The present invention relates to a protein-based three-dimensional tissue scaffold and the method of the manufacture thereof. Instant scaffolds are particularly useful in tissue reconstruction, in particular in wound treatment and as dermal replacement scaffolds.

A medical device for repairing injuries to the spinal cord or peripheral nerve has a first flexible substrate supporting first nanoparticles selected from the group consisting of silicon, carbon, gold and titanium, at least partially embedded in a binding layer joined to the first flexible substrate. Each first nanoparticle develops along a preferential direction of development. The nanoparticles are oriented so that, statistically, the preferential direction of development is parallel to a first orientation of growth. Stem cells are at least partially embedded in the binding layer. The first nanoparticles are functionalized so that stem cell differentiation along the first nanoparticles is guided in the first orientation of growth. The first flexible substrate is suitable to assume a distended configuration and a wrapped configuration in which it is wrapped around the spinal cord or peripheral nerve whereby the first orientation of growth is statistically parallel to the neuronal direction of extension of neurons of the spinal cord or peripheral nerve.

A tissue scaffold is described. The tissue scaffold comprises a synthetic polymer and one or more natural polymers selected from elastin, fibrin and collagen. The synthetic polymer may be in the form of a fibrous matrix coated with the at least one natural polymer.

The present disclosure is concerned with magneto-patterned cell-laden hydrogel materials and methods of making and using those materials. The disclosed materials are useful for, among other things, repair of tissue defects, e.g., tissue at a tissue interface such as a bone-cartilage interface.

This invention relates generally to water-insoluble but water-swellable and deformable crosslinked PEGylated microgel particles of proteins and protein-based macromolecules that are pseudoplastic (shear thinning) and flow in aqueous media under shear and which can be injected or made to flow, wherein said microgel particles can reform as a cluster of microgel particles when shearing forces are removed. The microgel particles function as a matrix to support cell growth, viability, and proliferation.

Disclosed herein are compositions to facilitate bone growth, formation, and/or repair. Methods of using and making the compositions are also disclosed.

A nerve regeneration device comprising a bioresorbable conduit and a matrix contained therein having elongate pores aligned with the longitudinal axis of the conduit. The matrix comprises collagen, fibronectin, laminin-1, and laminin-2, wherein the amount, by weight, of laminin-1 or laminin-2 is greater than the amount of fibronectin in the matrix.

Hydrogel-based scaffolds useful for promoting pulp cell growth and biosynthesis, regulating pulp cell migration and morphology, or both as well as methods for their production and use are provided.

This invention discloses methods and composition to form biodegradable polymer implant arrays in the live tissue. Artificial cavities are created in the live tissue by using laser ablation, oscillating needle, microneedle array and other methods. The cavities are then filled with biodegradable polymer solution. The solvent in the polymer solution is dissipated in the tissue to form a biodegradable polymer implant in artificial cavities. The cavities and implants formed are arranged to form of an array of implants. The biodegradable polymer in the cavity can also be loaded with drug to form biodegradable drug delivery array in the live tissue.

Bioprinting is the layer-by-layer construction of synthetic tissues or scaffolds. Described herein is a motorized extruder which can precisely extrude and retract extrudate such as bioinks in a compact and rapidly-loadable form-factor. This includes a compact bioprinter using a stepper motor coupled with a threaded shaft to directly move the plunger of an extruder. This pneumatic-mechanical system obviates the needs for pneumatic tubing, rods, or other complex elements of existing designs. The direct drive design further allows for a lighter, smaller gantry that is capable of more precise fabrication of bioprinted constructions. This includes delicate vasculature systems that are beyond limits of existing bioprinting technologies.