The present invention provides a method for manufacturing a regular and high-density regenerated hair follicle primordium aggregation similar to the hair follicle tissue of a mammal in a simple manner. A regenerated hair follicle primordium aggregation manufacturing method of the present invention includes a step of forming hair follicle primordia by inoculating a microwell plate, which includes regularly arranged microwell portions, with mesenchymal cells and epithelial cells and culturing a mixture of the cells while supplying oxygen thereto.

The present application relates to injectable tissue products and their production and use thereof. The tissue products include a group of acellular tissue matrix particles, a bioadhesive, and a biocompatible polymer. The tissue products may be used to treat hernia defects.

A haemostat agent in the form of a multi-layer patch comprising at least first and second layers, wherein said first layer comprises a composition comprising fibrous -chitin (which may be sourced from a marine source such as squid pens) and one or more biocompatible polymer (for example, a polyethylene glycol (PEG) polymer or sodium polyphosphate (PolyP)), and said second layer comprises a film layer comprising fibrous -chitin. In one particular application, the haemostat agent is used for treating carotid artery injury associated with endonasal surgery.

An antimicrobial polymer for use in an ophthalmic implant, includes at least one antimicrobial monomer; and at least one other monomer selected from an acrylic, silicone, vinyl and collagen monomer.

The present disclosure provides tissue products produced from adipose tissues, as well as methods for producing such tissue products. The tissue products can include acellular tissue matrices for treatment of a breast.

The present invention solves the following problems [1] to [3] found in conventional methods of preparing a three dimensional structure (organ primordium) by coculturing functional cells with umbilical cord-derived vascular endothelial cells and bone marrow-derived mesenchymal cells: [1] the quality of resultant organ primordia varies greatly depending on donors; [2] the growth capacities of cell sources are limited; and [3] it is difficult to secure immunocompatibility because cells are derived from different sources. An organ bud prepared from vascular cells, mesenchymal cells and tissue or organ cells, wherein each of the vascular cell, the mesenchymal cell and the tissue or organ cell has been induced from pluripotent stem cells. A method of preparing an organ bud, comprising culturing vascular cells, mesenchymal cells and tissue or organ cells in vitro, wherein each of the vascular cell, the mesenchymal cell and the tissue or organ cell has been induced from pluripotent stem cells.

A method is provided for pre-stretching implantable biocompatible materials, such as material to be incorporated into an implantable device. A sheet of implantable biocompatible material is attached to one or more tensioning members, where tension is applied along one or more axes. Tension is applied for a period of time, and at an appropriate force, to produce a desired degree of thinning or pre-stretching of the implantable biocompatible material. During the tensioning, the implantable biocompatible material is maintained at an elevated temperature, such as a temperature that is at least substantially a temperature of an environment into which the material will be implanted.

An implantable scaffold device comprises a non-biodegradable backbone and a biodegradable dermal compartment comprising live cells. Method of fabricating implantable devices via 3D printing using a synthetic ink formulation coprinted with a biodegradable bioink.

An antimicrobial polymer for use in an ophthalmic implant, includes at least one antimicrobial monomer; and at least one other monomer selected from an acrylic, silicone, vinyl and collagen monomer.

The present invention provides, in some embodiments, multi-layer silk compositions including a first layer comprising silk fibroin and keratinocytes, a second layer comprising silk fibroin and fibroblasts, a third layer comprising silk fibroin and adipocytes, and a plurality of nervous system cells, wherein at least some of the plurality of nervous system cells span at least two layers, and methods of making and using the same. In some embodiments, provided methods and compositions further include immune cells and/or endothelial cells.