Provided is a chitosan hydrogel composition including chitosan, glycerol, and a phosphate group, wherein the chitosan is crosslinked via the glycerol, the phosphate group, or a combination thereof. The temperature at which the chitosan hydrogel composition may be induced from a liquid state into a gel state may be controlled according to the content ratio of the phosphate group and the glycerol, and since printing properties and strength are affected by the gelatin concentration, the composition may be used as an ink for 3D printing.

The invention generally relates to cells and compositions comprising same for use in cell therapy, to methods of obtaining same, and to use of same in cell therapy. In one aspect, the invention provides a method for forming a cell composition from a tissue sample, the method comprising: providing a tissue sample comprising cells; contacting the sample with a polymer in binding conditions, said binding conditions being conditions that enable binding of cells in the sample to the polymer, so that said cells are bound to the polymer; culturing the cells bound to the polymer under conditions and for a time that allows the cell number to increase; providing conditions to induce a phase change of the polymer; thereby forming a cell composition from a tissue sample.

An ab externo method of placing an intraocular implant into an eye can include advancing a needle, in which the implant is disposed, into the eye through conjunctiva and sclera of the eye. The implant can include a drug deliverable to the eye. The implant can thereafter be released to be anchored in the eye and elute the drug to the eye.

In one aspect, a method includes providing support material within which the structure is fabricated, depositing, into the support material, structure material to form the fabricated structure, and removing the support material to release the fabricated structure from the support material. The provided support material is stationary at an applied stress level below a threshold stress level and flows at an applied stress level at or above the threshold stress level during fabrication of the structure. The provided support material is configured to mechanically support at least a portion of the structure and to prevent deformation of the structure during the fabrication of the structure. The deposited structure material is suspended in the support material at a location where the structure material is deposited. The structure material comprises a fluid that transitions to a solid or semi-solid state after deposition of the structure material.

A dental tissue regenerative composition. The composition includes a combination of (1) human dental pulp stem cells and (2) at least one of human umbilical vein endothelial cells or vascular endothelial growth factor. The combination is encapsulated in a light-activated gelatin methacrylate hydrogel.

Methods are disclosed for forming bone and/or cartilage in an avian subject. The methods include administering to the avian subject a therapeutically effective amount of a composition comprising avian mesenchymal stem cells and a hydrogel that supports the differentiation of the avian mesenchymal stem cells into cells of an osteogenic and/or condrogenic lineage. In some embodiments, methods are disclosed for repairing a bone defect and preventing infection, such as that associated bone fracture, in an avian subject. The methods include administering locally to the bone defect a composition comprising a therapeutically effective amount of avian mesenchymal stem cells and a hydrogel, such as a methacrylated gelatin hydrogel.

The present disclosure provides a biomaterial and a method for promoting tissue regeneration by using the biomaterial.

The present invention provides a deformable body (2), wherein the deformable body comprises a force application surface (12) opposite a bone contact surface (52) to be pressed against periosteum of a bone surface (52) of a bone such that the bone contact surface adapts its shape to the shape of the bone surface, wherein the deformable body comprises one or more through-going openings (3) and/or one or more fixation locations (34) arranged to receive a fixation element such as as screw (20), and wherein the deformable body comprises an anaesthetic that is released from or through the bone contact surface. The anaesthetic can be bupivicaine, liposome bupivacaine, lidocaine or levobupivacaine. The anaestethic can be arranged in one or more compartments (6, 7) which have ifferent release rates. The screw can comprise a detent or rim to mate with the deformable body. A sleeve (80) can be arranged in the opening (3) to receive the screw. A pusher element (81) can push the deformable body from the sleeve into position on the screw.

The artificial blood vessel comprises a cortex layer, a fibroblast layer, a smooth muscle cell layer, an endothelial cell layer and an inner cavity. According to the artificial blood vessel, the endothelial layer, the smooth muscle cell layer, the fibroblast layer and the cortex layer are orderly arranged in a three-dimensional space by utilizing integrated technologies of plasma spraying, electrospraying, electrospining, intra-mold pouring and 3D printing; anticoagulant activity of the artificial blood vessel is enhanced by adopting an anticoagulation factor; step-by-step induced differentiation of stem cells in the artificial blood vessel is realized by adopting a growth factor controlled release method; and the artificial blood vessel is cultured by a pulsatile reactor, so that the artificial blood vessel structurally and functionally simulates natural animal blood vessels and provides a corresponding substitute for vascular transplantation and repair.

The present invention provides new coumarin-polymer conjugates that, upon irradiation with IR light, undergo an intermolecular [2+2] cycloaddition reaction through coumarin units through the coumarin components of different units of said coumarin-polymer conjugate thereby forming a crosslinked product, compositions/mixtures comprising said conjugates, products comprising the crosslinked product, and uses thereof. The new coumarin-polymer conjugates of the invention are particularly useful for 3D bioprinting.