aligned nanofibers coupled to and extending between the first tab region and the second tab region, where the plurality of aligned nanofibers are suspended between the first tab region and the second tab region.

A high molecular weight polyethylene polymer is formulated so that the polymer is capable of being injection molded. The polyethylene polymer has a Viscosity Number of greater than about 400 ml/g and has a melt flow rate of greater than about 0.9 g/10 min. The polyethylene polymer is of high purity and is particularly well suited for producing medical products.

The present invention provides an actuator, comprising a fiber and a temperature regulator capable of at least one of heating and cooling the fiber. The fiber is twisted around a longitudinal axis thereof. The fiber is folded so as to have a shape of a cylindrical coil. The fiber is formed of linear low-density polyethylene. The following mathematical formula (I) is satisfied: D/d<1 (I), where D represents a mean diameter of the cylindrical coil; and d represents a diameter of the fiber.

The present invention is directed to a composition comprising a matrix suitable for implantation in humans, comprising defatted, shredded, allogeneic human muscle tissue that has been combined with an aqueous carrier and dried in a predetermined shape. Also disclosed is a tissue graft or implant comprising a matrix suitable for implantation in humans, comprising defatted, shredded, allogeneic human muscle tissue that has been combined with an aqueous carrier and dried in a predetermined shape. The composition and/or tissue graft or implant of the invention is usable in combination with seeded cells, a tissue growth factor, and/or a chemotactic gent to attract a desired cell.