A method for preserving proliferation and differentiation potential of undifferentiated cells, has steps of providing a culture carrier having a surface coated with a biological material selected from the group consisting of hyaluronan, chondroitin sulfate, carboxymethyl cellulose, carrageenan, alginate, and chitosan; and inoculating and culturing the undifferentiated cells on the surface in the culture carrier with an appropriate medium, such that the proliferation and differentiation potential of undifferentiated cells are preserved. The method can be used for expanding stem cells in vitro without loss of their replicative ability and differentiation capacity. Therefore, the method according to the present invention is amenable to application in regenerative medicine, tissue engineering, and therapy using umbilical cord blood and other cell sources such as peripheral blood, stem cells, tissue progenitor cells, and tissue cells.

Methods of generating tubular, bioengineered, smooth muscle structures are disclosed as well as bioengineered tissue for tubular organ repair or replacement. The methods can include the steps of obtaining smooth muscle cells; culturing the muscle cells to form a smooth muscle cell construct of directionally oriented smooth muscle cells; disposing the smooth muscle cell construct around a tubular scaffold; and culturing construct and scaffold in a growth media until a smooth muscle cell structure is achieved. The step of obtain smooth muscle cells can further include obtaining autologous smooth muscle cells from a subject. In one preferred embodiment, the muscle cells can first be on a fibrin substrate to form a muscle construct, which is then disposed around a tubular scaffold, for example, a chitosan scaffold. The methods of the present invention can further include connecting two or more tubular structures together to form an elongate composite structure.

A transdermal delivery system of microneedles containing a bioactive material, comprising at least one layer of a support material; at least one biodegradable needle associated with the support material, each needle comprising at least one biodegradable polymer and at least one sugar, wherein each biodegradable needle is hollow and is adapted to retain a bioactive material.

Provided are a composition containing mesenchymal stem cells and a hydrogel, and the use thereof. The mesenchymal stem cells are dispersed in the hydrogel. In the composition, the mesenchymal stem cells cooperate with the hydrogel, such that the healing of a fistula can be effectively promoted, the surgical operation difficulty and frequency are greatly reduced and the wound surface is also reduced, the discomfort of a patient in the perioperative period is alleviated, the disease course is shortened, the cure rate is increased, and the recurrence rate is reduced.

Plant-based microfibrous scaffolds and a method for producing these scaffolds for culturing meat, providing a biocompatible, edible, and scalable 3D structure that supports high cell yield. The scaffold includes plant-based proteins, polysaccharides, and carbohydrates, eliminating the need for synthetic polymers and toxic solvents. The method for producing these scaffolds includes dissolving the components, creating a homogeneous solution, spinning the fibers using air volume and centrifugal forces, and heating to achieve crosslinking. The resulting scaffolds have controlled fiber diameters, thicknesses, and area densities, enhancing cell growth, nutrient diffusion, and structural integrity and provide an efficient and sustainable solution for large-scale cultured meat production.

Provided herein is a three-dimensional scaffold composition comprising randomly oriented fibers, wherein the fibers comprise a polyethylene glycol-polylactic acid block copolymer (PEG-PLA) and a poly(lactic-co-glycolic acid) (PLGA). Also provided are methods for using the three-dimensional scaffolds described herein.

Provided herein is a three-dimensional scaffold composition comprising randomly oriented fibers, wherein the fibers comprise a polyethylene glycol-polylactic acid block copolymer (PEG-PLA) and a poly(lactic-co-glycolic acid) (PLGA). Also provided are methods for using the three-dimensional scaffolds described herein.

The present invention relates to a method for preparing a porous scaffold for tissue engineering. It is another object of the present invention to provide a porous scaffold obtainable by the method as above described, and its use for tissue engineering, cell culture and cell delivery. The method of the invention comprises the steps consisting of: a) preparing an alkaline aqueous solution comprising an amount of at least one polysaccharide, an amount of a cross-linking agent and an amount of a porogen agent b) transforming the solution into a hydrogel by placing said solution at a temperature from about 4 C. to about 80 C. for a sufficient time to allow the cross-linking of said amount of polysaccharide and c) submerging said hydrogel into an aqueous solution d) washing the porous scaffold obtained at step c).

A pharmaceutical composition includes a silicified cell or fraction thereof, a cationic layer disposed on at least a portion of the surface of the silicified cell or fraction thereof, and an immunomodulatory moiety bound to at least a portion of the cationic layer. Alternatively, the pharmaceutical composition includes a silicified cell or fraction thereof, a cationic layer disposed on at least a portion of the surface of the silicified cell or fraction thereof, an anionic layer disposed on at least a portion of the cationic layer, and an immunomodulatory moiety bound to at least a portion of the anionic layer.

Provided is a method of preparing a hydrogel composition including a uniform content of calcium phosphate, wherein a hydrogel composition prepared by the method has a uniform content of calcium phosphate, and thus may be used to quantify phosphates contained in the hydrogel composition. Provided is an in-vitro 3D osteoporosis model including a calcium phosphate hydrogel composition, wherein osteoblasts and osteoclasts may be three-dimensionally co-cultured inside a biogel, such that the osteoporosis model may be fabricated according to an intended use or clinical stage. Further, the model contains a calcium phosphate hydrogel with a uniform content of phosphate and thus enables quantification of calcium phosphate through measurement of phosphates, and therefore, the model may be used to screen candidate compounds for an osteoporosis drug and may effectively predict therapeutic effects of the drug on osteoporosis.