A hair anchor prepared by a process whereby a plurality of hair anchors are formed from a single elongated metal tube according to some embodiments of the present disclosure may include forming at least two slits in an elongated direction of the elongated metal tube, each slit spanning prospective end portions of at least two hair anchors; and severing the elongated metal tube at an intermediate location along the at least two slits such that a first portion of each of the at least two slits is contained in one of the at least two hair anchors and a second portion of each of the at least two slits remains attached to the elongated metal tube for inclusion in a subsequent hair anchor to be later severed from the elongated metal tube.

A hair anchor prepared by a process whereby a plurality of hair anchors are formed from a single elongated metal tube according to some embodiments of the present disclosure may include forming at least two slits in an elongated direction of the elongated metal tube, each slit spanning prospective end portions of at least two hair anchors; and severing the elongated metal tube at an intermediate location along the at least two slits such that a first portion of each of the at least two slits is contained in one of the at least two hair anchors and a second portion of each of the at least two slits remains attached to the elongated metal tube for inclusion in a subsequent hair anchor to be later severed from the elongated metal tube.

A method for preparing a skin regeneration scaffold is disclosed. The method may include preparing a polymer solution by dissolving a biopolymer in a solvent, and subjecting the polymer solution to a template-assisted extrusion process with a nanoporous material as a template in order to produce polymer nanofibers. Furthermore, the method includes fabricating a multilayer composite nanofibrous scaffold using the polymer nanofibers. The composite nanofibrous scaffold may be seeded with cells. In some cases, the cells may be selected from autologous cells, allogeneic cells, or combinations thereof.

The present invention relates to a dermal layer which is for grafting and has an improved graft survival rate, and a method for producing the same, wherein the dermal layer for grafting can be produced by filling a filling solution, including a DNA fragment mixture and chitosan, into an acellular dermal matrix from which cells have been removed. It was observed that the dermal layer for grafting produced in this manner, due to the filling solution filled therein and including a DNA fragment mixture and chitosan, increases the rate at which cells flow in from the tissue surrounding the graft and are fixed, and thereby alleviates an initial inflammatory reaction and promotes blending with the surrounding tissue.

The present invention relates to a dermal layer which is for grafting and has an improved graft survival rate, and a method for producing the same, wherein the dermal layer for grafting can be produced by filling a filling solution, including a DNA fragment mixture and chitosan, into an acellular dermal matrix from which cells have been removed. It was observed that the dermal layer for grafting produced in this manner, due to the filling solution filled therein and including a DNA fragment mixture and chitosan, increases the rate at which cells flow in from the tissue surrounding the graft and are fixed, and thereby alleviates an initial inflammatory reaction and promotes blending with the surrounding tissue.

A stretchable sensor, electronic skin, and a method of manufacturing the same are proposed. The stretchable sensor includes a first stretchable electrode including a first elastomer and a first conductor dispersed in the first elastomer, a stretchable active layer formed on the first stretchable electrode and including a third elastomer and an ion conductor dispersed in the third elastomer, and a second stretchable electrode formed on the stretchable active layer and including a second elastomer and a second conductor dispersed in the second elastomer. The stretchable sensor and the method of manufacturing the same are effectively capable of sensing a temperature without being affected by strain and recognizing strain without being affected by temperature.

The present disclosure describes a treatment composition comprising a nanoparticle composition comprising nanoparticles functionalized with surface amine groups and a crosslinking composition comprising genipin. The disclosure also describes a kit comprising the treatment composition, and instructions for using the kit to crosslink the nanoparticles to a tissue graft. The treatment composition and kit can be used to crosslink nanoparticles to a tissue graft, and the resulting tissue graft can be used to replace defective tissue in a subject in need thereof.

An automated hair restoration assembly includes a control unit and a cylinder that is gripped during a hair restoration surgical procedure. An actuator is positioned within the cylinder and a turret unit is rotatably coupled to the cylinder. A plurality of cartridges is provided and a selected one of the cartridges is loadable into the turret unit. Each of the cartridges contains a respective one of a plurality of incising blades, a plurality of hair grafts or an alternating sequence of a plurality of said incising blades. The actuator passes through the respective tube and engages one of the incising blades or one of the hair grafts. Thus, each the incising blades can make a respective incision and each of the hair grafts is inserted into the respective incision.

An automated hair restoration assembly includes a control unit and a cylinder that is gripped during a hair restoration surgical procedure. An actuator is positioned within the cylinder and a turret unit is rotatably coupled to the cylinder. A plurality of cartridges is provided and a selected one of the cartridges is loadable into the turret unit. Each of the cartridges contains a respective one of a plurality of incising blades, a plurality of hair grafts or an alternating sequence of a plurality of said incising blades. The actuator passes through the respective tube and engages one of the incising blades or one of the hair grafts. Thus, each the incising blades can make a respective incision and each of the hair grafts is inserted into the respective incision.

Systems, instruments, methods, and compositions are described involving removing a portion of the epidermis within a donor site on a subject, and harvesting dermal plugs within the donor site. An injectable filler is formed by mincing the dermal plugs. The injectable filler is configured for injecting into a recipient site on the subject.