A method of preparing a structure is provided. The method includes providing an initial structure; casting a first material in one or more void volumes of the initial structure; removing the initial structure from the first material; obtaining a cast structure comprising the first material; coating a second material on the cast structure; casting a third material using the coated cast structure; removing the first material; and obtaining a final structure. In various embodiments, the initial structure can include a first initial structure and a second initial structure and casting a first material in one or more first void volumes of the first initial structure and in one or more second void volumes of the second initial structure. In various embodiments, the method includes assembling the first cast structure and the second cast structure and obtaining an assembled structure comprising the first cast structure and the second cast structure.

A surgical membrane for supporting bone growth comprises a surface configured for receiving a surface functionalisation agent capable of promoting cell adhesion and proliferation and/or of reducing bacterial growth on said surface. The membrane is also subjected to a treatment improving the wettability of the surface.

A surgical membrane for supporting bone growth comprises a surface configured for receiving a surface functionalisation agent capable of promoting cell adhesion and proliferation and/or of reducing bacterial growth on said surface. The membrane is also subjected to a treatment improving the wettability of the surface.

The present disclosure relates to medical devices, and methods for producing and using the devices. In embodiments, the medical device may be a buttress including a porous substrate possessing a therapeutic layer of a chemotherapeutic agent and optional excipient(s) thereon. By varying the form of chemotherapeutic agents and excipients, the medical devices may be used to treat both the area to which the medical device is attached as well as tissue at a distance therefrom.

The present disclosure relates to medical devices, and methods for producing and using the devices. In embodiments, the medical device may be a buttress including a porous substrate possessing a therapeutic layer of a chemotherapeutic agent and optional excipient(s) thereon. By varying the form of chemotherapeutic agents and excipients, the medical devices may be used to treat both the area to which the medical device is attached as well as tissue at a distance therefrom.

Disclosed is a method of producing reconstructed human skin including forming a three-dimensional hydrogel scaffold matrix by gelling a matrix solution including a type I collagen solution, forming a coating layer by coating the three-dimensional hydrogel scaffold matrix with type IV collagen, and forming an epidermis by seeding epidermal keratinocytes onto the three-dimensional hydrogel scaffold matrix having the coating layer formed thereon and performing culture.

Disclosed is a method of producing reconstructed human skin including forming a three-dimensional hydrogel scaffold matrix by gelling a matrix solution including a type I collagen solution, forming a coating layer by coating the three-dimensional hydrogel scaffold matrix with type IV collagen, and forming an epidermis by seeding epidermal keratinocytes onto the three-dimensional hydrogel scaffold matrix having the coating layer formed thereon and performing culture.

The disclosure discloses a claw-shaped pedicle screw fastener for osteoporosis, including an inner screw plug and an outer screw; the outer screw includes an outer nut and an outer screw stem, a through hole is defined in and penetrates through the outer nut and the outer screw stem, the outer screw stem has a thread segment, a claw-shaped segment, and a conical segment that are provided on outside of the outer screw stem; the claw-shaped segment is made of deformable metal; the inner screw plug includes an inner nut and an inner screw stem, the inner screw stem is inserted into the through hole, and the inner screw stem is threadedly connected to the first inner thread and the second inner thread; the inner screw stem and the second inner thread are reverse thread screws relative to each other.

The disclosure discloses a claw-shaped pedicle screw fastener for osteoporosis, including an inner screw plug and an outer screw; the outer screw includes an outer nut and an outer screw stem, a through hole is defined in and penetrates through the outer nut and the outer screw stem, the outer screw stem has a thread segment, a claw-shaped segment, and a conical segment that are provided on outside of the outer screw stem; the claw-shaped segment is made of deformable metal; the inner screw plug includes an inner nut and an inner screw stem, the inner screw stem is inserted into the through hole, and the inner screw stem is threadedly connected to the first inner thread and the second inner thread; the inner screw stem and the second inner thread are reverse thread screws relative to each other.

Compositions of small molecules, matrices, and isolated cells including methods of preparation, and methods for differentiation, trans-differentiation, and proliferation of animal cells into the osteoblast cell lineage were described. Examples of osteogenic materials that were administered to cells or co-cultured with cells are represented by compounds of Formula II, IV, and VI independently or preferably in combination with a matrix to afford bone cells. Small molecule-stimulated cells were also combined with a matrix, placed with a cellular adhesive or material carrier and implanted to a site in an animal for bone repair. Matrix pretreated with compounds of Formula II, IV, and VI were also used to cause cells to migrate to the matrix that is of use for therapeutic purposes.