A method is described for the production of hybrid structures formed by the coupling of nanofibrous parts and microfibrous parts made with silk fibroin, possibly hierarchically organized into complex structures comprising more than two of said parts; these hybrid structures are used as implantable biomedical devices with tailored biological, geometrical and structural features, such that they can be adapted to different application requirements in the field of regenerative medicine.

This disclosure relates to pectin-based polymer compositions and methods of use thereof to cover, protect, and seal injuries, e.g., surgical wounds, in a mesothelial tissue. The methods include obtaining a bioadhesive pectin-based polymer composition including a complex of high-methoxyl pectin (HMP) and carboxymethylcellulose (CMC) in a ratio from about 10 to 1 to 1 to 10 by weight; applying the composition to an injured mesothelial tissue; and applying pressure for at least one minute to enable the composition to bind to the mesothelial tissue.

An inducer is directed to the induction of in situ regeneration in regenerative medicine. The inducer including an extracellular matrix and/or a bone morphogenetic protein, can induce the regeneration of bone and soft tissues surrounding the bone such as muscle, blood vessel and skin at the residual tissues where trauma occurs. The amount of regenerated tissue is associated with the dose of the implanted inducer.

Embodiments herein relate to cell encapsulation membranes, devices including the same, and related methods. In an embodiment, a cell encapsulation membrane is included. The cell encapsulation membrane can include a mesh substrate. The mesh substrate can include a first series of fibers extending in a first direction and a second series of fibers extending in a second direction, the first series of fibers intersecting with the second series of fibers, the mesh substrate defining a plurality of apertures disposed between adjacent fibers of the first series and the second series. The cell encapsulation membrane can further include a coating disposed on the mesh substrate, the coating partially occluding the plurality of apertures defined by the mesh substrate and forming pores. Other embodiments are also included herein.

It has been established that optimizing cell seeding onto tissue engineering vascular grafts (TEVG) is associated with reduced inflammatory responses and reduced post-operative stenosis of TEVG. Cell seeding increased TEVG patency in a dose dependent manner, and TEVG patency improved when more cells were seeded, however duration of incubation time showed minimal effect on TEVG patency. Methods of engineering patient specific TEVG including optimal numbers of cells to maintain graft patency and reduce post-operative stenosis are provided. Closed, single-use customizable systems for seeding TEVG are also provided. Preferably the systems are custom-designed based on morphology of the patient specific graft, to enhance the efficacy of cell seeding.

The invention relates to compositions useful for bone repair and methods of preparing the same. The invention is particularly suitable for bone repair of large bone defects. In an aspect of the invention, the compositions comprise a biocompatible polymer and a clay that form a scaffold. In a further aspect of the invention, the multiple scaffolds can be configured together to form scaffold blocks.

The present disclosure provides a coacervate composition containing a protein drug, gelatin A, sodium alginate and an acid and a wound-healing agent including the same. The coacervate composition according to the present disclosure can be useful as a wound-healing material delivery system for effectively delivering a protein drug, particularly epidermal growth factor, to a wound site in the wound-healing field.

Provided is a bioink comprising a mixture comprising a collagen and a polysaccharide, and a polyhedral oligomeric silsesquioxane (POSS), a hydrogel matrix formed from a bioink comprising a mixture comprising a collagen and a polysaccharide, and a polyhedral oligomeric silsesquioxane (POSS), a 3D biomaterial scaffold comprising a hydrogel matrix of the disclosure as a first hydrogel layer and a hydrogel matrix of the disclosure as a second hydrogel layer, optionally having an intervening layer between the first hydrogel layer and the second hydrogel layer, and methods of forming and using same.

Disclosed herein are nerve xenografts and methods of using such for repairing and/or protecting a nerve tissue in a human patient. The subject matter disclosed herein generally relates to nerve xenografts derived from genetically engineered source animals, and use of such nerve xenografts for repairing and/protecting nerve tissue in a human patient, e.g., for reconstruction of large peripheral nerve gaps, treatment of spinal cord injuries and ailments, and other therapies.

The present invention relates to a method of filling different two-kinds of multiple inks into an ink extruding member for a three-dimensional print and a method of three-dimensional printing using the filled ink, and relates to a three-dimensional printing method using multiple inks comprising a step of applying pressure to the retained multiple inks and extruding it into a single extruding port of the extruding part to prepare an ink extruded product and printing the ink extruded product.