A method for preparing a cell membrane-coated nano topological array and a use thereof are disclosed. The method includes: stimulating macrophages to form stimulated macrophages, and extracting the membrane of the stimulated macrophages; at the same time, processing a substrate to form a substrate with nanowires, and treating the substrate with nanowires to form a positively charged nanowire substrate; combining the membrane of the stimulated macrophages with the positively charged nanowire substrate to obtain a macrophage membrane-modified nano topological array. The present invention is simple in preparation and operation, and can be applied to capture bacteria.

The present invention relates to methods for removing antigens from tissues by sequentially destabilizing and/or depolymerizing cytoskeletal components and removing and/or reducing water-soluble antigens and lipid-soluble antigens. The invention further relates to tissue scaffolding and decellularized extracellular matrix produced by such methods.

Disclosed is a method for controlling the Young’s modulus of a three-dimensional tissue containing cells and an extracellular matrix by adjusting the average diameter of an extracellular matrix in production of the three-dimensional tissue.

The present invention provides novel methods for poling piezoelectric materials, e.g., collagen, which are carried out in the absence of liquid media and at a relatively low temperature. The present invention also provides electroactive scaffolds comprising poled collagen for promoting cell growth and differentiation.

The present invention provides the use of selected thermogelling polymers for the purpose of growing tumor spheroids. The invention provides a thermogelling platform comprising a synthetic polymer which, when seeded with cancer cells, induces the cells to grow into a natural spheroidal pattern forming a tumor spheroid. After accomplishing this in about 3-10 days, the gel washes away, leaving behind the spheroids.

The present invention relates to a cell culture support comprising a substrate and a polymeric blend layer bound to the substrate. The polymeric blend layer comprises at least one thermoresponsive polymer and at least one coupling agent. The coupling agent is a non-protein coupling agent that has functional thiol, ester, epoxy, or aldehyde groups. The cell culture support further includes cells supported by the polymeric blend layer, wherein the thermoresponsive polymer provides for temperature induced detachment of the cells and/or cell sheets.

The present invention relates to methods for removing antigens from tissues by sequentially destabilizing and/or depolymerizing cytoskeletal components and removing and/or reducing water-soluble antigens and lipid-soluble antigens. The invention further relates to tissue scaffolding and decellularized extracellular matrix produced by such methods.

Disclosed are microbeads for cell culture and a method of monitoring cell culture using the same. More particularly, each of the microbeads for cell culture according to an embodiment of the present invention include a core and a surface modification layer formed on a surface of the core. By using the method of monitoring cell culture with the microbeads for cell culture according to an embodiment of the present invention, cell culture may be carried out in highly scaled-up dimension and easily monitored.

The present invention is directed to methods for forming microparticles useful for cell seeding and for conjugating protein to the surface of the microparticles. The method comprises co-injecting an organic solution of PLGA or other polymer with an aqueous solution into a flow focusing tube.

The present invention relates to a biologically active placenta-derived liquid human substrate (hpS) comprising extracellular matrix (ECM) proteins, cytokines and growth factors and use thereof. The present invention also provides methods of producing a composition comprising biologically active placenta-derived liquid human substrate (hpS).