A resilient resorbable chemically crosslinked collagen sponge for promoting soft tissue volume augmentation in the oral region, comprising 60-96% (w/w) collagen and 4-40% (w/w) elastin, which shows by mercury intrusion porosimetry interconnected pores with a median pore diameter between 50 and 90 μm and at least 80% porosity with a pore diameter more than 10 μm, an onset temperature of 45 to 57° C. and a density in dry state from 50 to 65 mg/cm.sup.3. A process for preparing a resilient resorbable chemically crosslinked collagen sponge. A method of using a resilient resorbable chemically crosslinked collagen sponge as an implant in the oral cavity for soft tissue volume augmentation.

Methods are provided herein for modifying antigenic carbohydrate epitopes within a xenographic bioprosthetic tissue by oxidation of vicinal diols to form aldehydes or acids and subsequence reductive amination of aldehydes to form stable secondary amines, or amidation or esterification of acids to form stable amides or esters. Advantageously, methods provided herein mitigate the antigenicity of the bioprosthetic tissue while leaving the overall tissue structure substantially undisturbed, and thereby enhance the durability, safety and performance of the bioprosthetic implant.

A method for manufacturing a heart valve using bioprosthetic tissue that exhibits reduced in vivo calcification. The method includes applying a calcification mitigant such as a capping agent or an antioxidant to the tissue to specifically inhibit oxidation in tissue. Also, the method can be used to inhibit oxidation in dehydrated tissue. The capping agent suppresses the formation of binding sites in the tissue that are exposed or generated by the oxidation and otherwise would, upon implant, attract calcium, phosphate, immunogenic factors, or other precursors to calcification. In one method, tissue leaflets in assembled bioprosthetic heart valves are pretreated with an aldehyde capping agent prior to dehydration and sterilization.

A method or apparatus for creating a three-dimensional tissue construct of a desired shape for repair or replacement of a portion of an organism. The method may comprise injecting at least one biomaterial in a three-dimensional pattern into a first material such that the at least one biomaterial is held in the desired shape of the tissue construct by the first material. The apparatus may comprise an injector configured to inject at least one biomaterial in a three-dimensional pattern into a first material such that the at least one biomaterial is held in the desired shape of the tissue construct by the first material. The first material may comprise a yield stress material, which may be a material exhibiting Herschel-Bulkley behavior. The tissue construct may have a smallest feature size of ten micrometers or less.

The present invention relates to preparation and use of nanocellulose fibrils or crystals such as disintegrated bacterial nanocellulose, tunicate-derived nanocellulose, or plant-derived nanocellulose, together with carbon nanotubes, as a biocompatible and conductive ink for 3D printing of electrically conductive patterns. Biocompatible conductive bioinks described in this invention were printed in the form of connected lines onto wet or dried nanocellulose films, bacterial cellulose membrane, or tunicate decellularized tissue. The devices were biocompatible and showed excellent mechanical properties and good electrical conductivity through printed lines (3.8.Math.10.sup.−1 S cm.sup.−1). Such scaffolds were used to culture neural cells. Neural cells attached selectively on the printed pattern and formed connective networks. The devices prepared by this invention are suited as bioassays to screen drugs against neurodegenerative diseases such as Alzheimer's and Parkinson's, study brain function, and/or be used to link the human brain with electronic and/or communication devices. They can also be implanted to replace neural tissue or stimulate guiding of neural cells. They can also be used to stimulate the heart by using electrical signaling or to repair myocardial infarction and/or damage related thereto.

In one embodiment, a delivery assembly can comprise an annular frame, a leaflet structure positioned within the frame and secured thereto, and an outer skirt positioned around an outer surface of the frame. The annular frame can comprise an inflow end and an outflow end and can be radially collapsible and expandable between a radially collapsed configuration and a radially expanded configuration. The outer skirt can comprise pericardial tissue having a fibrous parietal layer defining a first surface of the outer skirt and a serous parietal layer defining a second surface of the outer skirt. The outer skirt can be positioned such that the first surface is facing away from the frame and the second surface is facing towards the frame.

The present invention provides compositions, systems and methods for treating diabetes in a subject. The composition of the present invention includes a decellularized vascular graft, a biocompatible hydrogel encasement with tunable rigidity, and a plurality of cells such as pancreatic islet cells.

The present disclosure relates to methods of preparing personalized blood vessels, useful for transplantation with improved host compatibility and reduced susceptibility to thrombosis. Also provided are personalized blood vessels produced by the methods and use thereof in surgery.

Provided herein is a living bone graft including a biofabricated graft core including demineralized bone matrix and a carrier and a pre-vascularized shell at least partially enrobing the graft core, the pre-vascularized shell including isolated, intact adipose-derived microvessel fragments, mesenchymal stem cells, and collagen. The disclosed bone grafts include stromal cells that differentiate and microvessels that inosculate to provide a functional microvasculature, thereby approximating native bone repair as the graft matures in the patient. Also provided herein are methods of fabricating a bespoke, living, vascularized bone graft and methods of treating a segmental bone defect in a patient.

This disclosure relates to composite materials for repairing a tissue of a subject by implanting the composite material in or on the tissue, e.g., heart tissue. In certain embodiments, the composite material comprises a first material and a second material coated on the first material, wherein the first material is an inert substantially non-biodegradable material providing mechanical support; wherein the second material is a biodegradable active material attracting cells from the body of a subject, and wherein, when the composite material is implanted, cells integrate into the inert material providing a remodeled tissue. In certain embodiments, this disclosure relates to methods of using the composite material wherein the inert and active materials allow for remodeling of the material in vivo.