A method of making an organ or tissue comprises: (a) providing a first dispenser containing a structural support polymer and a second dispenser containing a live cell-containing composition; (b) depositing a layer on said support from said first and second dispenser, said layer comprising a structural support polymer and said cell-containing composition; and then (c) iteratively repeating said depositing step a plurality of times to form a plurality of layers one on another, with separate and discrete regions in each of said layers comprising one or the other of said support polymer or said cell-containing composition, to thereby produce provide a composite three dimensional structure containing both structural support regions and cell-containing regions. Apparatus for carrying out the method and composite products produced by the method are also described.

Disclosed herein implantable material and methods for treatment of growth plate injuries and other purposes. These materials can be particularly useful for treating children whose growth plates are active, and can help encourage proper healing and inhibit unwanted bone formations. Exemplary compositions can comprise poly (ethylene glycol) (“PEG”), gelatin (“GEL”), and heparin (“HEP”). The PEG, GEL, and HEP components can be present in various forms of these materials, such as methacrylated forms, etc. The implanted materials can be anti-osteogenic and/or ant-mineralization, and can help prevent unwanted bone growth in the implanted area, such as boney tethers, which can inhibit desirable growth plate healing and overall bone growth.

The present invention features a neural organoid that recapitulates in vitro most characteristics of the brain (e.g., human), and methods of using this neural organoid to study disease and to identify therapeutic agents for the treatment of neurological diseases and disorders.

In one embodiment, the present invention provides a composition, wherein the composition is a porous scaffold, wherein the pores of the scaffold are from 1 to 500 microns, the composition comprising: a) a cross-linkable protein selected from the group consisting of collagen and gelatin; b) a cross-linker which induces cross-linking of the cross-linkable protein; and c) a liquid.

In one embodiment, the present invention provides a composition, wherein the composition is a porous scaffold, wherein the pores of the scaffold are from 1 to 500 microns, the composition comprising: a) a cross-linkable protein selected from the group consisting of collagen and gelatin; b) a cross-linker which induces cross-linking of the cross-linkable protein; and c) a liquid.

A photocurable composition for 3D printing includes a) at least one photocurable prepolymer chosen from the group consisting of functionalized gelatin bearing a first functional group and functionalized decellularized extracellular matrix bearing a second functional group; b) at least one solvent, the solvent being formamide; and c) at least one photoinitiator.

An object of the present invention is to provide a cell transplant device having an ability to induce angiogenesis around the cell transplant device, and a method for manufacturing the same. According to the present invention, a cell transplant device including a cell structure (A) that includes a plurality of biocompatible polymer blocks and a plurality of cells of at least one type, and in which at least one of the biocompatible polymer blocks is disposed in gaps between the plurality of cells; and an immunoisolation membrane (B) that encloses the cell structure is provided.

Disclosed are compositions derived from non-primate mammals having reduced expression of alpha 1,3 gal and their use in food products, food additives, cosmetic products, cosmetic additives, medical products, medical devices and products used in research and production of therapeutics. The compositions and methods disclosed are particularly useful to subjects diagnosed with α-Gal Syndrome (AGS).

Provided herein are composite scaffold biomaterials including two or more scaffold biomaterial subunits, each including a decellularized plant or fungal tissue from which cellular materials and nucleic acids of the tissue are removed, the decellularized plant or fungal tissue having a 3-dimensional porous structure, the two or more scaffold biomaterial subunits being assembled into the composite scaffold biomaterial and held together via gel casting using a hydrogel glue; via complementary interlocking geometry of the two or more scaffold biomaterial subunits; via guided assembly based biolithography (GAB); via chemical cross-linking; or any combinations thereof. Methods for producing such scaffold biomaterials, as well as methods and uses thereof, are also provided.

The present invention relates in part to a hydrogel composition and a method of fabricating the hydrogel composition comprising the steps of providing a solution comprising a polymer comprising crosslinkable groups; providing a solution comprising a crosslinking agent; mixing the solution comprising a polymer comprising crosslinkable groups and the solution comprising the crosslinking agent to form a combined solution; and crosslinking the combined solution. The invention also relates in part to a methods of treatment using the hydrogel composition.